1. Field of Invention
This invention relates to variable torque/speed transmission, specifically to a variable transmission where the transmission ratio can be varied continuously between any two predetermined values.
2. Description of Prior Art
In most applications the transmission ratio, which is the torque vs. speed ratio transmitted by a driving source, needs to be adjustable in order for the driving source to operate efficiently and effectively. For example, for a vehicle, during start-up, assuming that it is on a level road, the driving source needs to provide torque to accelerate the vehicle and torque to overcome the resisting forces mainly due to friction and wind resistance. Once the vehicle has reached its desired speed, again assuming that it is on level road, the engine only needs to provide torque to overcome the resisting forces, which in this case is likely to be greater than during start-up, but less than the total torque needed during start-up. Hence in this case the torque that the driving source needs to provide is less than the torque that it needs to provide during start-up. However, here the driving source needs to rotate the output shaft at a higher speed since the desired speed of the vehicle is assumed to be greater than the speed of the vehicle during start-up. From the example above, it can be seen that during start-up, the driving source needs to provide a relatively large torque and operate at a relatively low speed. And once the desired speed is reached, the driving source needs to provide a relatively small torque and operate at a relatively high speed. Here a relatively large torque would be wasteful. Hence in order to increase the efficiency of the driving source most vehicles have a transmission, which can vary the torque vs. speed ratio of the driving source.
Most vehicles, such as cars, bikes, or motorcycles use a discrete variable transmission. Here the operator can select between several discrete transmission ratios usually by selecting an input gear or sprocket that is coupled to an output gear or sprocket, which is selected from a set of output gears or sprockets of various pitch diameters. The main advantage of a Continuous Variable Transmission (CVT) over a discrete variable transmission is that a CVT can provide the driving source with a more efficient transmission ratio under most conditions.
One well known CVT, which principal of operation is similar with many CVT's of prior art, consists of two cones, each keyed to a separate shaft, that are coupled by a belt. Because the cones have a tapered surface, the pitch diameters of the cones, which depend on the diameters of the surface of the cones where the belt is axially positioned, changes as the axial position of the belt is changed. Since the apex of the cones point in the opposite direction, changing the axial position of the belt increases the pitch diameter of one cone while decreases the pitch diameter of the other cone. This fact is used to change the transmission ratio between the shafts. One problem with this CVT is that changing the transmission ratio causes wear and frictional energy loses, since the belt has to slide and/or stretch relative to the surfaces of the cones as the pitch diameters are changed.
Another problem with the CVT mentioned in the previous paragraph is that torque can only be transmitted by friction. The need of friction limits the torque that can be transmitted, without causing unpractical high stresses in the belt and in the CVT's supporting members.
It is an object of this invention to present cones or cone assemblies with one or two oppositely positioned torque transmitting devices, such as torque transmitting arcs of constant pitch (formed by torque transmitting members) or teeth. The torque transmitting devices will be used for torque transmission between at least one means for coupling, such as transmission belt or chain, and a cone or cone assembly. The cones or cone assemblies can be used to construct CVT's for which significant circumferential sliding between the torque transmitting surfaces of the torque transmitting devices and the torque transmitting surfaces of the means for coupling engaged to them due to change in pitch diameter can be eliminated, as to reduce wear and frictional energy loses typical in similar devices of prior art and allow the usage of positive engagement devices, such as teeth, in coupling the torque transmitting devices with their means for coupling.
It is another object of this invention to present CVT's that consist of at least one cone or one cone assembly of this invention that is coupled by a means for coupling to at least one means for conveying rotational energy, such as a pulley, a sprocket, a cone assembly of this invention, or a cone of this invention.
It is another object of this invention to provide adjuster systems that can increase the performance of the CVT's of this invention and other CVT's that suffer from either or both transition flexing and a limited duration at which the transmission ratio can be changed, so that efficient non-friction dependent CVT's and efficient friction dependent and CVT's do not suffer from transition flexing and/or a limited duration at which the transmission ratio can be changed can be constructed. Several CVT's utilizing an adjuster system are described in this disclosure.
Accordingly the objects and advantages of the present invention are:
In the drawings, closely relayed figures have the same number but different alphabetic suffixes. Also because of time constraint some items are not drawn to scale, however with the accompanying description their intent should be clear.
For the reference numerals in this disclosure, the label M(number) after a reference numeral, where (number) is a number, such as M2 for example, is used to label different members of a part that is given one reference numeral but consist of more than one member. And the label S(number) after a reference numeral, where (number) is a number, such as S2 for example, is used to label the different shapes of a part that is given one reference numeral. Furthermore, same parts that are used in different location might have a different labeling letter after their reference numeral, or a different reference numeral altogether if this is helpful in describing the invention. If two parts have the same reference numeral then they are identical unless otherwise described.
First the basic idea of the invention will be presented in the General Cone Assembly section. Then some alternate configuration of the invention, labeled as cone assembly A 1026A, cone assembly B 1026B, and cone assembly C 1026C will be presented. Next, a mover mechanism will be described. Finally, several preferred configurations for a Continuous Variable Transmission (CVT) utilizing the invention will be described.
Also in case no specific method of fixing one part to another is described, then the method of gluing one part to another can be used. Although more sophisticated methods might be preferable, having to explain these methods would complicate the description of the invention without helping in describing the essence of the invention. Also in case no specific method for keying a part is provided than set-screws that screw completely or partially through the part to be keyed and the shaft on which it is keyed on can be used.
The corner stone of the invention is shown in
A torque transmitting member 1046 is channel shaped, with two sides and a base. Here the bottom surface of the base of the torque transmitting member 1046 rests on the surface of cone 1024, and a leveling loop 1066 rests on the top surface of the base of torque transmitting member 1046. The leveling loop 1066 is used to provide a level-resting place for a rotational energy conveying device. The inner side surfaces of torque transmitting member 1046 have at least one tooth, which will be used for torque transmission between a rotational energy conveying device and cone 1024. In this disclosure, the torque transmitting members 1046 have a plurality of teeth, which are labeled as teeth 1047. For smooth operation teeth 1047 should have an involute tooth shape. It is also possible to have torque transmitting members 1046 which side surfaces are not toothed, since friction between the side surfaces of torque transmitting member 1046 and the torque transmitting surface(s) of a rotational energy conveying device can also be used to transmit torque,
In order to attach the torque transmitting member 1046 to cone 1024, cone 1024 has two slots 1027. Here each attachment plate 1048 of torque transmitting member 1046 is placed in a slot 1027, and secured to cone 1024 using an attachment wheel 1049. The attachment wheels 1049 are aligned so that they roll with minimum amount of drag when torque transmitting member 1046 is moved from one axial position of cone 1024 to another. It is recommended that an attachment wheel 1049 has some flexibility as to allow some slight play as to account for the change in curvature of the inner surface of cone 1024 where an attachment wheel 1049 is positioned, as the torque transmitting member 1046 is moved from one axial position of cone 1024 to another. It is also recommended that an attachment wheel 1049 has a low friction outer surface so as to minimize frictional losses in instances where an attachment wheel 1049 has to be dragged relative to the inner surface of cone 1024. Furthermore, the attachment plates 1048 can also be used to attach a mover mechanism, which is used to move the torque transmitting member 1046 to a new axial position.
The torque transmitting member 1046 is attached on cone 1024 so that it can only slide in the axial direction of cone 1024, which is the direction along the length of shaft 1016. Sliding the torque transmitting member 1046 in the axial direction changes the pitch diameter of the torque transmitting arc, which depends on the diameter of the surface of cone 1024 where torque transmitting member 1046 is positioned. The arc length, and hence the pitch, of the torque transmitting arc remains constant regardless of its pitch diameter. The arc length of the non-torque transmitting arc increases as torque transmitting member 1046 is being slid from the smaller end of cone 1024 to the larger end of cone 1024.
Furthermore, in order to prevent a rotational energy conveying device, such as a transmission belt, to deform as it comes in and out of contact with torque transmitting member 1046, the surface of cone 1024 that will not be covered by torque transmitting member 1046, should be made flush with the top surface of the base of torque transmitting member 1046. Another method would be to eliminate the base of torque transmitting member 1046. This can be achieved by constructing torque transmitting member 1046 out of two side members that sit directly on the surface of cone 1024, which will be joined beneath the surface of cone 1024. Also, in order to reduce vibrations due to the centrifugal force of torque transmitting member 1046, cone assembly 1026 should be properly balanced
The cones can be made out of die-cast stainless steel. And in order to obtain better dimensional tolerances and a smoother surface finish, it is recommended that the cones obtained from the die-cast process be machined.
The surface of cone 1024 should be PTFE coated. This will reduce the friction between torque transmitting member 1046 and the surface of cone 1024, which will extend the live of torque transmitting member 1046 and reduce the force required to move torque transmitting member 1046 to a new axial position. PTFE coating the surface of cone 1024 also reduces friction between the surface of cone 1024 and the rotational energy conveying device, so that wear due to sliding between the surface of cone 1024 and the rotational energy conveying device due to change in pitch diameter is minimized.
Hence a cone assembly 1026, which mainly consists of a cone 1024 and its torque transmitting member(s) 46, has been introduced.
Cone assembly A 1026A is a cone assembly 1026 with the restriction described in this section. Cone assembly A 1026A has two torque transmitting arcs, each consisting of the torque transmitting surfaces formed by a torque transmitting member 1046 or a group of torque transmitting members 1046. The torque transmitting arcs are positioned opposite from each other on the surface of a cone A 1024A. Furthermore, at the smallest end of cone A 1024A, each torque transmitting arc provides coverage to less than half of the circumference of cone A 1024A. As described before, the circumferential portions adjacent to the torque transmitting arcs, which are not covered by the torque transmitting arcs, will be referred to as non-torque transmitting arcs.
The only difference between cone assembly A 1026A and cone assembly B 1026B is that for cone assembly B 1026B, one torque transmitting arc is replaced with a maintaining arc, formed by one or a group of maintaining member(s) 46N, hence it also uses a cone A 1024A. A maintaining member 1046N is identical to a torque transmitting member 1046 except that it is not used for torque transmission between a rotational energy conveying device and a cone. The primary function of the maintaining member(s) 46N is to maintain the axial position of a rotational energy conveying device, such as a transmission belt, when it is not in contact with a torque transmitting member 1046. Hence the inner side surfaces of maintaining member(s) 46N should not be toothed, and friction between the rotational energy conveying device and maintaining member(s) 46N should be minimized by selecting a proper surface finish and shape for maintaining member(s) 46N.
Furthermore, the arc length of the torque transmitting arc is limited such that the torque transmitting surface(s) of the rotational energy conveying device(s) of the CVT where cone assemblies B 1026B are used, will never cover the entire non-torque transmitting arc of a cone assembly B 1026B. However, the arc length of the torque transmitting arc is long enough so that for the CVT where cone assemblies B 1026B are used, at least a torque transmitting arc of at least one cone assembly B 1026B is always engaged with its rotational energy conveying device.
Cone assembly C 1026C, is a cone assembly 1026 with the restriction described in this section. As in cone assembly B 1026B, the arc length of the torque transmitting arc, formed by the torque transmitting surfaces of torque transmitting member(s) 1046, is limited such that the torque transmitting surface(s) of the rotational energy conveying device(s) of the CVT where cone assemblies C 1026C are used, will never cover the entire non-torque transmitting arc of a cone assembly C 1026C. However, the arc length of the torque transmitting arc is long enough so that for the CVT where cone assemblies C 1026C are used, at least a torque transmitting arc of at least one cone assembly C 1026C is always engaged with its rotational energy conveying device. Like before, in order to reduce vibration due to the centrifugal force of the torque transmitting member(s) 1046, cone assembly C 1026C should be properly balanced.
In the description for cone assembly A 1026A, cone assembly B 1026B, and cone assembly C 1026C, the drawings for these cone assemblies show torque transmitting members 1046 that are toothed. Instead of torque transmitting members 1046 that are toothed, friction torque transmitting members 1046F, which use friction to transmit torque, can also be used for these cone assemblies or any other cone assembly 1026. For example, shown in
The torque transmitting members 1046 and the maintaining members 1046N will be moved relative to the surface of the cone on which they are attached using a mover mechanism. The maintaining members 1046N are attached to the mover mechanism in the same manner as the torque transmitting members 1046, and hence moved in the same manner. For clarity purposes, the maintaining members 1046N will not be referred to in this section.
The mover mechanism consists of a slider bushing 1055, which is attached to a shaft in a manner such that it tightly fits onto the shaft but is free to slide along the length of the shaft and in and out of the cone on which it is used through the support sleeve 1038 of the end cover 1037 of that cone. A rotor 1056 is fitted onto slider bushing 1055. Locking collars will be used to fix the axial position of rotor 1056 relative to slider bushing 1055, however rotor 1056 is free to rotate on slider bushing 1055. In order to attach telescopes 1057 to rotor 1056, pin-holed plates are attached to the outer surface of rotor 1056. The telescopes 1057 will be used to connect the torque transmitting member(s) 46 to rotor 1056, so that the axial position of the torque transmitting member(s) 46 depend on the axial position of rotor 1056. The length of telescopes 1057 can vary so that they can connect the torque transmitting member(s) 46 to rotor 1056 when the torque transmitting member(s) 46 are positioned at the smallest end and at the largest end of the cone on which they are attached. In instances were only one torque transmitting member 1046 is attached to rotor 1056, it is recommended that rotor 1056 is shaped as to reduce the centrifugal force due to that torque transmitting member 1046. The bottom end of each telescope 1057 has two parallel pin-holed plates, which will be used to join the bottom end of a telescope 1057 to a pin-holed plate on rotor 1056 using a locking pin, on which the pin-holed plates of the attached telescope 1057 are able to rotate. The top end of each telescope 1057 has an attachment plate, which is joined to an attachment plate 1048 of a torque transmitting member 1046 using a telescope connector. Here, in order to allow the attachment plates of a telescope 1057 to rotate relative to attachment plates 1048, locking pins are used.
Below is a detailed description of attachment plate 1048, which is shown in its assembled state as a front-view in
The top attachment plate of a telescope 1057, which is labeled as telescope attachment plate 1058, will be connected to attachment plate 1048 using a telescope connector 1059. Telescope attachment plate 1058 is shaped on the top end of a telescope 1057 and is shaped like a plate with a hole, which has a rounded top side. Telescope connector 1059 has a L-shape, where the horizontal and vertical members are formed by plates. At the bottom surface of the horizontal member of telescope connector 1059 a clevis exist. This clevis will be used to join telescope attachment plate 1058 to telescope connector 1059 using a pin and locking rings. At the vertical member of telescope connector 1059, a hole that has the same alignment as the hole of the plate with a hole of attachment plate 1048 exists. In the assembled state, the hole of the plate with a hole of attachment plate 1048 is aligned with the hole of the vertical member of telescope connector 1059, and a bolt, on which attachment wheel 1049 is mounted and which is secured with a nut, goes through those holes. Also, in the assembled state the bottom surface of the plate with a hole of attachment plate 1048 is engaged with top surface of the horizontal member of telescope connector 1059 so as to prevent the plate with a hole of attachment plate 1048 to pivot about the axis of its hole.
All parts discussed above are preferably made out of stainless steel, except the slider bushing 1055, which is preferably made out of oil-impregnated bronze. The mover mechanism described above can be used to change the axial position of the torque transmitting member(s) 46 and the maintaining member(s) 46N, if any, relative to the surface of cone 1024, or cone A 1024A to which they are attached, by changing the axial position of slider bushing 1055 relative to their cone 1024, or cone A1024A.
CVT 1 consists of a pair of cone assemblies A 1026A, each equipped with a mover mechanism described previously. Here one cone assembly A 1026A will be keyed to a driver shaft 1012 and the other cone assembly A 1026A will be keyed to a driven shaft 1014. Torque between the cone assemblies A 1026A is transmitted by a toothed transmission belt 1067, which couples the torque transmitting members 1046 of cone assembly A 1026A on the driver shaft 1012 with the torque transmitting members 1046 of cone assembly A 1026A on the driven shaft 1014. The configuration of CVT 1 and the arc length of the torque transmitting arcs of cone assemblies A 1026A should be designed such that for each cone assembly A 1026A, at least one torque transmitting arc is always engaged with transmission belt 1067. As described earlier, the arc lengths of the non-torque transmitting arcs increase as the torque transmitting members 1046 are slid from the smaller end of their cone A 1024A to the larger end of their cone A 1024A and vice-versa. Since there are instances were the arc lengths of the non-torque transmitting arcs do not correspond to a multiple of the width of a tooth of the teeth 1047 some stretching of transmission belt 1067 to account for this is to be expected. The transmission ratio depends on the axial position of the torque transmitting members 1046 on the surfaces of cones 1024A. The torque transmitting members 1046 of the cone assemblies A 1026A should always be properly aligned. In order to achieve this, the slider bushing 1055 on the driver shaft 1012 and the slider bushing 1055 on the driven shaft 1014 are connected by a connector 1075, in a manner such that they can rotate relative to connector 1075. In order to change the transmission ratio the pitch diameters of the torque transmitting arcs, formed by the torque transmitting surfaces of torque transmitting members 1046, of the cone assemblies A 1026A have to be changed. This is achieved by changing the axial position of transmission belt 1067 and the torque transmitting members 1046 relative to the surfaces of cones 1024A using an actuator, which is attached to connector 1075.
When for both cone assemblies A 1026A, transmission belt 1067 is not in contact with a complete non-torque transmitting arc then the transmission ratio can be changed without causing significant circumferential sliding between the torque transmitting surfaces of the torque transmitting members 1046 and the transmission belt 1067. This is because only the arc length of the non-torque transmitting arc changes as the transmission ratio is changed. The configuration where the transmission ratio can be changed without any significant circumferential sliding between the torque transmitting surfaces of the torque transmitting members 1046 and transmission belt 1067 is referred to as a moveable configuration. And the configuration where changing the transmission ratio will tend to cause significant circumferential sliding between the torque transmitting surfaces of the torque transmitting members 1046 and transmission belt 1067 is referred to as an unmovable configuration. Here changing the transmission ratio when transmission belt 1067 is in an unmovable configuration should simply cause the actuator to stall.
One method to eliminate or reduce stalling of the actuator is to equip the actuator with a spring-loaded piston. Here when the transmission belt 1067 is in a moveable configuration, than the torque transmitting members 1046 will move with the actuator. However, when the transmission belt 1067 is not in a moveable configuration then moving the actuator will not move the torque transmitting members 1046 but will stretch or compress the spring of the spring-loaded piston of the actuator. And once both cone assemblies A 1026A have rotated so that transmission belt 1067 is in a moveable configuration, the tension or compression in the spring-loaded piston will move transmission belt 1067 and the torque transmitting members 1046 in the direction the actuator was moved until the tension or compression of the spring-loaded piston is relieved.
When transmission belt 1067 is in the axial position where the transmission ratio is unity, where the cone assembly A 1026A on the driver shaft 1012 rotates at the same speed as the cone assembly A 1026A on the driven shaft 1014, then transmission belt 1067 can get stuck in an unmovable configuration. One method to avoid this problem is to make the smaller end of one cone assembly A 1026A slightly larger than the larger end of the other cone assembly A 1026A. Under this configuration the cone assemblies A 1026A will never rotate at the same speed, so that the rotational position of one cone assembly A 1026A relative to the other cone assembly A 1026A continuously changes as the cone assemblies A 1026A are rotating. Hence eventually the cone assemblies A 1026A will rotate to a movable configuration.
Another method to avoid having transmission belt 1067 stuck in an unmovable configuration is to have a mover control system control the movement of the actuator. Here, every time the actuator is about to move transmission belt 1067 to the position where the transmission ratio between the cone assemblies A 1026A is unity, the mover control system will stop the actuator. Then the mover control system will wait until the cone assemblies A 1026A have rotated to a rotational position such that once the actuator moves transmission belt 1067 to the axial position where the transmission ratio between the cone assemblies A 1026A is unity, during the rotation of the cone assemblies A 1026A an instance were transmission belt 1067 is in a movable configuration exists. In order for the mover control system to work, it needs to know the rotational position of each cone assembly A 1026A, the rotational speed of each cone assembly A 1026A, the axial position of transmission belt 1067, and the speed of the actuator.
In order for the mover control system to determine the rotational position and rotational speed of the cone assemblies A 1026A, a marked wheel 1085 is keyed to the driver shaft 1012 and to the driven shaft 1014, and each marked wheel 1085 has a marked wheel decoder 1086,which is attached to the frame of the CVT. In order to accurately determine the axial position of transmission belt 1067, a gear rack 1076 is attached to the actuator, and a gear 1077, which engages the gear rack 1076, is attached to the frame of the CVT. A marked wheel 1085 is attached to the gear, and a marked wheel decoder 1086 decodes the information from this marked wheel 1085 to determine the axial position of transmission belt 1067.
The information from the wheel decoders 86 mentioned previously, will be transmitted to a computer. The computer will then process the information to properly move the actuator, such that when the transmission belt 1067 is moved to the axial position where the transmission ratio is unity, an instance where the CVT is in a moveable configuration exists.
The mover control system can also be designed so that it only moves transmission belt 1067 when it is in a moveable configuration, as to prevent the actuator from stalling when it tries to move transmission belt 1067 when it is in an unmovable configuration. However, despite the use of a mover control system, stalling of the actuator is still possible. Furthermore, when gear 1077 is coupled to a rotary actuator it can be used as the actuator, which controls the axial position of the transmission belt 1067, see
CVT 2 consists of either two cone assemblies B 1026B, which are keyed to a driver shaft 1012 such that the torque transmitting arc of one cone assembly B 1026B is positioned opposite from the torque transmitting arc of the other cone assembly B 1026B, or two cones assemblies 1026C, which are attached in the same manner. Each cone assembly 1026(B/C) is coupled to a transmission pulley 1098, attached on driven shaft 1014, by a transmission belt 1067.
The surfaces of the transmission pulleys 1098 are tapered as to match the taper of the outer surfaces of cone assemblies 1026(B/C). This allows the transmission belts 1067 for this CVT to be shaped such that they can rest on the surface of their respective cone assembly 26(B/C) and on the surface of their respective transmission pulley 1098 without being twisted. Hence, there is no need for leveling loop 1066 for CVT 2. Also, as described earlier, the arc lengths of the non-torque transmitting arcs increase as the torque transmitting members 1046 are slid from the smaller end of their cone to the larger end of their cone and vice-versa. Since there are instances were the arc lengths of the non-torque transmitting arcs do not correspond to a multiple of the width of a tooth of the teeth 1047 some stretching of the transmission belts 1067 to account for this is to be expected.
Like in CVT 1, the transmission ratio is controlled by controlling the axial position of the torque transmitting members 1046 relative to the surface of their respective cone using the mover mechanism described earlier. In order to ensure that the axial position of the torque transmitting members 1046 relative to their respective cones is identical as to ensure that they rotate at the same speed, the slider bushings 1055 of the cones assemblies 1026(B/C) are rigidly connected by a slider joiner base 1096 and slider joiner rods 1097 (FIG 9E). The smaller end of the cone 1024A which smaller end is facing the larger end of the other cone 1024A has holes through which the slider joiner rods 1097 can slide through. The change in axial position of the torque transmitting members 1046 has to be accompanied by the change in axial position of the transmission pulleys 1098. In order to achieve this, the transmission pulleys 1098 are keyed to a spline sleeve 1099 (
Furthermore, the slider bushing 1055 of the cone assembly 1026(B/C) located closes to the actuator, which is used to change the transmission ratio, and the spline sleeve 1099 of the transmission pulleys 1098 are connected by a connector B 1075B, in a manner such that they can rotate relative to connector B 1075B, in a configuration such that the torque transmitting members 1046 are always properly aligned with their transmission pulleys 1098. Also, as described for CVT 1, here in instance when the transmission ratio is changed when the transmission belts 1067 are in an unmovable configuration, the actuator, used to change the transmission ratio, should simply stall. Here an unmovable configuration is a configuration were both torque transmitting members 1046 are in contact with their transmission belts 1067.
Furthermore, in order to maintain proper tension in the transmission belts 1067 for every transmission ratio of CVT 2, each transmission belt 1067 is equipped with a tensioning mechanism. The tensioning mechanism consists of two tensioning wheels 1105, two tensioning sliders 1106, two tensioning constrainers 1107, two tensioning movers 1108, and a tensioning actuator 1109. The tensioning wheels 1105 will be attached so that they touch the base of the transmission belts 1067. Each tensioning wheel 1105 is attached to a tensioning slider 1106. Each tensioning slider 1106 slides on a tensioning constrainer 1107. The tensioning constrainers 1107 are angled so that the tensioning wheels 1105 will maintain the proper tension in the transmission belts 1067 for every axial position of the transmission belts 1067. In order to change the axial position of the tensioning sliders 1106, each tensioning slider 1106 has two vertical sleeves, which will slide on two vertical guides of a tensioning mover 1108 so that the tensioning sliders 1106 can freely slide vertically as the axial positions of tensioning movers 1108 are changed. The tensioning actuator 1109 connects the tensioning mover 1108 closest to connector B 1075B to connector B 1075B, and the tensioning mover 1108 closest to connector B 1075B to the other tensioning mover 1108 in a manner such that each tensioning wheel 1105 is properly aligned with its torque transmitting member 1046 and its transmission pulley 1098 for every transmission ratio. Furthermore, tensioning wheels 1105 have smooth non-toothed side surfaces so that they can be used to maintain the alignment of the transmission belts 1067.
The configuration for CVT 1 and CVT 2, and other CVT's using the cones assemblies or cones of this disclosure, can also be used for cone assemblies that use friction torque transmitting members 1046F instead of torque transmitting members 1046. In this case, torque is transmitted through friction; however, in this case there is no stretching of the transmission belts that occur in CVT's where toothed torque transmitting members 1046 are used due to instances were the arc lengths of the non-torque transmitting arcs do not correspond to a multiple of the width of a tooth of the teeth of their torque transmitting members.
In addition to the CVT's described earlier another recommended configuration for a CVT is a CVT that is identical to CVT 1 except that one cone assembly is replaced with a transmission pulley. This CVT will be referred to as CVT 3. Here as in CVT 2, it needs to be ensured that the transmission pulley is always properly aligned with the torque transmitting members of its cone assembly for all transmission ratios. The basic method to maintain alignment and to maintain tension in the transmission belts used in CVT 2 can also be used here. Under this configuration only one cone assembly A 1026A or one cone assembly AF 1026AF is needed, and here the transmission belt used will never get stuck in an unmovable configuration, hence the mover control system of CVT 1 is not needed in this design. A configuration for this CVT, where a cone assembly AF 1026AF, which uses two friction torque transmitting members 1046F, is coupled by a friction belt 1067F to a friction pulley 1098F is shown as a top-view in
Furthermore for CVT 1 and CVT 2, in order to reduce or eliminate stretching of the transmission belts in instances were the arc lengths of the non-torque transmitting arcs do not correspond to a multiple of the width of a tooth of the teeth of their torque transmitting members, which will be referred to as transition flexing, and in order to increase the duration at which the transmission ratio can be changed by reducing or eliminating stalling of the actuator that is used to change the transmission ratio in instance when the transmission ratio is changed when the transmission belts are in an unmovable configuration, adjuster systems for CVT 1 and CVT 2, and the CVT's utilizing them will be described below. If friction torque transmitting members 1046F instead of torque transmitting members 1046 are used, then the adjuster systems are only needed to increase the duration at which the transmission ratio can be changed.
The adjuster systems described in this disclosure can also be used increase the performance of other CVT's, besides CVT 1 and CVT 2, that suffer from either or both transition flexing and a limited duration at which the transmission ratio can be changed by eliminating or reducing transition flexing and/or by increasing the duration at which the transmission ratio can be changed. Most likely, the adjuster systems of this disclosure, can benefit any machine that utilizes torque transmitting devices that alternately come in and out of contact with a common torque transmitting device, for which instances exist or can exist where rotational adjustment to an alternating torque transmitting device or a common torque transmitting device can improve the engagement of an alternating torque transmitting device with its common torque transmitting device; or for which instances exist where rotational adjustment(s) to alternating torque transmitting device(s) or common torque transmitting device(s) can compensate for the rotation of the torque transmitting device(s) that occur during transmission ratio change which may prevent transmission ratio change; or for which instances exist where rotational adjustment to a torque transmitting device which alternates between being in a moveable configuration, where the transmission ratio can be changed, and being in an un-moveable configuration, where the transmission ratio cannot be changed, can maintain that torque transmitting device in a moveable configuration.
Here the CVT 1 to which an adjuster system is added is labeled as CVT 1.1. CVT 1.1 is almost identical to CVT 1, shown again in
The transmission ratio can only be changed when for both cone assemblies only one torque transmitting member is in contact with transmission belt BL1A 31A. Otherwise stalling of the transmission ratio changing actuator occurs. The configuration where the transmission ratio can be changed is referred to as a moveable configuration. Also as described earlier, here transition flexing is not eliminated.
CVT 1.1, which is shown in
And in order to substantially increase the duration at which the transmission ratio can be changed, a mover adjuster AD2A 102A and a mover adjuster AD2B 102B, which are basically identical to the transition flexing adjuster 101A are used. Mover adjuster AD2A 102A, which is shown in
The adjuster body AD2A-M1102A-M1 of mover adjuster AD2A 102A is keyed to the input shaft SH313, and cone assembly CS2A 22A is fixed to the adjuster output member AD2A-M2102A-M2 of mover adjuster AD2A 102A, see
In order to properly control the transition flexing adjusters AD1A and AD1B and the mover adjusters AD2A and AD2B, a computer CP1121, which controls these adjusters based on the input of a transmission ratio sensor SN1A 131A, a rotational position sensors SN2A 132A, a rotational position sensor SN2B 132B, a relative rotational position sensor SN3A 133A, which shown in detail in
In order to connect the transmission ratio sensor SN1A 131A, the rotational position sensor SN2A 132A, and the rotational position sensor SN2B 132B to computer CP1121, simple wire connections are used. Also since transition flexing adjusters AD1A 101A, transition flexing adjuster AD1B 111B, mover adjuster AD2A 102A, mover adjuster AD2B 102B, relative rotational position sensor SN3A 133A, and relative rotational position sensor SN3B 133B are rotating relative to computer CP1121, in order to connect these transition flexing adjusters, mover adjusters and, relative rotational position sensors to the computer CP1121, a ring and brush connection, is used. An example of a ring and brush connection is shown in
A configuration for the transition flexing adjuster AD1A 101A, which has an adjuster body AD1A-M1101A-M1 and an adjuster output member AD1A-M2101A-M2, is shown in
Furthermore in order to ensure that the adjuster output member AD1A-M2101A-M2 can be used to control the rotational position of torque transmitting member CS2A-M2, a constrainer mechanism CN1A 111A, shown in
And the other constrainer link hole of each constrainer link 111A-M2-S1 is placed between a set of telescope constrainer clevis plates of a telescope constrainer clevis CS2A-M5-S122A-M5-S1, such that a constrainer pin 111A-M4 can be inserted through the constrainer link holes and the telescope constrainer clevis plate holes. Here the diameters of the constrainer pins are small enough such that the constrainer links can freely rotate on them, but large enough such that they can be securely held in place relative to their telescope constrainer clevis plates by friction between their side surfaces and the telescope constrainer clevis hole surfaces. In addition, the constrainer pins are long enough such that sufficient engagement between the constrainer pins and a set of telescope constrainer clevis plates can exist.
In addition, while the slots of the cone of cone assembly CS2A where the attachment pins CS2A-M1-S122A-M1-S1, used to attach torque transmitting member CS2A-M122A-M1 to a cone assembly CS2A 22A, are inserted, should allow minimal rotational movements between torque transmitting member CS2A-M122A-M1 and its cone, the slots where the attachment pins CS2A-M2-S122A-M2-S1 of torque transmitting members CS2A-M222A-M2 are inserted should allow sufficient rotational movement between the torque transmitting member CS2A-M222A-M2 and its cone such that transition flexing can be eliminated. Hence here, the attachment pins of torque transmitting member CS2A-M222A-M2 are placed in a gap. In this disclosure, a torque transmitting member which attachment pins are placed in a gap will be referred to as a gap mounted torque transmitting member.
From the description above it can be observed that the torque transmitting member CS2A-M122A-M1 is rotatably constrained relative to mover sleeve CS2A-M622A-M6, and torque transmitting member CS2A-M222A-M2 is rotatably constrained relative to the adjuster output member AD1A-M2101A-M2, and since the adjuster output member AD1A-M2101A-M2 can rotate relative to the mover sleeve CS2A-M622A-M6, the transition flexing adjuster AD1A 101A can be used by computer CP1121 to adjust the rotational position of the torque transmitting member CS2A-M222A-M2 relative to torque transmitting member CS2A-M122A-M1. As described earlier, like CVT 1, CVT 1.1 has two identical cone assemblies, one on the input shaft SH313, which is labeled as cone assembly CS2A 22A, and another one on the output shaft SH414, which is labeled as cone assembly CS2B 22B. Hence here, the transition flexing adjuster AD1B is identical to transition flexing adjuster AD1A, and is mounted on cone assembly CS2B 22B in the same manner as transition flexing adjuster AD1A is mounted on cone assembly CS2A 22A.
Next the mover adjusters AD2A and AD2B, which will be used to substantially increase the duration at which the transmission ratio can be changed, are described. In order to substantially increase the duration at which the transmission ratio can be changed, the mover adjusters will be used to try maintain CVT 1.1 in a moveable configuration, as shown in
Now that the physical configuration of CVT 1.1, including its adjuster system, has been described. The operation of transition flexing adjuster AD1A 101A, transition flexing adjuster AD1B 101B, mover adjuster AD2A 102A, and mover adjuster AD2B 102B will described.
In order to explain the operation of the transition flexing adjusters, first the required relative rotational movements between the torque transmitting members of a cone assembly CS222, such as cone assembly CS2A 22A or cone assembly CS2B 22B, in order to eliminate transition flexing will be described. The relative rotational movements that can be used to eliminate transition flexing are shown in
Graphs showing the required relative rotation between the torque transmitting members (lθ) vs. the arc length of the critical non-torque transmitting arc (lc) in order to reduce/eliminate transition flexing are shown in
Now the operation of the mover adjusters in order to substantially increase the duration at which the transmission ratio can be changed will be described. When the transmission ratio is about to be changed, the computer CP1121 monitors the rotational position of the cone assemblies CS2A 22A and CS2B 22B using the rotational position sensors SN2A 132A and SN2B 132B, and once the cone assemblies are in a moveable configuration, such as shown in
Here a slightly modified version of CVT 2 to which an adjuster system is added is labeled as CVT 2.1. CVT 2.1 is almost identical to CVT 2 described earlier. CVT 2, which is shown in
CVT 2.1, see
Like CVT 2, in order to change the transmission ratio, a transmission ratio changing actuator is used. The strength of the transmission ratio changing actuator should be limited such that under no condition should it be able to cause excessive high stresses in the transmission belts. So that it will stall or slip in instances when it is about to cause excessive high stresses in the transmission belts. But in order to avoid unnecessary stalling or slipping of the transmission ratio changing actuator, it should be strong enough to be able to stretch the transmission belts within an acceptable limit.
Furthermore, for CVT 2.1, in order to eliminate or significantly reduce transition flexing, and substantially increase the duration at which the transmission ratio can be changed, an adjuster AD3103 is used. Like the adjusters described earlier, adjuster AD3103 has an adjuster body AD3-M1103-M1 and an adjuster output member AD3-M2103-M2, that can rotate relative to the adjuster body AD3-M1103-M1. The adjuster body AD3-M1 is mounted on spline sleeve 51B using a set-screw so that it is axially and rotatably constrained relative to spline sleeve 51B. And on the adjuster output member AD3-M2103-M2, the transmission pulley PU1C 41C is fixed via a torque sensor SN4C 134C, so that adjuster output member AD3-M2103-M2 is virtually axially and rotatably constrained relative to transmission pulley PU1C 41C. And since the adjuster output member AD3-M2103-M2 can rotate relative to the adjuster body AD3-M1, transmission pulley PU1C 41C can rotate relative to spline sleeve 51B. However, no adjuster is used to mount transmission pulley PU1D 41D to spline sleeve 51B. Here transmission pulley PU1D 41D is mounted to spline sleeve 51B via a torque sensor SN4D 134D, so that transmission pulley PU1D 41D is virtually axially and rotatably constrained relative to spline sleeve 51B.
In order to control adjuster AD3103, a computer CP2122, which controls adjuster AD3103 based on the input from a transmission ratio sensor SN1B 131B, a rotational position sensor SN2C 132C, a rotational position sensor SN2D 132D, a rotational position sensor SN2E 132E, a torque sensor SN4C 134C, and a torque sensor SN4D 134D is used.
The transmission ratio sensor SN1B 131B is mounted on a frame so that it can be used to monitor the rotation of the transmission ratio gear rack gear via a sensor strip wrapped around the transmission ratio gear rack gear, so that computer CP2122 can determine the transmission ratio, and hence the axial position of the torque transmitting members relative to the cones on which they are attached. And from that information computer CP2122 can determine the pitch diameter, which as described earlier depends on the diameter of the surfaces of the cones where the torque transmitting members are positioned.
The rotational position sensors SN2E 132E, is mounted on a frame so that it can be used to monitor the rotational position of output shaft SH818 via a sensor strip wrapped around output shaft SH818. And from that information computer CP2122 can determine the rotational position of the torque transmitting members. The rotational position sensor SN2C 132C, is mounted on a frame so that it can be used to monitor the rotational position of transmission pulley PU1C 41C via a sensor strip wrapped around a portion of transmission pulley PU1C 41C, or the adjuster output member on which transmission pulley PU1C 41C is mounted. And the rotational position sensor SN2D 132D, is mounted on a frame so that it can be used to monitor the rotational position of transmission pulley PU1D 41D via a sensor strip wrapped around transmission pulley PU1D 41D, or the adjuster output member on which transmission pulley PU1C 41C is mounted. Using the rotational position sensor SN2C 132C and SN2D 132D, computer CP2122 can determine the absolute rotational position of the transmission pulleys and the rotational position of one transmission pulley relative to the other. Also if more advantageous, here a rotational position sensors that monitor the rotational position of the transmission pulleys can be replaced with a relative rotational position sensor that monitors the rotation between the adjuster body and the adjuster output member of adjuster AD3103, and hence the relative rotational position between the transmission pulleys.
The torque sensors SN4C 134C and SN4B 134D, which each have a body and an output shaft, can measure the torque applied between their body and their output shaft. However unlike an adjuster, no significant rotation between the body and the output shaft of a torque sensor is allowed. Torque sensor SN4A 134C is used to measure the pulling load on transmission pulley PU1C 41C due to the torque at input spline shaft SH717 and the rotational resistance provided by cone assembly CS3C 23C. And torque sensor SN4D 134D is used to measure the pulling load on transmission pulley PU1D 41D due to the torque at input spline shaft SH717 and the rotational resistance provided by cone assembly CS3D 23D. Here the body of torque sensor SN4C 134C, is fixed to the adjuster output member AD3-M2103-M2 and the output shaft of torque sensor SN4C 134C is fixed to transmission pulley PU1C 41C; and the body of torque sensor SN4D 134D is keyed to the spline sleeve SP1B 51B, and transmission pulley PU1D 41D is keyed to the output shaft of torque sensor SN4D 134D.
In order to connect the transmission ratio sensor SN1B 131B and the rotational position sensor SN2C 102C to computer CP2122, simple wire connections are used. And since adjuster AD3103, torque sensor SN4C 134C, and torque sensor SN4D 134D are rotating relative to computer CP2122, in order to connect them to computer CP2122, the ring and brush connection, is used. An example of a ring and brush connection is shown in
The rotational position sensor SN2E 132E, which monitors the rotational position of the shaft on which the cone assemblies are mounted, can consist of sensor wheel, which has a circular surface that has an alternating reflective and un-reflective pattern, and a counter, which counts the occurrence each time a reflecting pattern is positioned in front of it, as the sensor wheel is rotating. The counter resets each time the respective shaft rotates one full rotation. Based on the amount of reflective patterns counted, the controlling computer, computer CP2122, to which the sensor is connected can determine the angular position, such as in degrees or radians, of the respective shaft. The rotational position of the cone assemblies mounted on that shaft is determined from the angular position of the respective shaft by having a fixed predetermined reference point, which rotational position is monitored by the controlling computer through the use of rotational position sensor SN2E 132E. An internal memory is needed in order for the controlling computer to remember the reflective patterns counted even when the system is not in operation (turned-off), otherwise the controlling computer will not know the rotational position of the fixed predetermined reference point once the system is turned-off and turned back on. If desired, a marker, which has its own sensor that is connected to the controlling computer, can be used to mark the fixed predetermined reference point. In order to determine the rotational position of the fixed predetermined reference point using this marker and rotational position sensor SN2E 132E, the shaft of the fixed predetermined reference point, which is the shaft on which the marker is attached, should be rotated until the marker is detected by its sensor. Here, the marker will not provide the controlling computer with the rotational position of the fixed predetermined reference point until the marker has been detected by its sensor. Therefore, if a marker is used in conjunction the rotational position sensor SN2E 132E in order to determine the rotational position of the fixed predetermined reference point, if the rotational position of the fixed predetermined reference point is not known, the transmission ratio changing operation should be locked at or moved to a transmission ratio that requires no adjustments until the marker has been detected by its sensor. Hence it is recommended that at the start-up transmission ratio no adjustments are required. It is believed that the problem of having to monitor the rotational position of a reference point on a shaft is not unique; it is also believed that other solutions to this problem, which can also be applied here, exist.
The cone assemblies should be mounted relative to the predetermined reference point of their shaft in a manner such that the angular position of the reference points of the torque transmitting members of the cone assemblies relative to the angular positions of the predetermined reference point of their shaft do not change as the transmission ratio is changed. The angular relationship between the reference points of the torque transmitting members and the predetermined reference point of their shaft should then be programmed into the controlling computer. If the experimental method is used to obtain the function that determines the engagement condition as a function of the transmission ratio, explained later, than it is recommended to do this, although it might be unnecessary; if the mathematical method is used to obtain the function that determines the engagement condition as a function of transmission ratio, than it is necessary to do this. For the cone assemblies described in the description for CVT 1 and CVT 2, the reference points of the torque transmitting members are located at the midpoint of the torque transmitting members. Here if the predetermined reference point is placed to coincide with the reference point of one torque transmitting member, than the angle between the reference point of that torque transmitting member and the predetermined reference point is 0 degrees. And the angle between the reference point of the other torque transmitting member and the predetermined reference point is 180 degrees.
For the front pin belt cone assembly 520A and back pin belt cone assembly 520B described in the Alternate CVT's section of this disclosure, the angular position of a reference point of a torque transmitting member is located at the same angular position as the angular position where the center-lines of the torque transmitting member slides 560-S2 of that torque transmitting member are located, see
Furthermore, the rotational position sensor(s) in addition with the transmission ratio sensor can be used to obtain a function for the engagement condition(s) of the cone assemblies/cone assembly used for each transmission ratio. This can be obtained experimentally and then programmed into the controlling computer. An engagement condition can be represented using the following engagement statuses which are represented as: at what degrees of the predetermined reference point is only the first torque transmitting member, such as the torque transmitting member of cone assembly CS3C 23C for CVT 2.1 or torque transmitting member 1 for the example shown in shown in
An example of an engagement condition is as follows: at a rotational position of 105 to 255 degrees of the predetermined reference point of the shaft on which the first torque transmitting member and the second torque transmitting member are mounted, only the first torque transmitting member is engaged, this duration is referred as engagement status 1; at a rotational position of 255 to 285 degrees of the predetermined reference point both the first torque transmitting member and the second torque transmitting member are engaged, this duration is referred as engagement status 2; at a rotational position of 285 to 75 degrees of the predetermined reference point only the second torque transmitting member is engaged, this duration is referred as engagement status 3; and at a rotational position of 75 to 105 degrees of the predetermined reference point both the second torque transmitting member and the first torque transmitting member are engaged, this duration is referred as engagement status 4. Here the 0 degree rotational position of the predetermined reference point can be made to coincide with the 3 o'clock position of a clock.
The engagement condition can be obtained experimentally using the following procedure: First the CVT is placed at its lowest transmission ratio, lets say it is a transmission ratio of 3.00 for example and the engagement condition for this transmission ratio, which for CVT 2.1 can be represented as the ratio of the diameter of the cone assemblies (output spline) over the diameter of the transmission pulleys (input spline), is obtained. The engagement condition for this transmission ratio is obtained using the following procedures, while placed at this transmission ratio, the shaft on which the torque transmitting members are mounted and which has a predetermined reference point, is rotated; while being rotated the following is determined, using sensors that measures the torque transmitted by each torque transmitting member, visually, using a computer model with a designated program, or using other methods: at what rotational degrees of the predetermined reference point is only the first torque transmitting member engaged (referred to as engagement status 1), at what rotational degrees of the predetermined reference point are both the first torque transmitting member and the second torque transmitting member engaged (referred to as engagement status 2), at what rotational degrees of the predetermined reference point is only the second torque transmitting member engaged (referred to as engagement status 3), and at what rotational degrees of the predetermined reference point are both the second torque transmitting member and the first torque transmitting member engaged (referred to as engagement status 4). Next the transmission ratio is increased an increment, lets say it is increased from a transmission ratio of 3.00 to a transmission ratio of 3.10 for example; and the engagement condition (the rotational degrees of the predetermined reference point for engagement statuses 1 to 4) for that transmission ratio is obtained using the same procedures used for the transmission ratio of 3.00. Next the transmission ratio is increased another increment, lets say it is increased from a transmission ratio of 3.10 to a transmission ratio of 3.20 for example; and the engagement condition for that transmission ratio is obtained. The procedure of increasing the transmission ratio an increment and obtaining the engagement condition for that transmission ratio is repeated until the highest transmission ratio is reached. Obviously the smaller the increments of increasing the transmission ratio, the more accurate the function that estimates the engagement condition for a given transmission ratio, discussed in the next paragraph, will be. Also although in this paragraph for the experiment the entire range (start point to end point) of the engagement statuses are obtained, for the method to obtain the function that estimates the engagement condition for a given transmission ratio described in the next paragraph, only the start points of the engagement statuses are needed. So if it is desired to do so, than during the experiment, only the start points rather than the entire range of the engagement statuses should be determined.
Next the function that estimates the engagement condition for a given transmission ratio is obtained. This function can be obtained by obtaining the equations that estimate the start point of each engagement status. The end points of the engagement statuses are not needed, since the start point of an engagement status is also the end point of the engagement status prior to that engagement status. An equation that estimates the start point of an engagement status can be obtained by plotting all the start points of that engagement status, which can be obtained experimentally, on an equation solving software, such as excel for example, and then using the software to interpolate a function for the start point of that engagement status as a function of the transmission ratio, which is a function from which a start point of that engagement status for a given transmission ratio can be estimated. For example, in order to obtain the equation that estimates the start point of engagement status 1, we first plot the start points obtained experimentally, where we use the x-axis for the values of the transmission ratio, and the y-axis for the values in degrees of the start point; such as (3.00, 105 deg.), (3.10, 100 deg), (3.20, 95 deg), and so forth for example. Once all experimentally obtained start points of engagement status 1 are plotted, we use the software to determine a best-fit equation for those points, such that we obtain the equation that estimates the start point of engagement status 1 as a function of the transmission ratio. Next we use the same procedure to obtain the equation that estimates the start point of engagement status 2 as a function of the transmission ratio, the equation that estimates the start point of engagement status 3 as a function of the transmission ratio, and the equation that estimates the start point of engagement status 4 as a function of the transmission ratio. These equations should then be programmed into the controlling computer of the CVT, as to obtain the function that estimates the engagement condition for a given transmission ratio; so that for each transmission ratio, the controlling computer can determine the start point of each engagement status, and hence determine the current engagement status for a rotational position of a shaft, which is monitored by the controlling computer using dedicated sensors, on which the first torque transmitting member and the second torque transmitting member are used for torque transmission. If more than one shaft on which alternating torque transmitting members are mounted and which engagement condition needs to be known are used, the previous described procedure of obtaining the function that estimates the engagement condition for a given transmission ratio should be repeat for all such shafts as to obtain a function that estimates the engagement condition for a given transmission ratio for all such shafts.
Also instead of obtaining the function that estimates the engagement condition for a given transmission ratio through experimentation and interpolation, the function that estimates the engagement condition can also be obtained mathematically. In order to do this, first the degrees of the coverage of the first torque transmitting member on its cone and the degrees of the coverage of the second torque transmitting member on its cone as a function of the transmission ratio is obtained. The degrees of coverage of the torque transmitting members can be measured relative to the predetermined reference point of their shaft, which can be selected as the 0 degree location. For example, for a hypothetical cone assembly at a transmission ratio of 3.0 the coverage of the first torque transmitting member is from 330 to 30 degrees and the coverage of the second torque transmitting member is from 150 to 210 degrees, where the predetermined reference point of the shaft on which the first torque transmitting member and the second torque transmitting member are mounted is selected as the 0 degree location. If the torque transmitting members are toothed, than coverage does not refer to the coverage of the torque transmitting members on their cone but to the coverage of the teeth of the torque transmitting members on their cone. Also, the transmission ratio depends on the axial position of the torque transmitting members on the surface of their respective cones, and hence on the diameters of the cones where the torque transmitting members are positioned. Using this fact, the equation that determines the circumference of the cones as a function of transmission ratio can be obtained. However, since the pitch-line of the torque transmitting members are not positioned on the surface of the cones, the equation that determines the imaginary circumference of the pitch-line of the torque transmitting members as a function of the transmission ratio needs to be obtained; this equation can be obtained in a similar manner as the equation that determines the circumference of the cones as a function of the transmission ratio, since the radius of the pitch-line of the torque transmitting members is simply the radius of the cone where the torque transmitting members are positioned plus the distance from surface of the cone where the torque transmitting members are positioned to the pitch-line of the torque transmitting members. From the equation that determines the imaginary circumference of the pitch-line of the torque transmitting members as a function of the transmission ratio and the arc lengths of the torque transmitting members as measured at the pitch-lines of the torque transmitting members, the equation that determine the degrees of the coverage of the first torque transmitting member as a function of transmission ratio and the equation that determine the degrees of the coverage of the second torque transmitting member as a function of transmission ratio can be obtained, using the fact that at the pitch-lines of the torque transmitting members, the arc length of the torque transmitting members remain constant regardless of the transmission ratio. Next from the distance between the rotating torque transmission devices, such a cone assemblies, transmission pulleys, tensioning pulleys, etc, at each transmission ratio; and the diameter of the rotating torque transmission devices at each transmission ratio; equations that determine or estimate the engagement coverage of each transmission belt relative to each cone assembly with which it is in contact as a function of transmission ratio can be obtained. Here engagement coverage can be represented by the start degrees where contact between the transmission belt and its cone assembly starts and the end degrees where contact between the transmission belt its cone assembly ends, where the 0 degree position can be made to coincide with the 3 o'clock position of a clock. From the equation that determines the degrees of the coverage of the first torque transmitting member as a function of the transmission ratio; and the equations that determines the engagement coverage of the “transmission belt with which the first torque transmitting member engages” with “the cone on which the first torque transmitting member is mounted” as a function of the transmission ratio; an equation that determines at what degrees of the predetermined reference point the first torque transmitting member engages with its transmission belt as a function of the transmission ratio and an equation that determines at what degrees of the predetermined reference point the first torque transmitting member disengages with its transmission belt as a function of the transmission ratio can be obtained. And from the equation that determines the degrees of the coverage of the second torque transmitting member as a function of the transmission ratio; and the equations that determines the engagement coverage of the “transmission belt with which the second torque transmitting member engages” with the “cone on which the second torque transmitting member is mounted” as a function of the transmission ratio; an equation that determines at what degrees of the predetermined reference point the second torque transmitting member engages with its transmission belt as a function of the transmission ratio and an equation that determines at what degrees of the predetermined reference point the second torque transmitting member disengages with its transmission belt as a function of the transmission ratio can be obtained. The mathematically obtained function that estimates the engagement condition for a given transmission ratio for a shaft on which a first torque transmitting member and a second torque transmitting member are used for torque transmission can be obtained from: the equation that determines at what degrees of the predetermined reference point the first torque transmitting member engages with its transmission belt as a function of the transmission ratio, the equation that determines at what degrees of the predetermined reference point the first torque transmitting member disengages with its transmission belt as a function of the transmission ratio, the equation that determines at what degrees of the predetermined reference point the second torque transmitting member engages with its transmission belt as a function of the transmission ratio, and the equation that determines at what degrees of the predetermined reference point the second torque transmitting member disengages with its transmission belt as a function of the transmission ratio. Here the function that estimates the engagement condition for a given transmission ratio can be obtained by programming the equations mentioned in the previous sentence into the controlling computer. By monitoring the rotational position of the predetermined reference point of the shaft on which the first torque transmitting member and the second torque transmitting member are used for torque transmission and the transmission ratio of the CVT using the designated sensors, the programmed equations can then be used to determine the engagement condition of that shaft as represented by the engagement statuses. If desired, the equation that determines at what degrees of the predetermined reference point the first torque transmitting member engages with its transmission belt as a function of the transmission ratio, the equation that determines at what degrees of the predetermined reference point the first torque transmitting member disengages with its transmission belt as a function of the transmission ratio, the equation that determines at what degrees of the predetermined reference point the second torque transmitting member engages with its transmission belt as a function of the transmission ratio, and the equation that determines at what degrees of the predetermined reference point the second torque transmitting member disengages with its transmission belt as a function of the transmission ratio can be obtained by calculating several points of interest mathematically and then plotting them as to be able to obtain a best-fit equation for those points using an interpolation software. In the previous paragraph, a similar procedure is used in order to obtain the required equations from the experimentally obtained data points.
The functions that estimate the engagement condition for a given transmission ratio described in the previous paragraphs can be used to theoretically accurately determine the engagement condition for the shaft on which the cone assemblies are mounted for CVT 2.1. For a shaft on which a cone assembly is mounted of CVT 1.1, the method above still can be used to determine the engagement condition for that shaft, although it is slightly off due to the fact that the rotational position of a torque transmitting member is adjusted to compensate for transition flexing. One method to deal with this issue is to add a pause engagement status between each engagement status of the engagement statuses described above; here in order to compensate for the inaccuracies of determining the correct engagement status, no adjustments or actions should be taken during the pause engagement statuses. The pause engagement statuses should be long enough to account for the inaccuracies of determining the correct engagement status due to the fact that the rotational position of a torque transmitting member is adjusted to compensate for transition flexing. For example, if the maximum amount of rotational positional adjustment for a torque transmitting member to compensate for transition flexing is 5 degrees in either direction (rotated a maximum of 5 degrees clockwise and 5 degrees counter-clockwise from the unadjusted rotational position) from its unadjusted rotational position, then the start position of the pause engagement statuses that are used to compensate for this rotational positional adjustment should be selected such that the relevant pause engagement statuses start at least 5 degrees earlier than the start position of their engagement status and the end position of the pause engagement statuses that are used to compensate for this rotational positional adjustment should be selected such that the relevant pause engagement statuses end at least 5 degrees later than the start position of their engagement status. Since here the adjusted torque transmitting member can engage and disengage 5 degrees earlier and 5 degrees later compared to its unadjusted rotational position, which should be used to determine the relevant engagement statuses dependent on that adjusted torque transmitting member. In this paragraph it was stated that a pause engagement status should be added between each engagement status, if the shaft for which the engagement statuses are used has a torque transmitting member which rotational position is not adjusted, then some pause engagement statuses are not needed to compensate for the rotational positional adjustment of a torque transmitting member to compensate for transition flexing. If this is the case, then somebody skilled in the art should be able to determine which pause engagement statuses are needed and which are not needed. The description in the next paragraph should also be helpful, since it basically identifies which pause engagement statuses are needed to compensate for the rotational positional adjustment of a torque transmitting member. If in doubt, a pause engagement status, with a duration that is long enough to account for the maximum amount of rotational positional adjustments for a torque transmitting member from its unadjusted rotational position, can be used between each engagement status. More details on pause engagement statuses are described later in this section. Also, for all engagement statuses described in this disclosure, including pause engagement statuses, no engagement statuses overlap each other, and the end point of an engagement status is also the start point of its next engagement status.
Another method to deal with the inaccuracies of determining the correct engagement status for a respective shaft of CVT 1.1 due to the fact that the rotational position of a torque transmitting member is adjusted to compensate for transition flexing, is by compensating for the rotational position adjustments of that torque transmitting member. In order to do this, the relative rotational position between a reference torque transmitting member, which rotational position is not adjusted, relative to an adjusting torque transmitting member, which rotational position is adjusted to compensate for transition flexing, is recorded while the engagement condition is experimentally obtained; then for the equations that estimate the start points of the engagement statuses, derived from the experiment to obtain the engagement condition, a term is added that accounts for the change between the “relative rotational position between the reference torque transmitting member relative to an adjusting torque transmitting member as recorded during the experiment to obtain the engagement condition” and the “current the relative rotational position between the reference torque transmitting member relative to the adjusting torque transmitting member”. For example, if the “relative rotational position between the reference torque transmitting member relative to an adjusting torque transmitting member as recorded during the experiment to obtain the engagement condition” is 180 degrees, and the “current relative rotational position between the reference torque transmitting member relative to the adjusting torque transmitting member” is 181 degrees, then 1 degree should be added or subtracted, since the difference between 181 degrees and 180 degrees is 1 degree, from the start point of the engagement statuses that are affect by this. For example, if the adjusting torque transmitting member is the second torque transmitting member, then for engagement status 2 (at what rotational degrees of the predetermined reference point are both the first torque transmitting member and the second torque transmitting member engaged), in instances where torque transmitting member 2 is rotated such that it engages at an earlier rotational position compared to the relative rotational position used during the experiment to obtain the engagement condition, such that when it is rotated relative to torque transmitting member 1 in the same direction as the direction of the shaft on which it is mounted rotates, then 1 degree should be subtracted from the equation that estimates the start point of engagement status 2; and in instances where torque transmitting member 2 is rotated such that it engages at a later rotational position compared to the relative rotational position used during the experiment to obtain the engagement condition, such that when it is rotated relative to torque transmitting member 1 in the opposite direction as the direction of the shaft on which it is mounted rotates, then 1 degree should be added to the equation that estimates the start point of engagement status 2. Here it is assumed that the controlling computer is set-up such that the rotational position value (preferably in degrees or radians) of the predetermined reference point of the shaft increases as the shaft is rotating before it resets to 0 after a full revolution. And for engagement status 1 (at what rotational degrees of the predetermined reference point is only the first torque transmitting member engaged), in instances where torque transmitting member 2 is rotated such that it disengages at an earlier rotational position compared to the relative rotational position used during the experiment to obtain the engagement condition, such that when it is rotated relative to torque transmitting member 1 in the same direction as the direction of the shaft on which it is mounted rotates, then 1 degree should be subtracted from the equation that estimates the start point of engagement status 1; and in instances where torque transmitting member 2 is rotated such that it disengages at a later rotational position compared to the relative rotational position used during the experiment to obtain the engagement condition, such that when it is rotated relative to torque transmitting member 1 in the opposite direction as the direction of the shaft on which it is mounted rotates, then 1 degree should be added to the equation that estimates the start point of engagement status 1. Again, here it is assumed that the controlling computer is set-up such that the rotational position value (preferably in degrees or radians) of the predetermined reference point increases as the shaft is rotating before it resets to 0 after a full revolution.
The methods for compensating for the inaccuracies of the function that estimates the engagement condition for a given transmission ratio due to the rotational position adjustments of a torque transmitting member as described in the previous two paragraphs, can also be applied to the function that estimates the engagement condition for a given transmission ratio that is obtained mathematically instead of experimentally. For the mathematically obtained function: pauses between the engagement statuses can be added, or a compensating term can be added or subtracted to the equations that estimate the start points of the relevant engagement statuses. Also, the methods for compensating for the inaccuracies of the function that estimates the engagement condition for a given transmission ratio due to rotational position adjustments of a torque transmitting member can be applied to all shafts of a CVT where rotational position adjustments of a torque transmitting member occur, such as the shaft on which the cone assembly is mounted of CVT 1.2 for example.
By using the function that estimates the engagement condition for a given transmission ratio and the information from the transmission ratio sensor, which for CVT 2.1 is transmission ratio sensor SN1B 131B, and the rotational position sensor(s) of the shaft(s) on which cone or cone assemblies with torque transmitting members are mounted, which for CVT 2.1 is rotational position sensor SN2E 132E, the controlling computer can be programmed so that it can determine the engagement status of the torque transmitting members as they are rotating. The engagement statuses of the torque transmitting members as described previously are: 1) only the first torque transmitting member is engaged, 2) the first torque transmitting member and the second torque transmitting member are engaged, 3) only the second torque transmitting member is engaged, 4) the second torque transmitting member and the first torque transmitting member are engaged. For CVT 2.1, the first torque transmitting member can be assigned to the torque transmitting member of cone assembly CS3C 23C and the second torque transmitting member can be assigned to the torque transmitting member of cone assembly CS3D 23D.
In order to account for the inaccuracy of the function that estimates the engagement condition for a given transmission ratio, wear, and other issues that might affect the controlling computer in accurately determining the correct engagement status, and the responsiveness of the controlling computer in controlling the movements of the adjuster(s), which direction of rotation in some instances have to be changed from one engagement status to the next if no pause engagement statuses are used, the following engagement statuses are used for all CVT's described in this disclosure unless otherwise stated: 1) only the first torque transmitting member is engaged, 2) the first torque transmitting member is engaged and the second torque transmitting member is about to come into engagement, 3) the first torque transmitting member and the second torque transmitting member are engaged, 4) the first torque transmitting member is about to come out of engagement and the second torque transmitting member is engaged, 5) only the second torque transmitting member is engaged, 6) the second torque transmitting member is engaged and the first torque transmitting member is about to come into engagement, 7) the second torque transmitting member and the first torque transmitting member are engaged, 8) the second torque transmitting member is about to come out of engagement and the first torque transmitting member is engaged. Engagement statuses 2, 4, 6, and 8 are referred to as pause engagement statuses, and it is recommended that no adjustment is provided during the pause engagement statuses. In order to obtain pause engagement statuses 2, 4, 6, and 8, several degrees of rotation are added, subtracted, or added and subtracted, which is recommended here, to the start point of engagement statuses 3, 5, 7, and 1. For example, in order to obtain engagement status 2, 3 degrees are added to and subtracted from the start point before the pause engagement statuses are added of engagement status 3, which is the start point of that engagement status situation for the set of engagement statuses where no pause is used (which is the start point of engagement status 2 of the set of engagement statuses that do not have a pause), the start point of engagement status 3 is going to change once pause engagement status 2 is added. So if here engagement status 3 starts at a rotational position of 255 degrees, then engagement status 2 starts at a rotational position of 252 degrees, which is 255−3 degrees and which is the end point of engagement status 1 after the pause engagement statuses have been added, and ends at a rotational position of 258 degrees, which is 255+3 degrees and which is the start point of engagement status 3 after the pause engagement statuses have been added, since the end point of the previous engagement status is the start point of the next engagement status. In order to obtain pause engagement statuses 4, 6, and 8, the same procedure is used where 3 degrees are added to and subtracted from the start point before the pause engagement statuses are added of their next engagement status, which is the start point of their next engagement status situation of the set of engagement statuses where no pause is used. So here in order to obtain pause engagement statuses 4, 3 degrees are added to and subtracted from the start point before the pause engagement statuses are added of engagement status 5 (which is the start point for engagement status 3 of the set of engagement statuses where no pause engagement statuses are used); in order to obtain pause engagement statuses 6, 3 degrees are added to and subtracted from the start point before the pause engagement statuses are added of engagement status 7 (which is the start point for engagement status 4 of the set of engagement statuses where no pause engagement statuses are used); and in order to obtain pause engagement statuses 8, 3 degrees are added to and subtracted from the start point before the pause engagement statuses are added of engagement status 1 (which is the start point for engagement status 1 of the set of engagement statuses where no pause engagement statuses are used). The amount of rotational degrees that are added and subtracted to obtain the pause engagement statuses can be estimated by estimating how inaccurate the function that estimates the engagement condition for a given transmission ratio is, how inaccurate the sensors used in determining the engagement condition, such as the rotational positions sensor(s), transmission ratio sensor, etc., are, how much play that affects the accuracy in determining the actual engagement condition does the system has, such as rotational play of the shafts or axial play of the transmission ratio changing mechanism, and other issues that affects the accuracy of the controlling computer in determining the actual engagement condition. The sources of inaccuracies of the previous sentence can then be added to obtain a conservative estimate for the amount of rotational degrees that need to be added and subtracted in order to obtain pause engagement statuses 2, 4, 6, and 8. The value for the amount of rotational degrees that need to be added and subtract can also be obtained experimentally or in conjunction with the value obtained from adding the sources of inaccuracies, which can be used as an initial value that can be refined through experimentation. In order to obtain the value for the amount of rotational degrees that need to be added and subtract (add/subtract value) experimentally, the following test run procedure can be used: first a test add/subtract value is selected arbitrarily, or the sources of inaccuracies described earlier is selected as the test add/subtract value, lets say the test add/subtract value is 5 degrees; then the CVT is run through all transmission ratios, which should be changed at different rates including the slowest and fastest transmission ratio changing rate for the system, for all operating speeds of the CVT. The longer the CVT is left running and the more times it is run through all transmission ratios, the better. While the CVT is running, no adjustments should be provided during the pause engagement statuses 2, 4, 6, and 8; and if adjustments are required during transmission ratio change, then the transmission ratio changing operation should be stopped during the pause engagement statuses 2, 4, 6, and 8. If flexing of the parts of the CVT can compensate for having no adjustments provided during the pause engagement statuses 2, 4, 6, and 8 despite the fact that the transmission ratio is changed, the transmission ratio changing operation does not need to be stopped during pause engagement statuses 2, 4, 6, and 8. Experimentation can be used to determine if this is the case, if in doubt the transmission ratio changing operation should be stopped during pause engagement statuses 2, 4, 6, and 8. For example, for CVT 2.1 adjustments to reduce/eliminate transition flexing should only be provided during engagement statuses 1 and 5, adjustments to increase the duration at which the transmission ratio can be changed should only be provided during engagement statuses 3 and 7; and if adjustments to allow transmission ration change are required during pause engagement statuses 2, 4, 6, and 8, then the transmission ratio changing operation should be stopped during the pause engagement statuses 2, 4, 6, and 8. If during the test run no issues occur, then 5 degrees can be used as the add/subtract value; if issues occur than a test add/subtract value greater than 5 degrees need to be tested until an add/subtract value at which the CVT can run with no issues is found; also if the CVT runs with no issues with a test add/subtract value of 5 degrees, then a smaller test add/subtract value can be tested such as 4.5 degrees for example, if there are no issues at this test add/subtract value than 4.5 degrees it can be used as the add/subtract value and another smaller test add/subtract value can be tested if desired, if issues occur than a test add/subtract value greater than 4.5 degrees needs to be tested. So the experimental method is basically a trial and error procedure to obtain the smallest add/subtract value at which the CVT can run with no issues. Obviously an add/subtract value greater than the smallest add/subtract value can be used, as to account for wear and other issues that might affect the accuracy of the system over time, so as to increases the robustness of the system. However an increase in the add/subtract value will reduce the duration at which the transmission ratio can be changed, and might increase the speed requirement of the adjuster used to reduce/eliminate transition flexing.
The engagement statuses for CVT 2.1, for which the first torque transmitting member is assigned to the torque transmitting member of cone assembly CS3C 23C and the second torque transmitting member is assigned to the torque transmitting member of cone assembly CS3D 23D, are: 1) only the torque transmitting member of cone assembly CS3C 23C is engaged, 2) the torque transmitting member of cone assembly CS3C 23C is engaged and the torque transmitting member of cone assembly CS3D 23D is about to come into engagement, 3) the torque transmitting member of cone assembly CS3C 23C and the torque transmitting member of cone assembly CS3D 23D are engaged, 4) the torque transmitting member of cone assembly CS3C 23C is about to come out of engagement and the torque transmitting member of cone assembly CS3D 23D is engaged, 5) only the torque transmitting member of cone assembly CS3D 23D is engaged, 6) the torque transmitting member of cone assembly CS3D 23D is engaged and the torque transmitting member of cone assembly CS3C 23C is about to come into engagement, 7) the torque transmitting member of cone assembly CS3D 23D and the torque transmitting member of cone assembly CS3C 23C are engaged, 8) the torque transmitting member of cone assembly CS3D 23D is about to come out of engagement and the torque transmitting member of cone assembly CS3C 23C is engaged. And the engagement statuses for the shaft of CVT 1.1 on which cone assembly CS2A 22A is mounted for which the first torque transmitting member is assigned to torque transmitting member CS2A-M122A-M1 and the second torque transmitting member is assigned to torque transmitting member CS2A-M222A-M2 are: 1) only torque transmitting member CS2A-M122A-M1 is engaged, 2) torque transmitting member CS2A-M122A-M1 is engaged and torque transmitting member CS2A-M222A-M2 is about to come into engagement, 3) torque transmitting member CS2A-M122A-M1 and torque transmitting member CS2A-M222A-M2 are engaged, 4) torque transmitting member CS2A-M122A-M1 is about to come out of engagement and torque transmitting member CS2A-M222A-M2 is engaged, 5) only torque transmitting member CS2A-M222A-M2 is engaged, 6) torque transmitting member CS2A-M222A-M2 is engaged and torque transmitting member CS2A-M122A-M1 is about to come into engagement, 7) torque transmitting member CS2A-M222A-M2 and torque transmitting member CS2A-M122A-M1 are engaged, 8) torque transmitting member CS2A-M222A-M2 is about to come out of engagement and torque transmitting member CS2A-M122A-M1 is engaged. From the examples and information given in this disclosure, somebody skilled in the art should be able to come up with the engagement statuses for a shaft on which two alternating torque transmitting members are used.
The engagement statuses described in the previous paragraph can be used to have the controlling computer of CVT 2.1 computer CP2122, properly control adjuster AD3103 as to reduce/eliminate transition flexing and increase the duration at which the transmission ratio can be changed. Adjustments to reduce/eliminate transition flexing should be provided when only one torque transmitting member is engaged with its transmission belt, as in engagement status 1) and engagement status 5); and adjustments to increase the duration at which the transmission ratio can be changed should be provided when more than one torque transmitting members are engaged (such as two torque transmitting members for example), as in engagement status 3) and engagement status 7). As described earlier, it is recommended that no adjustments are provided during the pause engagement statuses 2, 4, 6, and 8, so as to have a pause between the engagement status for which adjustments is to be provided if required. However, depending on the accuracy and responsiveness of the system, a CVT might be operated without a pause. So that for example, for CVT 2.1, instead of using the set of engagement statuses that consist of engagement statuses 1 to 8, which have pause engagement statuses, described in the previous paragraphs, the following set of engagement statuses, which do not have pause engagement statuses, can be used: 1) only the torque transmitting member of cone assembly CS3C 23C is engaged, 2) the torque transmitting member of cone assembly CS3C 23C and the torque transmitting member of cone assembly CS3D 23D are engaged, 3) only the torque transmitting member of cone assembly CS3D 23D is engaged, 4) the torque transmitting member of cone assembly CS3D 23D and the torque transmitting member of cone assembly CS3C 23C are engaged. This set of engagement statuses is identical to the set of engagement statuses of the torque transmitting members that does not have pause engagement statuses, described previously, which are: 1) only the first torque transmitting member is engaged, 2) the first torque transmitting member and the second torque transmitting member are engaged, 3) only the second torque transmitting member is engaged, 4) the second torque transmitting member and the first torque transmitting member are engaged; for which the first torque transmitting member is assigned to the torque transmitting member of cone assembly CS3C 23C and the second torque transmitting member is assigned to the torque transmitting member of cone assembly CS3D 23D. If it is desired to use the set of engagement statuses that consist of engagement statuses 1 to 4, which do not have pause engagement statuses, then an experimental test run should be performed to make sure that the CVT can be operated without a pause. An example of an experimental test run is as follows: the CVT is run through all transmission ratios, which should be changed at different rates including the slowest and fastest transmission ratio changing rate for the system, for all operating speeds of the CVT. The longer the CVT is left running and the more times it is run through all transmission ratios, the better. While the CVT is run, adjustments, if required should be provided during all engagement statuses. If during the experimental test run no issues occur, than those engagement statuses can be used. However, it is recommended that pause engagement statuses are used; since they can increase the robustness of the system, so that it is more resistant to failure.
Also for the set of engagement statuses that consist of engagement statuses 1 to 4, which do not have pause engagement statuses, if used for CVT 2.1, if the controlling computer provides inaccurate adjustments to reduce/eliminate transition flexing during engagement statuses 1 and 3 (during which only one torque transmitting member is engaged with its transmission belt) than improper engagement between a torque transmitting member and its transmission belt can occur. This is very undesirable since it can cause a malfunction of the system and/or even damage the system. And if the controlling computer, provides inaccurate adjustments to compensate for transmission ratio change rotation during engagement statuses 2 and 4 (during which two torque transmitting members are engaged with their transmission belt) than stalling or slipping of the adjustment providing adjuster and transmission ratio changing actuator will occur. This should not cause a malfunction of the system and is not so damaging, if it is damaging at all, to the system. One method to reduce the chance that inaccurate adjustments to reduce/eliminate transition flexing are provided during engagement statuses 1 and 3, is by increasing the duration of engagement statuses 1 and 3 by having engagement statuses 1 and 3 start earlier than their actual predicted/calculated start point and end later than their actual predicted/calculated end point so as to ensure that adjustments to reduce/eliminate transition flexing are provided during engagement statuses 1 and 3 despite the inaccuracy of the function that estimates the engagement condition for a given transmission ratio, wear, and other issues that might affect the controlling computer in accurately determining the correct engagement status. In order to obtain the amount of rotational degrees that engagement statuses 1 and 3 need to start earlier than their actual predicted/calculated start point, and end later than their actual predicted/calculated end point, experimental test runs similar to the ones performed to obtain the add/subtract value for pause engagement statuses 2, 4, 6, and 8 can be performed. The smallest amount of rotational degrees that engagement statuses 1 and 3 need to start earlier than their actual predicted/calculated start point, and end later than their actual predicted/calculated end point such that no issues during the test runs occur, can be increased to account for wear and other issues that might affect the accuracy of the system over time, so as to increases the robustness of the system. However an increase in the amount of rotational degrees that engagement statuses 1 and 3 start earlier and end later will reduce the duration at which the transmission ratio can be changed. The approach of increasing the duration of the engagement statuses for which correct adjustments are critical can be used for other sets of engagement statuses, where this is useful. Other modifications can also be performed on the sets of engagement statuses described earlier, and other sets of engagement statuses can also be derived. The engagement statuses are simply a tool to identify the rotational positions of a shaft at which different actions/adjustments need to be provided.
For proper operation the adjuster(s) need to be fast enough so that it can provide proper adjustments to reduce/eliminate transition flexing during the duration of the respective engagement statuses described previously. The required speed for the adjuster can be estimated by first estimating the minimum duration at which adjustment can be provided. The minimum duration at which adjustment can be provided can be estimated by first estimating “the minimum duration of one revolution”, which can be estimated by: dividing 1 by (the sum of “the maximum rpm of the shaft on which the cone assemblies are mounted” plus “the maximum speed of transmission ratio change rotation”, which will be discussed latter). From “the minimum duration of one revolution”, “the minimum duration for adjustment” can be estimated by: multiplying “the minimum duration of one revolution” by (“the minimum angle the shaft on which the cone assemblies are mounted can be rotated so that only one torque transmitting member is engaged in degrees” minus “the maximum amount of adjustments needed in degrees”), and then dividing that value by 360 degrees. From “the minimum duration for adjustment”, “the minimum required speed of the adjuster” can be estimated by: dividing “the maximum amount of adjustments needed” by “the minimum duration for adjustment”. However, it is recommended that the minimum required speed of the adjuster to reduce/eliminate transition flexing is considerably faster than the estimation above. Also the minimum required speed of the adjuster(s) is determined by the minimum required speed of the adjuster to reduce/eliminate transition flexing and by the minimum required speed of the adjuster to compensate for transmission ratio change rotation, which can be obtained through experimentation. If the minimum required speed of the adjuster to compensate for transmission ratio change rotation is faster than the minimum required speed of the adjuster to reduce/eliminate transition flexing than that minimum required speed criteria should determine the minimum required speed for the adjuster. The minimum required speed for the adjuster can also be verified/determined by performing an experimental test run that ensures that the speed of the adjuster is fast enough such that the CVT can perform with no issues for a given test speed of an adjuster. An example of an experimental test run is as follows: the CVT is run through all transmission ratios, which should be changed at different rates including the slowest and fastest transmission ratio changing rate for the system, for all operating speeds of the CVT. The longer the CVT is left running and the more times it is run through all transmission ratios, the better. While the CVT is run, adjustments, if required should be provided during all engagement statuses.
Also, from the transmission ratio sensor, the controlling computer, computer CP2122, can determine the axial position of the torque transmitting members on the surface of their respective cones and from there the arc length of the critical non-torque transmitting arc, which is the surface of the cone assembly about to be engaged, which is not covered by the torque transmitting member and is about to be covered by its transmission belt. This of course assumes that the entire torque transmitting member is toothed. If the torque transmitting member has a portion or portions that are not toothed, such as an extension, than those portions are part of the critical non-torque transmitting arc. Also here it is obviously assumed that the end portions of the torque transmitting member consist of a complete tooth shape. A complete tooth shape of a torque transmitting member or transmission pulley, which width is the width of a tooth, wt, can be represented by a tooth shape that starts at the midpoint of a space between two teeth and ends at an adjacent midpoint of a space between two teeth. If the end portions of the torque transmitting member do not consists of a complete tooth shape, then appropriate adjustments have to be made to the critical non-torque transmitting arc. For example, if one end portion of the torque transmitting member, which is forming one end of the critical non-torque transmitting arc, consists of a ⅔ complete tooth shape, than the other ⅓ of that tooth shape should be considered as part of the torque transmitting member instead of part of the critical non-torque transmitting arc so that the arc length of that ⅓ of a complete tooth shape should be subtracted from the arc length of critical non-torque transmitting arc.
A cone assembly can be viewed as a partial gear, which pitch-line is located at the neutral-axis or bending-axis of its torque transmitting member, which in most cases is also where the height center-line of the teeth of its torque transmitting member is located; so that the pitch-line of its transmission belt or chain should also be located at the neutral-axis or bending-axis of the transmission belt or chain. For the transmission belt described in the Alternate CVT's section of this disclosure, its pitch-line is located at the center of the pins, which when engaged with its torque transmitting member coincides with the pitch-line of its torque transmitting member. For a series of gears with different diameters of the same pitch, the width of a tooth, wt, remains constant at the pitch-line of the gears, which for a gear and transmission pulleys form the shape of a circle. Since for a cone assembly, the pitch of the teeth of its torque transmitting member should also remain constant as the diameter of the torque transmitting member is changed, here the width of a tooth, wt, should also remains constant at the pitch-line of the torque transmitting member as the diameter of the torque transmitting member is changed. Also, when a torque transmitting member is fully engaged with its transmission belt, the pitch-line of the torque transmitting member and the pitch-line of the transmission belt should coincide.
In order to have a width of a tooth, wt, value that remains constant for different diameters of the torque transmitting members, the length of the critical non-torque transmitting arc should be measured at the pitch-line of the torque transmitting member of its cone assembly; so that the width of a tooth, wt, as shown on the vertical-axis and horizontal-axis of the graphs in FIGS. 21A/B/C corresponds to the width of a tooth as measured at that pitch-line. As described earlier, a complete tooth shape, which width is the width of a tooth, wt, can be represented by a tooth shape that starts at the midpoint of a space between two teeth and ends at an adjacent midpoint of a space between two teeth; this is true regardless circumferential-line used to measure the arc length of the critical non-torque transmitting arc.
Obviously, the arc length of the critical non-torque transmitting arc can be measured at a different circumferential-line, but then the width of a tooth, wt, as shown on the vertical-axis and horizontal-axis of the graphs in FIGS. 21A/B/C should also be measured at the circumferential-line at which the length of the critical non-torque transmitting arc is measured. And if the circumferential-line of measurement does not coincide with the pitch-line, the width of a tooth changes as the transmission ratio is changed. For optimum performance, the controlling computer, computer CP2122, should be programmed so that it can determine or estimate the width of a tooth at each transmission ratio. A competent engineer should be able do determine the equation that determines or estimates the width of a tooth at a desired circumferential-line as a function of the diameter of its torque transmitting member, which can be derived from the fact that the width of a tooth at a desired circumferential-line is: “the width of a tooth at the neutral-axis of the torque transmitting member” multiplied by “the radius of the desired circumferential-line” divided by “the radius of the neutral-axis of the torque transmitting member”. Once the equation that determines or estimates the width of a tooth at a desired circumferential-line as a function of the diameter of its torque transmitting member is obtained, it can be programmed into the controlling computer so that it can determine the width of a tooth, wt, at each transmission ratio. However, unless otherwise stated for this disclosure the length of the critical non-torque transmitting arc is always measured at the pitch-line of the torque transmitting member of its cone assembly and consequently, the width of a tooth, wt, is also always measured at the pitch-line of the torque transmitting member of its cone assembly.
In order to reduce/eliminate transition flexing, a controlling computer first determines the arc length of the critical non-torque transmitting arc from the transmission ratio sensor if it is a CVT 2.1, and from the transmission ratio sensor and the sensors that monitor the rotational position of one torque transmitting member relative to the other of the cone(s) for which the rotational position between the torque transmitting members is adjusted if it is a CVT 1.1. From the arc length of the critical non-torque transmitting arc, the controlling computer than uses a graph from the graphs of FIGS. 21A/B/C to determine the adjustment required to reduce/eliminate transition flexing. In order to provide accurate adjustments, the adjustment provided should be monitored. This can be done by first determining the angular adjustment provided by using sensor(s) that monitor the rotational position of the first torque transmitting member relative to the second torque transmitting member of the cones for which adjustment to reduce/eliminate transition flexing is to be provided for a CVT 1.1 for example, or by using sensors that monitor the rotational position of one transmission pulley relative to the other transmission pulley for a CVT 2.1 for example; from the angular adjustment provided the arc length adjustment, which should be monitored, can be calculated by the controlling computer by also using the pitch-line radius of the item the adjuster is rotating; for a transmission pulley, the pitch-line radius is fixed, for a single tooth or torque transmitting member a correlation (equation/function) between a transmission ratio and the pitch-line radius of a single tooth/torque transmitting member for that transmission ratio, for all transmission ratios of the CVT can be programmed into the controlling computer so that the controlling computer can use the transmission sensor to determine current the pitch-line radius of the single tooth/torque transmitting member; and from the pitch-line radius, the controlling computer can the convert angular adjustments into arc length adjustments; also the direction (clockwise or counter-clockwise) that the adjustment is provided should be monitored by the controlling computer; more details regarding these items are provided in other paragraphs of this disclosure. Also, adjustment to reduce/eliminate transition flexing should only be provided when only one torque transmitting member is engaged (transmitting torque). In order to know when to provide adjustment, the controlling computer should monitor the rotational position of the cone(s) for which adjustments to reduce/eliminate transition flexing is to be provided, which can be done using rotational position sensors. The rotational position of the cones can then be categorized into engagement statuses, which if used, should be programmed into the controlling computer such that the controlling computer only provides adjustment to reduce/eliminate transition flexing at the proper engagement statuses (for which having only one transmitting member engaged should be a requirement under normal operating condition).
Using the description from the previous paragraph and additional details provided in this disclosure, for a CVT 2.1, somebody skilled in the art should be able to program and set-up the controlling computer, computer CP2122, and the required sensors, such that computer CP2122 is able to control adjuster AD3103 to reduce/eliminate transition flexing. Using the description from the previous paragraph and additional details provided in this disclosure, somebody skilled in the art should also be able to program and set-up the controlling computer, including the required sensors, of other CVT's, such as CVT 1.1, CVT 1.2, CVT 2.2, CVT 2.3, CVT 2.4, CVT 2.5, any other CVT described in this disclosure, or any other CVT where this is applicable, such that the controlling computer is able to control the dedicated adjuster(s) to reduce/eliminate transition flexing.
The engagement statuses can also be used when adjuster AD3103 is used to increase the duration at which the transmission ratio can be changed. Also, for the set of engagement statuses that use pause engagement statuses, pause engagement statuses 2, 4, 6, and 8, can act as transition engagement statuses where the adjuster(s) and the transmission ratio changing actuator, if required, perform no operation so that they can come to a halt so that they are ready to perform their next task.
For the cones and cone assemblies of this disclosure, in instances where the space between the torque transmitting members, of a cone or cone assembly or of a pair of cones or cone assemblies, that is about to be completely covered by its transmission belt(s) is not a multiple of the width of a tooth of the teeth of the torque transmitting members, the cone assemblies resemble a sprocket where the number of teeth is not an integer so that it has a partial tooth, such as sprocket with 5¼ teeth, 7⅛ teeth, or 3⅓ teeth for example; where the partial tooth is removed and does not physically engage with the chain of the sprocket; and for which the partial tooth is about to be imaginarily engaged with its chain. Here the tooth positioned immediately after the partial tooth will not properly engage with its chain so that transition flexing will occur. Since that tooth will either be too early or too late relative to its chain. For CVT 1.1, looking at
A similar adjustment method used for a CVT 1, such as CVT 1.1, can also be for a CVT 2, such as CVT 2.1. The required adjustment for a given arc length of the critical non-torque transmitting arc for CVT 1.1 and CVT 2.1 is identical. However, while for CVT 1.1 the rotational position of a torque transmitting member about to be engaged relative to its transmission belt is adjusted, which is achieved by adjusting the rotational position of one torque transmitting member relative to the other, for CVT 2.1 the rotational position of the transmission belt about to be engaged relative to its torque transmitting member is adjusted, which is achieved by adjusting the rotational position of one transmission pulley relative to the other. Depending on the context where it is used, the word relative as in adjusting the rotational position of part A relative to part B can mean that the adjustment is achieved by rotating only part A, as is the case in the sentence ( . . . for CVT 1.1 the rotational position of a torque transmitting member about to be engaged relative to its transmission belt is adjusted . . . ) and the sentence ( . . . for CVT 2.1 the rotational position of the transmission belt about to be engaged relative to its torque transmitting member is adjusted . . . ) of the previous paragraph, where the rotational position of part B is by design not adjusted; or it can mean that the adjustment is achieved by rotating either part A or part B, which is the case in the sentence ( . . . adjusting the rotational position of one torque transmitting member relative to the other . . . ) and the sentence ( . . . adjusting the rotational position of one transmission pulley relative to the other . . . ), where the configuration for which adjustment is achieved by rotating part A will not significantly change from the configuration for which adjustment is achieved by rotating part B. In order to provide correct adjustments to reduce/eliminate transition flexing for the same critical non-torque transmitting arc, the relative rotational positional adjustment between a torque transmitting member and its transmission belt for CVT 1.1 and CVT 2.1 are identical. For example, for a given critical non-torque transmitting arc, if for CVT 1.1 the torque transmitting member about to be engaged has to be rotated clockwise relative to its transmission belt in order to eliminate transition flexing so as to trying to achieve perfect engagement; then in order to provide the same relative rotational positional adjustment between a torque transmitting member and its transmission belt for CVT 2.1, for CVT 2.1 the transmission belt about to be engaged has to be rotated counter-clockwise relative to its torque transmitting member by the same amount. Obviously since CVT 2.1 has two transmission belts, while CVT 1.1 only has one, for CVT 2.1 before any adjustment is made, the teeth of its transmission belts need to be aligned so that they resemble one transmission belt; in other words, the angle between the teeth of one transmission pulley relative to the other needs to be 0 degrees. Also for CVT 1.1, the arc length of the critical non-torque transmitting arc is the space between the torque transmitting members that is about to be covered by its transmission belt, if the same adjustment method used for CVT 1.1 is used for CVT 2.1, then the corresponding arc length of the critical non-torque transmitting arc needs to be used for CVT 2.1; so that for CVT 2.1 the arc length of the critical non-torque transmitting arc is also the space between the torque transmitting members, which should be measured at the pitch-line of the torque transmitting members, that is about to be covered by its transmission belts. Since for CVT 2.1 the rotational position of one torque transmitting member relative to the other torque transmitting member is fixed and one torque transmitting member should be positioned exactly opposite of the other torque transmitting member (the torque transmitting members are positioned 180 degrees apart), the arc length of the critical non-torque transmitting arc for a given transmission ratio is simply: {“the entire circumference (360 degrees) of either the cone for cone assembly CS3C 23C or the cone for cone assembly CS3D 23D as measured at the pitch-line of its torque transmitting member for that given transmission ratio” minus “the arc length of the torque transmitting member of cone assembly CS3C 23C as measured at the pitch-line of that torque transmitting member for that given transmission ratio” minus “the arc length of the torque transmitting member of cone assembly CS3D 23D as measured at the pitch-line of that torque transmitting member for that given transmission ratio”} divided by “two”. By using the transmission ratio sensor and the equation of the previous sentence, somebody skilled in the art should be able to set-up the controlling computer such that it can determine the arc length of the critical non-torque transmitting arc for each given transmission ratio of the CVT. Additional information regarding this are provided in other paragraphs of this disclosure. As for CVT 1.1, for CVT 2.1 the graphs shown in
A slightly different approach to reduce/eliminate transition flexing than the one described in the previous paragraph is the approach to reduce/eliminate transition flexing that is referred to as the “adjustment phase” method, which involve values such as the “phase for cone assembly CS3C 23C”, “phase for cone assembly CS3D 23D”, “phase arc length for cone assembly CS3C 23C”, and “phase arc length for cone assembly CS3D 23D” values. The “adjustment phase” method will be described specifically in the next 9 paragraphs below.
For a CVT 2.1, in order to reduce/eliminate transition flexing, the rotational position of transmission pulley PU1C 41C relative to transmission pulley PU1D 41D needs to be monitored by the controlling computer, computer CP2122. In order to achieve this, rotational position sensor SN2C 132C and rotational position sensor SN2D 132D (from which the rotational position of the adjuster mounted transmission pulley relative to the rotational position of the unadjusted transmission pulley can be determined by: subtracting “the measured rotation of the unadjusted transmission pulley” from “the measured rotation of the adjuster mounted transmission pulley”), or a relative rotational position sensor that monitors the rotation between the adjuster body and the adjuster output member of adjuster AD3103 can be used. The relative rotational position sensor can also utilize the sensor wheel and counter described previously. In addition, adjuster AD3103 should be connected to the controlling computer so that the controlling computer knows the direction the adjuster is rotating one transmission pulley relative to the other, such as rotating transmission pulley PU1D 41D clockwise relative to transmission pulley PU1C 41C, or rotating transmission pulley PU1D 41D counter-clockwise relative to transmission pulley PU1C 41C for example. Two values from the data from the rotational position sensors or the relative rotational position sensor should be determined and monitored by the controlling computer. The first value is the “phase for cone assembly CS3C 23C” value; this value represents the phase between the torque transmitting member of cone assembly CS3C 23C and its transmission belt. The second value is the “phase for cone assembly CS3D 23D” value; this value represents the phase between the torque transmitting member of cone assembly CS3D 23D and its transmission belt. In order to determine the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D” values, first the angular value (such as in degrees or radians) for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley needs to be determined. Once this value is obtained, it should be used to program the controlling computer so that the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D” values are zero when the teeth of one transmission pulley are aligned with the teeth of the other transmission pulley, and reset to zero each time the adjuster has rotated one transmission pulley relative to the other transmission pulley such that the teeth of the transmission pulleys are aligned again. And for all other relative rotational positions between the transmission pulleys, the controlling computer via the data from the rotational position sensors or relative rotational position sensor should determine the angle (such as in degrees or radians) a transmission pulley has been rotated relative to the other transmission pulley. For the “phase for cone assembly CS3C 23C” value, if the rotational position of transmission pulley PU1C 41C is adjusted relative to the rotational position of transmission pulley PU1D 41D, so that its transmission belt, transmission belt BL2C 32C, is moved away from its torque transmitting member, torque transmitting member CS3C-M123C-M1, which is about to be engaged, which for a configuration of CVT where the transmission pulleys are rotating clockwise corresponds to adjustments where transmission pulley PU1C 41C is rotated counter-clockwise relative to transmission pulley PU1D 41D, a positive value is assigned for the angle measurement (such as in degrees or radians) that transmission pulley PU1C 41C has been rotated relative to transmission pulley PU1D 41D from an initial position where the teeth of the transmission pulleys are aligned. As described above, this angle measurement resets to zero each time the teeth of the transmission pulleys are aligned again. This angle measurement is the value for the “phase for cone assembly CS3C 23C” value. So basically, the “phase for cone assembly CS3C 23C” represents the angle between the teeth of transmission pulley PU1C 41C and the teeth of transmission pulley PU1D 41D where the teeth of transmission pulley PU1C 41C are positioned behind the teeth of transmission pulley PU1D 41D according to the direction the transmission pulleys are rotating. Also, for the “phase for cone assembly CS3C 23C” value, if the rotational position of transmission pulley PU1C 41C is adjusted relative to the rotational position of transmission pulley PU1D 41D so that its transmission belt, transmission belt BL2C 32C, is moved towards its torque transmitting member, torque transmitting member CS3C-M123C-M1, which is about to be engaged, which for a configuration of a CVT where the transmission pulleys are rotating clockwise corresponds to adjustments where transmission pulley PU1C 41C is rotated clockwise relative to transmission pulley PU1D 41D, the “phase for cone assembly CS3C 23C” value is obtained by subtracting “the angle measurement transmission pulley PU1C 41C has been rotated relative to transmission pulley PU1D 41D from an initial position where the teeth of the transmission pulleys are aligned (also a positive value)” from “the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next rotational position where its teeth are aligned with the teeth of the other transmission pulley”. Also in case the transmission pulleys are rotating counter-clockwise, then in order to move the transmission belt for cone assembly CS3C 23C away from its torque transmitting member which is about to be engaged, transmission pulley PU1C 41C has to be rotated clockwise relative to transmission pulley PU1D 41D; and in case the transmission pulleys are rotating counter-clockwise, then in order to move the transmission belt for cone assembly CS3C 23C towards its torque transmitting member which is about to be engaged, transmission pulley PU1C 41C has to be rotated counter-clockwise relative to transmission pulley PU1D 41D. In this paragraph, regarding the terms moved away and moved towards, moved away means that the transmission belt about to be engaged is rotated in the opposite direction the cone assemblies are rotating; and moved towards means that the transmission belt about to be engaged is rotated in the direction the cone assemblies are rotating. Also in instances where the transmission ratio is increased, the arc length of the critical non-torque transmitting arc increases in proportion to the transmission ratio increase; here it can be observed that while the arc length of the critical non-torque transmitting arc is increased from a length that is a multiple of the width of a tooth, wt, of its torque transmitting member, its transmission belt, which is about to be engaged, has to be proportionally moved away from its torque transmitting member to compensate for the increase in the arc length of the critical non-torque transmitting arc in order to avoid transition flexing. Similarly, in instances where the transmission ratio is decreased, the arc length of the critical non-torque transmitting arc decreases in proportion to the transmission ratio decrease; here it can be observed that while the arc length of the critical non-torque transmitting arc is decreased from a length that is a multiple of the width of a tooth, wt, of its torque transmitting member, its transmission belt, which is about to be engaged, has to be proportionally moved towards its torque transmitting member to compensate for the decrease in the arc length of the critical non-torque transmitting arc in order to avoid transition flexing. The “phase for cone assembly CS3D 23D” value represents the angle between the teeth of transmission pulley PU1D 41D and the teeth of transmission pulley PU1C 41C where the teeth of transmission pulley PU1D 41D are positioned behind the teeth of transmission pulley PU1C 41C according to the direction the transmission pulleys are rotating. The method to obtain the “phase for cone assembly CS3D 23D” is identical to the method to obtain the “phase for cone assembly CS3C 23C”. So here if transmission pulley PU1D 41D is rotated in the opposite direction the cone assemblies are rotating relative to transmission pulley PU1C 41C (moved away), the “phase for cone assembly CS3D 23D” is the angle measurement transmission pulley PU1D 41D has been rotated relative to transmission pulley PU1C 41C from an initial position where the teeth of the transmission pulleys are aligned (a positive value). Like the “phase for cone assembly CS3C 23C”, the “phase for cone assembly CS3D 23D” resets to zero each time the adjuster has rotated one transmission pulley relative to the other transmission pulley such that the teeth of the transmission pulleys are aligned again. And if transmission pulley PU1D 41D is rotated in the direction the cone assemblies are rotating relative to transmission pulley PU1C 41C (moved towards), the “phase for cone assembly CS3D 23D” value is obtained by subtracting “the angle measurement transmission pulley PU1D 41D has been rotated relative to transmission pulley PU1C 41C from an initial position where the teeth of the transmission pulleys are aligned (also a positive value)” from “the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley”. Also all values for the “phase for cone assembly CS3C 23C” value and “phase for cone assembly CS3D 23D” value are positive.
Regarding the “phase for cone assembly CS3C 23C” value and the “phase for cone assembly CS3D 23D” value, in this paragraph some equations that can be used by the controlling computer to determine the phases are presented; these equations can be used if only one adjuster is used to adjust the rotational position of one transmission pulley or if the rotational positions of both transmission pulleys are adjusted by an adjuster each (two adjusters are used). The first equation is: rotational positioning of transmission pulley PU1C 41C such that its transmission belt is moved away from its torque transmitting member=amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member—amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member. The second equation is: rotational positioning of transmission pulley PU1D 41D such that its transmission belt is moved away from its torque transmitting member=amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member—amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member. For the terms “amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member” and “amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member” of the first and second equation, if the transmission pulleys are rotated in the opposite direction indicated, such is the case when a transmission belt is moved towards instead of moved away of its torque transmitting member, then a negative sign is added to the magnitude of those terms; so the term: amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member=—amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved towards its torque transmitting member (a positive value), and the term: amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member=—amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved towards its torque transmitting member (a positive value). Also the initial position for the first equation and the second equation is the position where the teeth of transmission pulley PU1C 41C and the teeth of transmission pulley PU1D 41D are aligned; at the initial position all terms for the first equation and the second equation are zero, and all terms for the first equation and the second equation should reset to zero once the teeth of transmission pulley PU1C 41C and the teeth of transmission pulley PU1D 41D are aligned again. From the first and second equation, the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D” values can be obtained. The equation for the “phase for cone assembly CS3C 23C” value is: phase for cone assembly CS3C 23C=rotational positioning of transmission pulley PU1C 41C such that its transmission belt is moved away from its torque transmitting member, with two conditions; the first condition is: phase for cone assembly CS3C 23C=0, when the teeth of the transmission pulleys are aligned, here the phase for cone assembly CS3C 23C is zero when the teeth of the transmission pulleys are aligned, and the phase for cone assembly CS3C 23C resets to zero each time the teeth of the transmission pulleys are aligned again, this condition should be automatically satisfied due to the fact that all terms of the first equation and all terms of the second equation are zero when the teeth of the transmission pulleys are aligned and reset to zero each time the teeth of the transmission pulleys are aligned again; and the second condition is: for negative values of the term “rotational positioning of transmission pulley PU1C 41C such that its transmission belt is moved away from its torque transmitting member”, the equation for the “phase for cone assembly CS3C 23C” value is: phase for cone assembly CS3C 23C=“the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next rotational position where its teeth are aligned with the teeth of the other transmission pulley”+“rotational positioning of transmission pulley PU1C 41C such that its transmission belt is moved away from its torque transmitting member (a negative value)”; and the equation for the “phase for cone assembly CS3D 23D” value is: phase for cone assembly CS3D 23D=rotational positioning of transmission pulley PU1D 41D such that its transmission belt is moved away from its torque transmitting member, with two conditions; the first condition is: phase for cone assembly CS3D 23D=0, when the teeth of the transmission pulleys are aligned, here the phase for cone assembly CS3D 23D is zero when the teeth of the transmission pulleys are aligned, and the phase for cone assembly CS3D 23D resets to zero each time the teeth of the transmission pulleys are aligned again, this condition should be automatically satisfied due to the fact that all terms of the first equation and all terms of the second equation are zero when the teeth of the transmission pulleys are aligned and reset to zero each time the teeth of the transmission pulleys are aligned again; and the second condition is: for negative values of the term “rotational positioning of transmission pulley PU1D 41D such that its transmission belt is moved away from its torque transmitting member”, the equation for the “phase for cone assembly CS3D 23D” value is: phase for cone assembly CS3D 23D=“the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next rotational position where its teeth are aligned with the teeth of the other transmission pulley”+“rotational positioning of transmission pulley PU1D 41D such that its transmission belt is moved away from its torque transmitting member (a negative value)”. Also, from the “phase for cone assembly CS3C 23C” value, the “phase for cone assembly CS3D 23D” value can be obtained using the following equation: “phase for cone assembly CS3C 23C”=“the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next rotational position where its teeth are aligned with the teeth of the other transmission pulley”−“phase for cone assembly CS3D 23D”; likewise, from the “phase for cone assembly CS3D 23D” value, the “phase for cone assembly CS3C 23C” value can be obtained using the following equation: “phase for cone assembly CS3D 23D”=“the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next rotational position where its teeth are aligned with the teeth of the other transmission pulley”−“phase for cone assembly CS3C 23C”. All equations and their conditions, if applicable, presented in this paragraph can be programmed into the controlling computer so that the controlling computer can determine the “phase for cone assembly CS3C 23C” value and the “phase for cone assembly CS3D 23D” value from the rotations of transmission pulley PU1C 41C and the rotations transmission pulley PU1D 41D, it is recommended that if the rotations of transmission pulley PU1C 41C, which is used for the term “amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member”, is determined using a rotational position sensor, which is a sensor that monitors the rotational position of a transmission pulley relative to a static frame, then the rotations of transmission pulley PU1D 41D, which is used for the term “amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member”, is also determined using a rotational position sensor; and it is also recommended that if the rotations of transmission pulley PU1C 41C, which is used for the term “amount of rotation of transmission pulley PU1C 41C in the direction such that its transmission belt is moved away from its torque transmitting member”, is determined using a relative rotational position sensor, which is a sensor that monitors the rotational position of a transmission pulley relative to the shaft on which it is mounted, then the rotations of transmission pulley PU1D 41D, which is used for the term “amount of rotation of transmission pulley PU1D 41D in the direction such that its transmission belt is moved away from its torque transmitting member”, is also determined using a relative rotational position sensor, unless only the rotational position relative to its shaft of one transmission pulley is adjusted, in which case only the relative rotational position of the transmission pulley which rotational position is adjusted needs to be monitored by a relative rotational position sensor; also, since the “phase for cone assembly CS3C 23C” value can be obtained from the “phase for cone assembly CS3D 23D” value from one of the equation presented in this paragraph, and vice-versa, if desired only the equations for one phase can be programmed into the controlling computer, and the value for the other phase can be obtained from the phase which equations are programmed into the controlling computer using the equation from which the value for the other phase can be obtained from the value of the phase which equations are programmed into the controlling computer. All terms of all equations presented in this paragraph should have the same units; for example, if one term uses the unit degrees, than all terms should use the unit degrees; likewise, if one term uses the unit radians, than all terms should use the unit radians.
In order to ensure that the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D” values are zero when the teeth of the transmission pulleys are aligned, and reset to zero each time the teeth of the transmission pulleys are aligned again, a sensor that senses when the teeth of the transmission pulleys are aligned can be used by the controlling computer. An example of such a sensor consists of a reflector disk mounted on one transmission pulley and a light source with a light sensor fixed on the other transmission pulley. For the reflector disk one reflector is positioned under each tooth of its transmission pulley, while the light source with a light sensor is positioned under one tooth of its transmission pulley. In instances where the teeth of the transmission pulleys are aligned, the light source with a light sensor is aligned with a reflector of the reflector disk such that the light from the light source is reflected back to the light sensor and this triggers a signal that lets the controlling computer know that the teeth of the transmission pulleys are aligned. In instances where the teeth of the transmission pulleys are not aligned, the light source with a light sensor will not be aligned with a reflector of the reflector disk such that the light from the light source will not be reflected back to the light sensor and no signal that lets the controlling computer know that the teeth of the transmission pulleys are aligned will be send to the controlling computer so that the controlling computer assumes that the teeth of the transmission pulleys are not aligned. If the sensor introduced in this paragraph is not used, then the controlling computer has to continually monitor the rotational positional adjustments performed on the transmission pulley(s) and continually calculate whether the teeth of the transmission pulleys are aligned or not. If the teeth of the transmission pulleys are aligned at the initial position, which should be the case, then the teeth of the transmission pulleys are aligned when the following result is obtained for the first equation of the previous paragraph: rotational positioning of transmission pulley PU1C 41C such that its transmission belt is moved away from its torque transmitting member=0; and the following result is obtained for the second equation of the previous paragraph: rotational positioning of transmission pulley PU1D 41D such that its transmission belt is moved away from its torque transmitting member=0. When the results of the first equation and of the second equation of the previous paragraph are as stated in the previous sentence, then all terms of the first equation and the second equation should reset to zero, so that all terms of the first equation and second equation are zero when the teeth of the transmission pulleys are aligned. Obviously no system is fail prove, hence there is a chance that the controlling computer losses count and hence don't know the rotational position of one transmission pulley relative to the other, or there is also a chance that the sensors used to determine the rotational or relative rotational position of the transmission pulley(s) fail; hence in applications where reliability is important, such as in most vehicles for example, then it is recommended that the sensor introduce in this paragraph or a different sensor that can determine whether the teeth of the transmission pulley are aligned or not is used.
From the angular values for the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D” and the pitch-line diameters of the transmission pulleys, the controlling computer should continuously calculate and monitor the corresponding arc lengths of the “phase for cone assembly CS3C 23C” and the “phase for cone assembly CS3D 23D”. The corresponding arc length for the “phase for cone assembly CS3C 23C” will be referred to as the “phase arc length for cone assembly CS3C 23C” and the corresponding arc length for the “phase for cone assembly CS3D 23D” will be referred to as the “phase arc length for cone assembly CS3D 23D”. A corresponding arc length for a given phase, such as the “phase for cone assembly CS3C 23C” or the “phase for cone assembly CS3D 23D”, can be obtained by dividing “the phase measured in degrees” by “360 degrees”, and then multiplying “that value” by “the circumference of the pitch-line of the transmission pulley which rotational position is adjusted”. The pitch-line of a transmission pulley should coincide with the pitch-line of the portion of its transmission belt that is fully engaged with that transmission pulley. And for the same CVT, the width of a tooth, wt, as measured at the pitch-line of the transmission pulleys (which is an arc length) should be identical to the corresponding width of a tooth, wt, as measured at the pitch-line of its transmission belt (regarding the word corresponding: for an involute tooth shape of a torque transmitting member or a transmission pulley that starts at the midpoint of a space between two teeth and ends at an adjacent midpoint of a space between two teeth, the corresponding tooth shape of its transmission belt starts at the midpoint of a peak of a tooth and ends at an adjacent midpoint of a peak of a tooth; here while engaged, a midpoint of a peak of a tooth of a transmission belt should be positioned in a space between two teeth of its torque transmitting member), and the width of a tooth, wt, as measured at the pitch-line of its torque transmitting member (which is also an arc length). The width of a tooth, wt, of the previous sentence should correspond to the width of a tooth, wt, as shown in the graphs of FIGS. 21A/B/C. Also, the corresponding arc length value for: “the angular value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley” should correspond to the width of a tooth, wt, as shown in the graphs of FIGS. 21A/B/C; using this fact, the “phase arc length for cone assembly CS3C 23C” and the “phase arc length for cone assembly CS3D 23D” can be obtained from their respective phase measured in degrees, which is either the “phase for cone assembly CS3C 23C” or the “phase for cone assembly CS3D 23D”, by: multiplying “the phase measured in degrees” by {“the width of a tooth, wt” divided by “the angular value in degrees for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley”}.
For the “adjustment phase” method, if the graph shown in
In the graphs of FIGS. 21A/B/C the vertical-axis (y-axis) shows the arc length of adjustment required in order to reduce/eliminate transition flexing, or the required phase arc length for the cone assembly about to be engaged if the “adjustment phase” method is used, and the horizontal-axis (x-axis) shows the arc length of the critical non-torque transmitting arc. The values for the y-axis and the x-axis in the graphs of FIGS. 21A/B/C are shown in terms of the width of a tooth, wt. Unless the controlling computer also measures the critical non-torque transmitting arc, and the arc length of adjustment required and provided or the required phase arc length for the cone assembly about to be engaged and the actual phase arc lengths of the cone assemblies (“phase arc length for cone assembly CS3C 23C” and “phase arc length for cone assembly CS3D 23D”) in terms of a fraction or a multiple of the width of a tooth, wt, the width of a tooth, wt, of the CVT where the graph is used, should be used to obtain numerical values for the y-axis and the x-axis of the graph. Then in order to determine the arc length of adjustment required for a given critical non-torque transmitting arc or the required phase arc length for the cone assembly about to be engaged, the controlling computer can use a mathematical function or a program that can determine the arc length of adjustment required for a given critical non-torque transmitting arc based on a graph of FIGS. 21A/B/C. It is believed that somebody skilled in the art should be able to create a mathematical function or a program that can obtain the value for the y-axis for a given value of the x-axis for a graph of FIGS. 21A/B/C.
Regarding the engagement statuses, if a pause between the different operations of the adjuster(s) is desired, then the engagement statuses that consist of engagement statuses 1 to 8, which have pause engagement statuses, should be used. Here for engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged), adjustments to reduce/eliminate transition flexing should be provided, if necessary, so as trying to match the actual “phase arc length for cone assembly CS3D 23D” with the vertical-axis value of the graph shown in
It is recommended that CVT 2.1 is designed so that at the lowest (start-up) transmission ratio, no adjustment is required, so that the controlling computer knows the “phase arc length for cone assembly CS3C 23C” and the “phase arc length for cone assembly CS3D 23D” during start-up using the fact that at the lowest (start-up) transmission ratio, no adjustment is required. In order to let the controlling computer know that it is at the lowest (start-up) transmission ratio, a stop-switch can be used. It is recommended that CVT 1.1 and all other CVT's described in this disclosure where this is useful are designed in the same manner.
It does not matter in what direction the adjuster rotates one transmission pulley relative to the other as long as the proper phase is obtained. The controlling computer can be programmed so that it only rotates one transmission pulley relative to the other in one direction, preferably in the opposite direction the cone assemblies are rotating when the transmission pulleys are mounted on the input shaft and in the direction the cone assemblies are rotating when the transmission pulleys are mounted on the output shaft so that the adjuster only needs to slip; or the controlling computer can be programmed so that it rotates one transmission pulley relative to the other in the direction that requires the least amount of adjustment for example. For the least amount of adjustment, if the “phase arc length for cone assembly CS3C 23C” and the “phase arc length for cone assembly CS3D 23D” is less or equal to “the arc length value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley” divided by two, the controlling computer should be programmed so that the transmission belt about to be engaged is moved away from its torque transmitting member; and if the “phase arc length for cone assembly CS3C 23C” and the “phase arc length for cone assembly CS3D 23D” is greater than “the arc length value for the amount of adjustment needed in order to rotate one transmission pulley from a position where its teeth are aligned with the teeth of the other transmission pulley, to the next position where its teeth are aligned with the teeth of the other transmission pulley” divided by two, the controlling computer should be programmed so that the transmission belt about to be engaged is moved towards its torque transmitting member.
For each cone or cone assembly for which adjustments to reduce/eliminate transition flexing is to be provided, a “critical non-torque transmitting arc length function” that allows the controlling computer to determine the arc length of the critical non-torque transmitting arc of the cone/cone assembly or cones/cone assemblies for which the “critical non-torque transmitting arc length function” is used as a function of the transmission ratio should be programmed into the controlling computer; it is important that the controlling computer determines the arc length of the critical non-torque transmitting arc before a torque transmitting member is about to engage so that the controlling computer knows if adjustments to reduce/eliminate transition flexing is required and so that the controlling computer can determine the amount of adjustments to reduce/eliminate transition flexing required if it has determined that such adjustment is required. It is recommended that the controlling computer is set-up so that it continuously monitor the arc length of the critical non-torque transmitting arc, which value should be updated at the beginning of each engagement status. A “critical non-torque transmitting arc length function” for a cone/cone assembly or cones/cone assemblies can be obtained by first determining the “circumference equation”, which is the equation from which the circumference of the respective cone/cone assembly or of a cone/cone assembly of a pair of cones/cone assemblies (both cones of a pair of cones/cone assemblies should have the same circumference) as measured at the pitch-line of its torque transmitting member(s) or single tooth/teeth (the radius of the pitch-line, which should be the same for a pair of alternating torque transmitting members or single teeth, is the radius of the circumference used for the “circumference equation”) as a function of the transmission ratio can be obtained. Somebody skilled in the art should be able to determine the “circumference equation” either experimentally or mathematically; it basically involves determining the radius to the pitch-line for each transmission ratio and using the radius to the pitch-line for each transmission ratio to calculate the circumference for each transmission ratio. Next, for configurations where one torque transmitting member is positioned opposite of the other, the “first torque transmitting member arc length equation” and the “second torque transmitting member arc length equation” for the respective cone/cone assembly or cones/cone assemblies should be obtained. The “first torque transmitting member arc length equation” is an equation that determines the arc length of the toothed portion of the first torque transmitting member as measured at the pitch-line of the first torque transmitting members (the radius to the pitch-line of the first torque transmitting member is the radius of the arc length of the first torque transmitting member) as a function of the transmission ratio; and the “second torque transmitting member arc length equation” is an equation that determines the arc length of the toothed portion of the second torque transmitting member as measured at the pitch-line of the second torque transmitting member (the radius to the pitch-line of the second torque transmitting member is the radius of the arc length of the second torque transmitting member) as a function of the transmission ratio. For a cone/cone assembly that has a single tooth, the “first torque transmitting member arc length equation” or “second torque transmitting member arc length equation” for that cone/cone assembly is an equation that determines the arc length of the single tooth as measured at the pitch-line of the single tooth. For configurations where the rotational position of the first torque transmitting member/first single tooth relative to the second torque transmitting member/second single tooth is adjusted, the arc length of the critical non-torque transmitting arc also depends on the rotational position of the first torque transmitting member/first single tooth relative to the second torque transmitting member/second single tooth. In order to account for any adjustments made to the rotational position of one torque transmitting member relative to the other, first the arc length of the critical non-torque transmitting arc for a neutral relative rotational position of the torque transmitting members should be obtained. For the neutral relative rotational position of the torque transmitting members, the first torque transmitting member/first single tooth is positioned exactly opposite of the second torque transmitting member/second single tooth (the torque transmitting members/single teeth are positioned 180 degrees apart), here the arc length of each non-torque transmitting arc for a given transmission ratio, for which one of the non-torque transmitting arcs is the critical non-torque transmitting arc, is simply the (“entire circumference of the respective cone/cone assembly or of a cone/cone assembly of a pair of cones/cone assemblies as measured at the pitch-line of its torque transmitting member(s) or single tooth for that given transmission ratio” minus “the arc length of the first torque transmitting member/first single tooth as measured at the pitch-line of that torque transmitting member/single tooth for that given transmission ratio” minus “the arc length of the second torque transmitting member/second single tooth as measured at the pitch-line of that torque transmitting member for that given transmission ratio”) divided by “two”. The neutral relative rotational position of the torque transmitting members can be used to determine the arc length of the critical non-torque transmitting arc for a given transmission ratio only if the rotational position of the torque transmitting members remain exactly opposite of each other, as is the case for CVT 2.1 for example. If the rotational position of the torque transmitting members is adjusted, as is the case for CVT 1.1 for example, then a “critical non-torque transmitting arc length correction term” needs to be used. Regarding the “critical non-torque transmitting arc length correction term”, first of all the required adjustment to reduce/eliminate transition flexing are determined by the actual and required arc length of the critical non-torque transmitting arc, hence the adjustment provided should be measured in terms of an arc length. However, in order to measure the adjustment provided, an adjuster that provides adjustment to reduce/eliminate transition flexing measures the adjustments provided in degrees or radians. Hence in order for the controlling computer to be able to control an adjuster as to provide adjustments as measured in terms of an arc length, the controlling computer needs to convert the degrees of rotation of an adjuster into a corresponding arc length, such that it can control the adjuster in terms of an arc length. In order to do this, the controlling computer needs to know the pitch-line radius of the item the adjuster is rotating. If adjustment is provided by rotating the first torque transmitting member/first single tooth relative to the second torque transmitting member/second single tooth than the pitch-line radius used to determine the arc length adjustment is the current pitch-line radius of the torque transmitting members/single teeth (both torque transmitting members/single teeth should have the same pitch-line radius). If adjustment is provided by rotating the transmission pulley with which the first torque transmitting member/first single tooth engages relative to the transmission pulley with which the second torque transmitting member/second single tooth engages, than the pitch-line radius used to determine the arc length adjustment is the pitch-line radius of the transmission pulleys (both transmission pulleys should have the same pitch-line radius). From the pitch-line radius used to determine the arc length adjustment, the controlling computer can calculate the “circumference to determine the arc length adjustment” by calculating the circumference for which the pitch-line radius used to determine the arc length adjustment is the radius. And from the “circumference to determine the arc length adjustment” the controlling computer can convert the angular adjustment (degrees/radians) of an adjuster into an arc length adjustment by: dividing the “angular adjustment” by “360 degrees”, and then multiplying “that value” by the “circumference to determine the arc length adjustment”. The controlling computer should monitor the current amount of arc length adjustment between the first torque transmitting member/first single tooth relative to the second torque transmitting member/second single tooth that have been provided by an adjuster from the neutral relative rotational position of the torque transmitting members in order to determine the arc lengths of the non-torque transmitting arcs in instances where adjustment between the torque transmitting members has been provided. For configurations where the rotational position of the first torque transmitting member/first single tooth relative to the second torque transmitting member/second single tooth is adjusted, the arc lengths of the non-torque transmitting arcs change and are not equal. Hence, the controlling computer should monitor the current arc length of each non-torque transmitting arc based on the neutral relative rotational position of the torque transmitting members and the arc length of adjustment provided that deviates from the neutral relative rotational position of the torque transmitting members (the arc length of adjustment provided should reset to zero each time the relative rotational position of the torque transmitting members are returned to the neutral relative rotational position). In order to do this a label should be assigned to each non-torque transmitting arc. For example, the non-torque transmitting arc located clockwise of the first torque transmitting member/first single tooth, and hence also counter-clockwise of the second torque transmitting member/second single tooth can be labeled as “non-torque transmitting arc 1”; and the non-torque transmitting arc located counter-clockwise of the first torque transmitting member/first single tooth, and hence also clockwise of the second torque transmitting member/second single tooth can be labeled as “non-torque transmitting arc 2”. Here the arc length of “non-torque transmitting arc 1” is the “arc length of a non-torque transmitting arc for the neutral relative rotational position of the torque transmitting members (“non-torque transmitting arc 1” and “non-torque transmitting arc 2” are equal in length for the neutral relative rotational position of the torque transmitting members)” minus “the arc length of adjustment between the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth that deviates from the neutral relative rotational position of the torque transmitting members/single teeth”; here the minus sign is for a configuration where clockwise rotational adjustment of the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth is positive and counter-clockwise rotational adjustment of the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth is negative; and the arc length of “non-torque transmitting arc 2” is the “arc length of a non-torque transmitting arc for the neutral relative rotational position of the torque transmitting members” plus “the arc length of adjustment between the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth that deviates from the neutral relative rotational position of the torque transmitting members/single teeth”; here the plus sign is for a configuration where clockwise rotational adjustment of the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth is positive and counter-clockwise rotational adjustment of the first torque transmitting member/first single tooth relative the second torque transmitting member/second single tooth is negative. Once a label is assigned to each non-torque transmitting arc in the controlling computer, and the arc length of each non-torque transmitting arc is monitored by the controlling computer, the controlling computer needs to determine which non-torque transmitting arc is the critical non-torque transmitting arc. In order to do this the controlling computer can use the engagement statuses by monitoring the engagement statuses and by labeling which non-torque transmitting arc is the critical non-torque transmitting arc for which engagement statuses. For example, for a configuration of CVT 2.1 where the shaft on which the cone assemblies are mounted is positioned on the left, where the shaft on which the transmission pulleys are mounted is positioned on the right, and where the shaft on which the cone assemblies are mounted rotates clockwise; here for the labeling of the non-torque transmitting arcs described earlier in this paragraph, for the following engagement statuses “non-torque transmitting arc 2” is the critical non-torque transmitting arc: 1) only the first torque transmitting member is engaged, 2) the first torque transmitting member is engaged and the second torque transmitting member is about to come into engagement, 3) the first torque transmitting member and the second torque transmitting member are engaged, 4) the first torque transmitting member is about to come out of engagement and the second torque transmitting member is engaged; and for the following engagement statuses “non-torque transmitting arc 1” is the critical non-torque transmitting arc: 5) only the second torque transmitting member is engaged, 6) the second torque transmitting member is engaged and the first torque transmitting member is about to come into engagement, 7) the second torque transmitting member and the first torque transmitting member are engaged, 8) the second torque transmitting member is about to come out of engagement and the first torque transmitting member is engaged. Somebody skilled in the art should be able to determine which non-torque transmitting arc of the labeled non-torque transmitting arcs is the critical non-torque transmitting arc for other configurations and/or other sets of engagement statuses. A non-torque transmitting arc is a space between two torque transmitting members, which does not have to be located on the same cone; and the critical non-torque transmitting arc is the non-torque transmitting arc for which adjustment to reduce/eliminate transition flexing has to be provided immediately or has to be currently provided, if required, if transition flexing is to be reduced/avoided. For CVT 1.1 and CVT 2.1 and other similar CVT's, the critical non-torque transmitting arc is the non-torque transmitting arc which is about to be completely covered by its transmission belt(s). For CVT 2.1, the torque transmitting members forming the non-torque transmitting arcs are positioned on different cones, hence here the critical non-torque transmitting arc is not positioned on either cone, despite being a space between two torque transmitting members. Looking at a front-view of CVT 2.1, with the configuration described in this paragraph, which is the view which shows the shafts and transmission pulleys as circles and where the shaft of the cone assemblies is positioned on the left and the shaft of the transmission pulleys is positioned on the right; in this view, for a situation where one torque transmitting member is positioned at the 12 o'clock position of a clock and the other torque transmitting member is positioned at the 6 o'clock position of a clock, it can be seen that here the non-torque transmitting arc positioned on the left is covered by the transmission belts and hence that non-torque transmitting arc is the critical non-torque transmitting arc. It is the critical non-torque transmitting arc since here if the teeth of the transmission belts are aligned so that they resemble one transmission belt (no adjustment of the rotational position of one transmission belt relative to other is provided), then it is obvious that the arc length of the non-torque transmitting arc positioned on the left needs to be a multiple of the width of a tooth of the teeth of the torque transmitting members in order to avoid transition flexing; if the arc length of the non-torque transmitting arc positioned on the left is not a multiple of the width of a tooth of the teeth of the torque transmitting members, then compensating adjustment between the rotational position of one transmission belt relative to other needs to be provided in order to reduce/eliminate transition flexing. Also here the non-torque transmitting arc positioned on the right is not completely covered by the transmission belts and hence for this configuration, it is not the critical non-torque transmitting arc; the arc length of this non-torque transmitting arc, whatever it might be, will for the current situation not determine whether transition flexing occurs or not. If no rotational positional adjustment between one torque transmitting member/single tooth relative to the other torque transmitting member/single tooth is provided as in CVT 2.1 for example, then it is recommended that the non-torque transmitting arcs are equal in length so that there is no need in determining which non-torque transmitting arc is the critical non-torque transmitting arc. If there are any mistakes in the description provided in this paragraph as well in all the others, experimentation such as the trial and error method, can be used to obtain the necessary correction. For example, if there is an error in identifying the correct non-torque transmitting arc as the critical non-torque transmitting arc for a group of engagement statuses, then the correct non-torque transmitting arc for each engagement status can be determined through trial and error, by simply determining which non-torque transmitting arc needs to be multiple of the width of a tooth of the teeth of the torque transmitting members in order to avoid transition flexing (there are only two non-torque transmitting arcs). It is believed that sufficient explanation and reasoning has been provided for somebody skilled in the art to make use of the invention. Also, the basic principles of how to reduce/eliminate transition flexing described in this disclosure can also be applied to configurations where more than two torque transmitting members/single teeth are used on a rotating means for transmitting torque, such as a cone assembly for example; it is believed that somebody skilled in the art should know how to do this. Other methods can also be used to determine the arc length of the critical non-torque transmitting arc for a given transmission ratio and for a given rotational position of the respective shaft(s).
The process to reduce/eliminate transition flexing for the “adjustment phase” method of CVT 2.1 basically involves the following steps: first step: having the controlling computer determine if the respective shaft of the CVT is at a rotational position where adjustment to reduce/eliminate transition flexing can be provided; for this the engagement statuses can be used, in which case the controlling computer needs to ensure that the current engagement status of the CVT allows for adjustment to reduce/eliminate transition flexing before providing such adjustment; if engagement statuses are used, they should be continuously monitored by the controlling computer otherwise the rotational position of the respective shaft of the CVT should be continuously monitored by the controlling computer and other categorization based on the rotational position of the respective shaft of the CVT that let the controlling computer know if adjustment to reduce/eliminate transition flexing can be provided or not should be used by the controlling computer. Second step: in order to provide accurate adjustment to reduce/eliminate transition flexing, the controlling computer needs to determine the arc length of the critical non- torque transmitting arc, which should be continuously monitored by the controlling computer. Step 3: from the arc length of the critical non-torque transmitting arc, the controlling computer should determine the required relative rotational position between the transmission pulleys in order to reduce/eliminate transition flexing, which can be represented by the required phase arc length of the cone assembly about to be engaged in order to reduce/eliminate transition flexing; in order to do this the controlling computer can use the graphs/or a graph of FIGS. 21A/B/C; the graphs/or a graph of FIGS. 21A/B/C, or a function/equation/program that represents the graphs/or a graph of FIGS. 21A/B/C can be programmed into the controlling computer. Step 4: from the required relative rotational position between the transmission pulleys in order to reduce/eliminate transition flexing, obtained from step 3, and the actual relative rotational position between the transmission pulleys, which can be represented by the actual phase arc length of the cone assembly about to be engaged, the controlling computer should determine the required adjustment to reduce/eliminate transition flexing, which is the adjustment required to adjust the rotational position between the transmission pulleys from the actual relative rotational position between the transmission pulleys to the required relative rotational position between the transmission pulleys in order to reduce/eliminate transition flexing. Step 5: once the required adjustment to reduce/eliminate transition flexing has been determined by the controlling computer, the controlling computer should control the adjuster(s) to provide the required adjustment to reduce/eliminate transition flexing, which can be done by adjusting the rotational position of one transmission pulley relative to the other, during the rotational position intervals or engagement statuses where adjustment to reduce/eliminate transition flexing can be provided.
The process to reduce/eliminate transition flexing for CVT 1.1 and CVT 2.1 where the “adjustment phase” method is not used basically involves the following steps: first step: having the controlling computer determine if the respective shaft(s) of a CVT are/is at a rotational position where adjustment to reduce/eliminate transition flexing can be provided; for this the engagement statuses can be used, in which case the controlling computer needs to ensure that the current engagement status of the CVT allows for adjustment to reduce/eliminate transition flexing before providing such adjustment; if engagement statuses are used, they should be continuously monitored by the controlling computer otherwise the rotational position of the respective shaft(s) of the CVT should be continuously monitored by the controlling computer and other categorization based on the rotational position of the respective shaft(s) of the CVT that let the controlling computer know if adjustment to reduce/eliminate transition flexing can be provided or not should be used by the controlling computer. Second step: in order to provide accurate adjustment to reduce/eliminate transition flexing, the controlling computer needs to determine the arc length of the critical non-torque transmitting arc, which should be continuously monitored by the controlling computer. Step 3: from the arc length of the critical non-torque transmitting arc, the controlling computer should determine the required adjustment to reduce/eliminate transition flexing for the relative rotational position between the torque transmitting devices which rotational position relative to each other is adjusted in order to reduce/eliminate transition flexing, which for a CVT 1.1 can be the torque transmitting members and which for a CVT 2.1 can be the transmission pulleys; in order to do this the controlling computer can use the graphs/or a graph of FIGS. 21A/B/C; the graphs/or a graph of FIGS. 21A/B/C, or a function/equation/program that represents the graphs/or a graph of FIGS. 21A/B/C can be programmed into the controlling computer. Step 5: once the required adjustment to reduce/eliminate transition flexing has been determined by the controlling computer, the controlling computer should control the adjuster(s) to provide the required adjustment to reduce/eliminate transition flexing, which can be done by adjusting the rotational position of one torque transmitting member relative to the other or by adjusting the rotational position of one transmission pulley relative to the other for example, during the rotational position intervals or engagement statuses where adjustment to reduce/eliminate transition flexing can be provided; also, for CVT 2.1 before any adjustment to reduce/eliminate transition flexing is provided, it needs to be ensured that the teeth of the transmission pulleys are aligned.
Information, methods, approaches, etc. mentioned in one section of the disclosure can be used in other sections if applicable; they are not unnecessarily repeat since a competent engineer should be able to figure-out how to utilize useful information from one section for an item or method described in another section. For example, the details and information regarding the arc length of the critical non-torque transmitting arc; an incomplete tooth shape of a torque transmitting member; the width of a tooth, wt,; how to use a graph shown in FIGS. 21A/B/C; the rotational position sensors; how to use a marker with a sensor in conjunction with the rotational position sensor in order to determine the rotational position of the fixed predetermined reference point of a shaft; the engagement condition (which can be used for all shafts of a CVT where the current engagement status of the torque transmitting members needs to be known); how to determine the arc length of critical non-torque transmitting arc as a function of the transmission ratio using the “critical non-torque transmitting arc length function”; using the engagement statuses in order to determine which non-torque transmitting arc is the critical non-torque transmitting arc; why it is recommended to measure the arc length of the critical non-torque transmitting arc and the width of a tooth, wt,, at the pitch-line of the torque transmitting members; and all other applicable details and information described in the section for CVT 2.1, which is this section, can be used for the section describing CVT 1.1 and all other sections where these details and information are applicable or useful. The same applies to details and information from other section, in that they can be used for all other sections where they are applicable or useful. Therefore, if something is not clear it is recommended that reader continues reading the disclosure until the end, since sometimes additional details or information for a topic are provided in the later sections of the disclosure.
Also if an item is mentioned in one section, where it has not been previously described in that section, than the mentioned item is most likely identical to an item with the same name/label that is described in another section. Somebody skilled in the art should have sufficient judgment to know if this is the case or not.
And although the following adjustment is not critical and can be omitted, the performance of the CVT can be increased when in instances when both torque transmitting members are in contact with their transmission belt, adjuster AD3A 103A is used to adjust the rotational position between the transmission pulleys so as to properly adjust the torque applied to each transmission pulley so that the torque rating and/or the durability of the CVT is maximized. One method is to have adjuster AD3103 try to evenly distribute the load on each tooth. In order to achieve this, the rotational position sensor is used to estimate the amount of teeth of each transmission pulley that is transmitting torque at that instance, and the torque sensors can be used to determine the load on each transmission pulley. And by dividing the measured load on a transmission pulley by its estimated amount of teeth, the load on each of its teeth can be estimated. Another method is to have adjuster AD3103 try to maintain an even tension in the transmission belts.
Furthermore, although the following is also not critical and can be omitted, the torque sensors SN4C 134C and SN4D 134D can also be used as a diagnostic device that ensures the proper operation of adjuster AD3103 in trying to eliminate transition flexing. For instance, when under non-transmission ratio changing operation the reading of torque sensor SN4C 134C when only transmission pulley PU1C 41C is transmitting torque is significantly different than the reading of torque sensor SN4D 134D when only transmission pulley PU1D 41D is transmitting torque, or when the reading of a torque sensor is excessively high, the controlling computer of the CVT can take corrective actions and safety steps that prevents or minimizes damages to the CVT, such as adjusting the adjustment provided in order to reduce/eliminate transition flexing, or signaling warnings, or initiating shutdowns.
The reason why adjuster AD3103 is needed in order to substantially increase the duration at which the transmission ratio can be changed is because of transmission ratio change rotation. Transmission ratio change rotation is rotation of a cone assembly that occurs when the axial position of its torque transmitting member is changed while it is in contact with its transmission belt. In order to help explain transition ratio change rotation, the points where the transmission belts first touch the upper surface of their cone assemblies will be referred to as points N. Here points N are neutral points, which are points where almost no sliding between the transmission belts and the surface of their cone assembly occur when the pitch diameter of the cone assemblies are changed, regardless of the rotational position of the torque transmitting members. This is because the lengths of the transmission belts from their point N to the points where the horizontal mirror lines of the transmission pulleys intersect the surfaces of the transmission pulleys remain almost constant as the transmission ratio is changed, since the center distance between the cone assemblies and the transmission pulleys do not change; however this is only true for reasonably small changes in pitch diameter of the cone assemblies. And point N is also the neutral point because changes in the pitch diameter of the cone assemblies do not affect the portions of the transmission belts that are not in contact with a cone assembly.
Note, for other configurations of a CVT, point N might be positioned elsewhere. For CVT's that utilizes transmission pulleys, a point N is most likely located at a point that corresponds to the end point of a portion of a transmission belt which length from the point where the horizontal mirror line of a transmission pulley intersect the surface of that transmission pulley to point N remains almost constant as the pitch diameter of its cone assembly is changed. For different configurations of CVT's, the location of point N can easily be determined experimentally, by simply determining the point where almost no sliding between the transmission belt and the surface of its cone assembly occur as the pitch diameter of the cone assembly is changed.
When the midpoint of the torque transmitting member is not positioned at point N, then significant transmission ratio change rotation occurs. The amount of transmission ratio change rotation depends on the angle θ, which is the angle between the midpoint of the torque transmitting member, referred to as point M, and point N. And the direction of transmission ratio change rotation depends on whether the midpoint of the torque transmitting member is positioned to the left or to the right of point N, and on whether the pitch diameter of the torque transmitting member is increased or decreased. The reason that transmission ratio change rotation has to occur is because if no slippage between the torque transmitting member and the transmission belt is allowed, then the arc length between point N and the midpoint of the torque transmitting member, point M, has to remain constant regardless of the pitch diameter. For a given initial angle θ1, initial radius R1, and final radius R2, the transmission ratio change rotation, Δθ, can be determined from the equation shown in
Furthermore, because of the configuration of CVT 2.1, in instances where both torque transmitting member CS3C-M123C-M1 and torque transmitting member CS3D-M123D-M1 are in contact with their transmission belt, the transmission ratio change rotation for cone assembly CS3C 23C is different from that of cone assembly CS3D 23D. Hence in order to allow the transmission ratio to be changeable when both torque transmitting members are in contact with their transmission belts, compensating relative rotation between either the cone assemblies or the transmission pulleys has to occur. As described earlier, the relative rotational position between the cone assemblies will not be changed, since it is desired to keep the rotational position of torque transmitting member CS3D-M123D-M1 opposite or close to opposite from the rotational position of torque transmitting member CS3C-M123C-M1. Therefore, in order to compensate for transmission ratio change rotation, adjuster AD3103 is used to adjust the rotational position of transmission pulley PU1C 41C relative to transmission pulley PU1D 41D. In order to compensate for transmission ratio change rotation, adjuster AD3103 is used to rotate transmission pulley PU1C 41C relative to transmission pulley PU1D 41D such that the difference in pulling loads on the transmission pulleys, as measured by torque sensor SN4C 134C and torque sensor SN4D 134D, is maintained between a preset low limit value or preset high limit value, depending on whether the adjuster is used to increase torque or reduce torque, and an acceptable preset value.
The acceptable preset value, preset low limit value, and preset high limit value should be select such that at those values, no damaging stresses in the parts of the CVT occur; such as damaging stresses in the shafts, transmission pulleys, cone assemblies, transmission belts, etc., for example. Since the transmission belts are most likely the most flexible and weakest parts of the CVT, the acceptable preset value is most likely dependent on the strength of the transmission belts. It is also recommended that a factor of safety commonly used in engineering practices is used in selecting an acceptable preset value, preset low limit value, and preset high limit value. Also, more flexible transmission belts allow for more inaccurate adjusters, since the flexing of the transmission belts will also compensate for transmission ratio change rotation.
Also in instances where the difference in torque transmitted by the transmission pulleys reaches an unacceptable level, the transmission ratio changing actuator, used to change the transmission ratio, should stall. The unacceptable level should be selected such that no damaging stresses in the parts of the CVT occur.
As another safety measure, if desired programmed preset values, such as a lower preset low limit value, a higher preset high limit value, and an overshoot preset value, can be used to stop the transmission ratio changing operation once the difference in torque transmitted by the transmission pulleys reaches an unacceptable level. If used, the transmission ratio changing operation should stop once the lower preset low limit value, the higher preset high limit value, or the overshoot preset value is reached. And if used, the lower preset low limit value, the higher preset high limit value, and the overshoot preset value should be selected such that the difference in torque transmitted by the transmission pulleys will not cause damaging stresses in the parts of the CVT. It is also recommended that if used, the lower preset low limit value, the higher preset high limit value, and the overshoot preset value should be selected such that unnecessary and excessive stopping of the transmission ratio changing operation is avoided. The lower preset low limit value, the higher preset high limit value, and the overshoot preset value, are safety measures that should not activate regularly during normal operations. If used, it might also be preferable, but not required, to have the transmission ratio changing operation be stopped before the transmission ratio changing actuator stalls.
The lower preset low limit value and the higher preset high limit value, which should allow for greater difference in the torque transmitted by the transmission pulleys than the preset low limit value and the preset high limit value, can be used to account for insufficient adjustments. And the overshoot preset value, which should allow for greater difference in the torque transmitted by the transmission pulleys than the acceptable preset value, can be used to account for the overshoot of the adjuster.
Besides eliminating transition flexing and compensating for transmission ratio change rotation, the adjuster system for CVT 2.1 can also be used to compensate for wear that causes unequal pulling loads in the alternating transmission pulleys.
The rotational movements between transmission pulley PU1C 41C and transmission pulley PU1D 41D for different rotational positions and transmission ratio changes (increasing/decreasing) as to compensate for transmission ratio change rotation, and the rotational movements between transmission pulley PU1C 41C and transmission pulley PU1D 41D as to eliminate or reduce transition flexing, when the input shaft is rotated clockwise are described below:
Here while torque transmitting member CS3C-M123C-M1 is engaged and torque transmitting member CS3D-M123D-M1 is not engaged with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) and engagement status 2 (the torque transmitting member of cone assembly CS3C 23C is engaged and the torque transmitting member of cone assembly CS3D 23D is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 1 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 2. If no pause is desired, then the previously described set of engagement statuses that consist of engagement statuses 1 to 4 should be used instead of the previously described set of engagement statuses that consist of engagement statuses 1 to 8, which are used for all CVT's, including here, unless mentioned otherwise; and engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) of the set of engagement statuses that consist of engagement statuses 1 to 4 should be used to reduce/eliminate transition flexing and to change the transmission ratio. In this instance adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that due to transition ratio change rotation the cone assemblies are rotated counter-clockwise. Since here only one torque transmitting member is in contact with its transmission belt, transmission ratio change rotation does not cause excessive stretching of the transmission belts. And some counter-clockwise rotation of the cone assemblies, which causes slippage at the output shaft, slightly reduces the performance of the CVT, but is not damaging the CVT. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
And once both torque transmitting member CS3C-M123C-M1, which is positioned on the upper half, and torque transmitting member CS3D-M123D-M1 are in contact with their transmission belts, see
And once torque transmitting member CS3C-M123C-M1 comes out of contact with its transmission belt, during transmission ratio change as during non-transmission ratio change operation, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 5 (only the torque transmitting member of cone assembly CS3D 23D is engaged), and engagement status 6 (the torque transmitting member of cone assembly CS3D 23D is engaged and the torque transmitting member of cone assembly CS3C 23C is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 5 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 6. If no pause is desired, then the previously describe set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 3 (only the torque transmitting member of cone assembly CS3D 23D is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. Since in this instance only one torque transmitting member is contact with its transmission belt, it is not necessary for adjuster AD3103 to compensate for transmission ratio change rotation, despite the fact that due to transmission ratio change rotation, cone assembly CS3D 23D, and hence output shaft SH818 are rotated counter-clockwise. Since some counter-clockwise rotation applied to cone assembly CS3D 23D, which causes slippage at the output shaft SH818, slightly reduces the performance of the CVT but is not damaging the CVT. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
Here while torque transmitting member CS3C-M123C-M1 is not engaged with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 5 (only the torque transmitting member of cone assembly CS3D 23D is engaged) and engagement status 6 (the torque transmitting member of cone assembly CS3D 23D is engaged and the torque transmitting member of cone assembly CS3C 23C is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 5 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 6. If no pause is desired, then the previously describe set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 3 (only the torque transmitting member of cone assembly CS3D 23D is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. Since in this instance only one torque transmitting member is in contact with its transmission belt, it is not necessary for adjuster AD3103 to compensate for transmission ratio change rotation, despite the fact that due to transition ratio change rotation the cone assemblies are rotated counter-clockwise. Since some counter-clockwise rotation of the cone assemblies, which causes slippage at the output shaft, slightly reduces the performance of the CVT but is not damaging the CVT. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
And once both torque transmitting member CS3C-M123C-M1, which is positioned on the lower half, and torque transmitting member CS3D-M123D-M1 are in contact with their transmission belt, see
And once torque transmitting member CS3D-M123D-M1 comes out of contact with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged), and engagement status 2 (the torque transmitting member of cone assembly CS3C 23C is engaged and the torque transmitting member of cone assembly CS3D 23D is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 1 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 2. If no pause is desired, then the previously describe set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. Since in this instance only one torque transmitting member is in contact with its transmission belt, adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that transmission ratio change rotation rotates cone assembly CS3C-M123C-M1, and hence output shaft SH818, counter-clockwise. Since some counter-clockwise rotation applied to cone assembly CS3C 23C, which causes slippage at the output shaft SH818, slightly reduces the performance of the CVT but is not damaging the CVT. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
Here while torque transmitting member CS3C-M123C-M1 is engaged and torque transmitting member CS3D-M123D-M1 is not engaged with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) and engagement status 2 (the torque transmitting member of cone assembly CS3C 23C is engaged and the torque transmitting member of cone assembly CS3D 23D is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 1 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 2. If no pause is desired, then the previously describe set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. Since in this instance only one torque transmitting member is in contact with its transmission belt, the adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that due to transition ratio change rotation the cone assemblies are rotated clockwise, for the same reason discussed earlier. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
And once both, torque transmitting member CS3C-M123C-M1, which is positioned on the upper half, and torque transmitting member CS3D-M123D-M1 are in contact with their transmission belts, see
And once torque transmitting member CS3C-M123C-M1 comes out of contact with its transmission belt, during transmission ratio change as during non-transmission ratio change operation, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 5 (only the torque transmitting member of cone assembly CS3D 23D is engaged), and engagement status 6 (the torque transmitting member of cone assembly CS3D 23D is engaged and the torque transmitting member of cone assembly CS3C 23C is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 5 should be used to reducing transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 6. If no pause is desired, then the previously described set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 3 (only the torque transmitting member of cone assembly CS3D 23D is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. Since in this instance only one torque transmitting member is in contact with its transmission belt, adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that transmission ratio change rotation rotates cone assembly CS3D-M123D-M1, and hence output shaft SH818, clockwise. Since some clockwise rotation applied to the output shaft SH818 is not damaging the CVT, and actually increases the total amount of rotation at the output shaft SH818 at the expense of the work provided by the transmission ratio changing actuator. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
Here while torque transmitting member CS3C-M123C-M1 is not engaged with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 5 (only the torque transmitting member of cone assembly CS3D 23D is engaged) and engagement status 6 (the torque transmitting member of cone assembly CS3D 23D is engaged and the torque transmitting member of cone assembly CS3C 23C is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 5 should be used to reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 6. If no pause is desired, then the previously described set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 3 (only the torque transmitting member of cone assembly CS3D 23D is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. In this instance the adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that due to transition ratio change rotation the cone assemblies are rotated clockwise, for the same reasons discussed earlier. A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is described after the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description.
And once both torque transmitting member CS3C-M123C-M1, which is positioned on the lower half, and torque transmitting member CS3D-M123D-M1 are in contact with their transmission belts, see
And once torque transmitting member CS3D-M123D-M1 comes out of contact with its transmission belt, adjuster AD3103 is used to reduce/eliminate transition flexing. This situation corresponds to engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged), and engagement status 2 (the torque transmitting member of cone assembly CS3C 23C is engaged and the torque transmitting member of cone assembly CS3D 23D is about to come into engagement). In order to have a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, only engagement status 1 should be used reduce/eliminate transition flexing and to change the transmission ratio. Hence adjuster AD3A 103A and the transmission ratio changing actuator are not in operation during engagement status 2. If no pause is desired, then the previously described set of engagement statuses that consist of engagement statuses 1 to 4 should be used, and engagement status 1 (only the torque transmitting member of cone assembly CS3C 23C is engaged) of that set of engagement statuses should be used to reduce/eliminate transition flexing and to change the transmission ratio. However in this instance the adjuster AD3103 is not used to compensate for transmission ratio change rotation, despite the fact that transmission ratio change rotation rotates cone assembly CS3C-M123C-M1, and hence output shaft SH818, clockwise. Since some clockwise rotation applied to the output shaft SH818 is not damaging the CVT, and actually increases the total amount of rotation at the output shaft SH818 at the expense of the work provided by the transmission ratio changing actuator.
A detailed control scheme to reduce/eliminate transition flexing during transmission ratio change is as follows, when both torque transmitting members are engaged, then adjuster AD3103 simply performs as described in the rotational movements between the transmission pulleys for different rotational positions and transmission ratio changes description above. When one torque transmitting member has just disengaged with its transmission belt, adjuster AD3103 rotates the just disengaged transmission belt relative to its torque transmitting member such that that torque transmitting member is positioned so that it can properly engage with its transmission belt. If required transmission ratio change can be temporarily stopped or slowed down during this period. When there is still time left, then as the transmission ratio is changed, the rotational position of the transmission belt about to be engaged is proportionally adjusted relative to the rotational position of its torque transmitting member. For example, as the pitch diameter is increased, the transmission belt is proportionally moved away from its torque transmitting member about to be engaged such that the proper phase is obtained; and when the pitch diameter is decreased, the transmission belt is proportionally moved towards its torque transmitting member about to be engaged such that the proper phase is obtained. In instances where the adjuster is not able to provide sufficient adjustments (leaves a predetermined tolerance range) the transmission ratio actuator should stop.
Also it is recommended that when only one torque transmitting member is engaged with its transmission belt and the direction of rotation of transmission ratio change rotation is opposite from the direction of rotation of the shaft on which the cone are assemblies are mounted, then the speed of the transmission ratio changing actuator should be limited, based o the feedback of the rotational position sensors SN2E 132E, so that the just disengaged torque transmitting member will not reengage with its transmission belt due to transmission ratio change rotation.
It is recommended that a pause between the different operations of adjuster AD3A 103A, which are reducing transition flexing and compensating for transmission ratio change rotation, is used, in order to have CVT that is reliable, consistent, and robust. The pauses should be long enough to account for the inaccuracy of the CVT in determining the proper engagement status. For example, the CVT might assume that it is engagement status 2 while it is still engagement status 1.
It is also recommended that the operations of the adjuster(s) and the operation of the transmission ratio changing actuator are coordinated by the controlling computer of the CVT, for all operations of the adjuster(s). For example, if the operation of an adjuster that needs to provide adjustments is paused, then it is recommended that the operation of the transmission ratio changing actuator is also paused. Unless it was predetermined that the pause of the adjuster that needs to provide adjustments is short enough such that no pausing of the transmission ratio changing actuator is required. The determination whether a pause is short enough, such is the case where the pause of the adjuster that needs to provide adjustments can be compensated by the flexing of the parts of the CVT in instance when adjustments to compensate for transmission ratio change rotation is required for example, can be obtained through experimentation. As another example, in instances where the direction of an adjuster that needs to provides adjustments needs to reverse its direction, then it is recommended that the speed of the transmission ratio changing actuator also slows-down, speeds-up, and stops according to the deceleration, acceleration, and stopping of the adjuster.
The strength of the adjuster AD3A 103A and the transmission ratio changing actuator should be limited such that they cannot cause damaging stresses in the transmission belts or any other part of the CVT. They should stall or slip before they cause damaging stresses. If slippage limiting torque devices such as friction clutches are used, they should be mounted such that they will not affect the accuracy of any sensors of the CVT. Also, the preset low limit value, the preset high limit value, and the acceptable preset value should be selected so that they occur before stalling of the transmission ratio changing actuator occurs. The strength limitation of the adjuster AD3A 103A and the transmission ratio changing actuator is recommended as a safety measure but is not absolutely necessary.
Despite the utilization of adjuster AD3103, occasional stalling of the transmission ratio changing actuator can still be allowed, as long as the stalling is sufficiently reduced as to justify the cost of the adjuster. Since although it might be theoretically possible to completely eliminate stalling of the transmission ratio changing actuator, by also taking into account the flexibility of the transmission belts, this might not be economically practical. The cost to implement this might not compensate for the additional duration at which the transmission ratio can be changed.
Furthermore, in the instances where adjuster AD3103 needs to increase the pulling load of its transmission pulley, adjuster AD3103 needs to provide a pulling torque, which might be quite large, since it has to overcome the rotational resistance of cone assembly CS3C 23C. This situation is similar to a situation where a load is pulled up a cliff. And in the instances where adjuster AD3103 needs to decrease the pulling load of its transmission pulley, adjuster AD3103 needs to provide a releasing torque. Unlike the pulling torque, the releasing torque does not have to provide torque that overcomes the rotational resistance of cone assembly CS3C 23C. Here when a holding mechanism, which prevents transmission pulley PU1C 41C from freely rotating in the opposite direction the cone assemblies are rotating is used, the only load adjuster AD3103 needs to exert is due to friction. This situation is similar to a situation where a load is lowered down a cliff using a winch that has a locking mechanism that prevents the load from going down the cliff without any input at the winch. By providing both transmission pulleys with an adjuster, the need of the adjusters to provide a pulling torque can be eliminated. Since here, in order to compensate for transmission ratio change rotation, one adjuster needs to provide a pulling torque, and the other adjuster needs to provide a releasing torque. Hence here the adjusters can be operated such that only the adjuster that needs to provide a releasing torque is active. Also, by providing both transmission pulleys with an adjuster, the adjusters can also be operated as to eliminate any rotation at the output shaft due the changing of the transmission ratio.
In addition, when compensating for transmission ratio change rotation, the difference in torque transmitted by the transmission pulleys is the main criteria that needs to be accounted for, since the magnitude of the stresses in the parts of the CVT due to transmission ratio change rotation depend on the magnitude of the difference in torque transmitted by the transmission pulleys. The preset low limit value, which is used when transmission ratio change rotation causes the pulling load of the non-adjuster mounted transmission pulley to decrease relative to the pulling load of the adjuster mounted transmission pulley, and the preset high limit value, which is used when transmission ratio change rotation causes the pulling load of the non-adjuster mounted transmission pulley to increase relative to the pulling load of the adjuster mounted transmission pulley, are mainly used for illustrative purposes. Instead of using the preset low limit value, the preset high limit value, and the acceptable preset value as control values to compensate for transmission ratio change rotation, a “difference in torque adjuster start preset value” and a “difference in torque adjuster stop preset value” can be used. Here in order for the controlling computer to control the adjuster(s) as to maintain the difference in torque value, which is the difference in torque transmitted by the transmission pulleys, between the “difference in torque adjuster start preset value” and the “difference in torque adjuster stop preset value”, the controlling computer needs to calculate the difference in torque transmitted by the transmission pulleys. The torque transmitted by each transmission pulley can be obtained from their torque sensors. The “difference in torque adjuster stop preset value” is the value at which the difference in torque value has reached a target difference in torque value at which the adjuster(s) stop providing adjustments. This preset value has the same operational function as the acceptable preset value. And the “difference in torque adjuster start preset value” is the value at which the difference in torque value has sufficiently deviated from the target difference in torque value such that the adjuster(s) start providing adjustments as to maintain the difference in torque transmitted by the transmission pulleys within a predetermined acceptable range. This preset value has the same operational function as the preset low limit value and the preset high limit value. In a similar manner, the lower preset low limit value, the higher preset high limit value, and the overshoot preset value can be replaced with a “transmission ratio actuator stop difference in torque preset value”. When multiple adjusters are used to compensate for transmission ratio change rotation it is recommended that the “difference in torque adjuster start preset value” and the “difference in torque adjuster stop preset value”, and the “transmission ratio actuator stop difference in torque preset value” are used; otherwise it needs to be defined in the controlling computer for which transmission pulley the preset low limit value, the preset high limit value, etc. are applied.
In this section a design for an electrical adjuster 160 that can be used as a transition flexing adjuster, mover adjuster, or adjuster AD3103 is described.
All the adjusters described in this invention consist of an adjuster body and an adjuster output member, that can rotate relative to the adjuster body. In order for the adjuster to transmit torque from a transmission pulley or a cone assembly that is fixed to the adjuster output member to the shaft to which the adjuster body is fixed, the adjuster output member has to be able to hold the adjuster output member fixed relative to the adjuster body despite the fact that torque is applied at the adjuster output member. This can be can be achieved by using an electrical brake or a holding mechanism.
For the electrical adjuster 160, shown as top-view in
The body of the adjuster consists mainly of an attachment sleeve 160-M4, which has an attachment sleeve arm 1160-M4-S1, an attachment sleeve arm 2160-M4-S2, an adjuster motor holder 160-M7, and a counter-weight 160-M8. The attachment sleeve 160-M4 can be fixed to an input shaft, an output shaft, or a spline sleeve, so that it is rotatably and axially constrained relative to the shaft or sleeve on which it is attached using a electrical adjuster set screw 160-M5. Extending radially outwards from the side surfaces of the attachment sleeve 160-M4 are the two attachment sleeve arms 160-M4-S1 and 160-M4-S2. Attached to attachment sleeve arm 1160-M4-S1 is the adjuster motor holder 160-M7, on which the adjuster motor 160-M1 is pressed in such that due to friction, the adjuster motor 160-M1 can not move axially or rotate relative to the adjuster motor holder 160-M7. And attached to the attachment sleeve arm 2160-M4-S2 is counter-weight 160-M8, which is used to counter-balance the centrifugal force of the adjuster motor holder 160-M7, the adjuster motor 160-M1, and the worm gear 160-M2. Using another adjuster motor with a worm gear to counter-balance the centrifugal force of the existing adjuster motor 160-M1 and worm gear 160-M2 should also work. The additional adjuster motor can be used to increase the torque capacity of the electrical adjuster 160, or it can be used as a back-up in case the main adjuster motor 160-M1 fails.
And extending axially backwards from the attachment sleeve 160-M4 are four attachment sleeve fins 160-M4-S3, spaced at 90 deg. from each other, on which two electrical rings 160-M6 are securely pressed in, as to prevent them from rotating or from moving axially relative to the attachment sleeve fins 160-M4-S3. Each electrical ring 160-M6 is connected to a pole/connection of the adjuster motor 160-M1. The surfaces of the attachment sleeve fins 160-M4-S3 in contact with the electrical rings 160-M6 are insulated such that the electricity directed to the electrical rings 160-M6 by some electrical brushes are directed to the electrical poles of the adjuster motor 160-M1 by electrical cables 160-M9. If an electric motor that requires more than two input signals is used, than additional electrical rings 160-M6 and electrical cables 160-M9 are needed.
Positioned axially in front of the attachment sleeve 160-M4 is an attachment sleeve flange 160-M4-S4, which is larger in diameter than the main body of attachment sleeve 160-M4. And positioned axially in front of the attachment sleeve flange 160-M4-S4 is an attachment sleeve extension 160-M4-S5, which is shaped like a hollow cylinder which has a smooth side surface, except at its front end, were it is threaded.
The adjuster gear 160-M3, with which the worm gear 160-M2 engages, is shaped like a spur gear, that has a centrically positioned cylindrical extension at its front surface. The spur gear shaped portion of adjuster gear 160-M3 is labeled as spur gear 160-M3-S1. And shaped axially in front of the spur gear 160-M3-S1 is an adjuster gear extension 160-M3-S2, which is shaped like a hollow cylinder, which center is positioned at the center of the spur gear 160-M3-S1. And positioned axially in front of the adjuster gear extension 160-M3-S2 is an adjuster gear flange 160-M3-S3, which is shaped like a disk that has a thick rim. The rim portion of adjuster gear flange 160-M3-S3 extends forwards beyond the surface of its disk shape. On the rim portion of the adjuster gear flange 160-M3-S3, two bolt holes that can be used to attach the electrical adjuster 160 to a torque transmitting device such as a cone assembly, a transmission pulley, an attachment extension on which the telescopes of a torque transmitting member can be attached, etc. The adjuster gear 160-M3 also has a centrically positioned hole that goes through all shapes of the adjuster gear 160-M3, so that it can be slid onto the attachment sleeve extension 160-M4-S5. When adjuster gear 160-M3 is slid onto attachment sleeve extension 160-M4-S5 until the back surface of adjuster gear 160-M3 is in contact with the attachment sleeve flange 160-M4-S4, the threaded portion of attachment sleeve extension 160-M4-S5 is not covered by the disk shaped portion of adjuster gear flange 160-M3-S3 but is only covered by its flange shaped portion. The engagement between the back surface of adjuster gear 160-M3 and the attachment sleeve flange 160-M4-S4 prevents the adjuster gear 160-M3 from moving axially backwards relative to the attachment sleeve 160-M4, and in order to prevent the adjuster gear 160-M3 from moving axially forwards relative to the attachment sleeve 160-M4, an electrical adjuster nut 160-M10 is threaded onto the threaded portion of the attachment sleeve extension 160-M4-S5. The width of the electrical adjuster nut 160-M10 should be less than the thickness of the rim shape of adjuster gear flange 160-M3-S3. Since the adjuster gear 160-M3 has to rotate relative to the attachment sleeve 160-M4, friction between the engaging surfaces of the attachment sleeve 160-M4, the adjuster gear 160-M3, and the electrical adjuster nut 160-M10 should be minimized. This can be done by coating the engaging surfaces of the adjuster gear with bronze.
It might also be useful to have a limiting clutch attached between the shaft of the adjuster motor and the worm gear, as a safety measure in case the controlling computer fails to control the electrical actuator properly. It is also recommended that a housing that protects the components of the electrical adjuster from dirt is used.
This CVT, which is shown in
CVT 2.2, shown in
The adjusted equation, takes into account the changes in θ due to the change in the radius of the cone assembly where its torque transmitting member is positioned as its pitch diameter is changed, labeled as dθ/dR; and takes into account the rotation of the cone assembly also due to the change in the radius, labeled as dθrot/dR. For the adjusted equation, first the equation shown in
A rough estimation for the values for dθ/dR and dθrot/dR, which here are assumed to be identical, can be obtained experimentally. This can be done by using a configuration for a CVT 2 where only one cone assembly is coupled to its transmission pulley by a transmission belt. Also in order to monitor dθ/dR and dθrot/dR as the pitch diameter, and hence radius, of the coupled cone assembly is changed, a computer that can monitor the rotational position of the coupled cone assembly and the transmission ratio via appropriate sensors is needed. The experiment is conducted by first positioning the transmission belt at the smallest pitch diameter, and positioning the midpoint of the torque transmitting member at the location where the transmission belt first touches the upper surface of the cone assembly. Then, the transmission belt is moved towards the largest pitch diameter, while the transmission ratio and the rotation of the cone assembly is continuously monitored by the computer. The computer can then use this information to compute the values for dθ/dR and dθrot/dR, which can then be used in the adjusted equation.
The method for determining dθ/dR and dθrot/dR described in the previous paragraph might not be accurate enough for some applications. If this is the case, then the values for dθ/dR can be determined by again using a configuration for a CVT 2 where only one cone assembly is coupled to its transmission pulley by a transmission belt. However here, it might be easier to use a cone assembly that does not have a torque transmitting member. The experiment is conducted by first positioning the transmission belt at the smallest pitch diameter and then moving it towards the largest pitch diameter while continuously monitoring the location of point N, which is the point where the transmission belt first touches the upper surface of the cone assembly. Here the movement of point N as the pitch diameter, and hence radius, is changed is dθ/dR. And the values for dθrot/dR can be determined by the same method used in the previous paragraph. However here instead of moving the transmission belt in one step, the transmission belt should be moved in a stepwise manner. So that by making adjustments as necessary, it can be assured that the midpoint of the torque transmitting member is positioned at or close enough to point N each time the pitch diameter is changed.
Also in cases where acceptable flexing in the transmission belts cannot compensate for the inaccuracy of the equation shown in
Furthermore, the method for starting the adjuster as to provide adjustments to compensate for transmission ratio change rotation for CVT's using an adjuster or adjusters where no torque sensors are used, is by using the engagement statuses. Here a time lag to start providing adjustments to compensate for transmission ratio change rotation after an engagement status that requires such adjustments has occurred, which causes a pause of the adjuster(s) used, can be used to compensate for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT for the relevant engagement statuses. This will prevent having adjustments compensating for transmission ratio change rotation while only one torque transmitting member is engaged, which will cause incorrect engagement for the torque transmitting member about to be engaged. A positional lag based on the rotational position of a cone assembly can also be used instead of a time lag. If the relevant pause engagement statuses are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer for the relevant engagement statuses, then this time lag or positional lag is not needed, since this is already provided by the relevant pause engagement statuses. If pause engagement statuses, such pause engagement statuses 2, 4, 6, and 8 of the set of engagement statuses that consist of engagement statuses 1 to 8, are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT, than no adjustments should be provided during the pause engagement statuses.
And in order to stop the adjuster in providing adjustments to compensate for transmission ratio change rotation, the engagement statuses should be used. This method should also be used for all other CVT's using an adjuster or adjusters described in this disclosure regardless of whether torque sensors are used or not. Here a time lead to stop providing adjustments to compensate for transmission ratio change rotation before an engagement status that requires such adjustments will end, which causes a pause of the adjuster(s) used, can be used to compensate for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT for the relevant engagement statuses. This will prevent having adjustments compensating for transmission ratio change rotation while only one torque transmitting member is engaged, which can cause incorrect engagement for the torque transmitting member about to be engaged. A positional lead based on the rotational position of a cone assembly can also be used instead of a time lead. If the relevant pause engagement statuses are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT for the relevant engagement statuses, then this time lead or positional lead is not needed, since this is already provided by the relevant pause engagement statuses. If pause engagement statuses are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT, than no adjustments should be provided during the pause engagement statuses.
In the same manner, a time lag or positional lag to start providing adjustments to reduce/eliminate transition flexing after an engagement status that requires such adjustments has started; and a time lead or positional lead to stop providing adjustments to reduce/eliminate transition flexing before an engagement status that requires such adjustments will end can also be used to compensate for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT for the relevant engagement statuses. If relevant pause engagement statuses are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer for the relevant engagement statuses, then the time lag or positional lag and time lead or positional lead of this paragraph are not needed, since they are already provided by the relevant pause engagement statuses. If pause engagement statuses are used to account for the inaccuracies between the actual engagement status and the engagement status as determined by the controlling computer of the CVT, than no adjustments should be provided during the pause engagement statuses.
The time lags and time leads described in the paragraphs above are optional and do not need to be used if unnecessary.
CVT 2.3, shown in
And in order to compensate for transmission ratio change rotation and in order to distribute the torque loading on the cone assemblies when both torque transmitting members are transmitting torque, if desired, only the adjuster that need to provide a releasing torque can be made active so as to reduce the required torque capacity of the adjusters, see last paragraph of the Adjuster System for CVT 2 section.
CVT 2.4, shown in
When the equation shown in
Furthermore, instead of using the equation shown in
If desired, the over adjustment method can also be used where the active adjuster is providing a pulling torque. However, here the stresses in the parts of the CVT when over adjustment is provided is larger, since here the active adjuster should have sufficient torque to overcome the pulling torque in its transmission belt under maximum operating load. Hence using an adjuster that needs to provide a pulling torque as the active adjuster should be avoided when possible. For a configuration where two adjusters are used, the over adjustment method might be used for an adjuster that needs to provide a pulling torque when one adjuster fails. Here the torque of the adjuster needs to be increased when it needs to provide a pulling torque, or the strength of the adjusters need to be selected such that they can provide a pulling torque as well as a releasing torque. Although in this case it might more practical to simply ignore compensating for transmission ratio change rotation when the adjuster that needs to provide a releasing torque fails, which is recommended the inventor. However, if transmission ratio changing responsiveness is very important than using the over adjustment method for an adjuster that needs to provide a pulling torque when one adjuster fails might be considered. If the CVT only has one adjuster, which needs to provide a releasing torque as well as a pulling torque, then it might be advantageous to use the over adjustment method over other control methods.
Also if springs or weights are used to maintain the tension in the slack side of the transmission belts, which is the case for the tensioner pulley assemblies described in the Alternate CVT's section, the springs or weights should be strong enough such that the load applied by the over adjustment method will not affect the shape of the transmission belts under any operational condition.
CVT 2.5, which is shown in
In this section differential adjuster shafts which can be used to replace the shaft on which the transmission pulleys are mounted of a CVT 2 will be presented. Here first the advantages of using a differential adjuster shaft, which is a shaft or spline that uses a differential, in a CVT 2 will be described. Then, the preferred and alternate configurations for differential adjuster shafts will be described. Next, the mounting details of a differential adjuster shaft, so as to allow axial movements for it's transmission pulleys, will be described.
As described in the previous sections, in a configuration where each transmission pulley is mounted on an adjuster, in order to distribute the torque loading on the cone assemblies when both torque transmitting members are transmitting torque and in order to compensate for transmission ratio change rotation, only the adjuster that needs to provides a releasing torque can be made active. Hence under this configuration, unlike the configuration where only one adjuster is used, the adjusters do not have to provide a pulling torque. And not having to provide a pulling torque can significantly lower the torque requirements of the adjuster. However, the obvious disadvantage for this configuration is that here two adjusters are needed instead of one.
By the use of a differential adjuster shaft, such as differential adjuster shaft 1 shown in
An alternate configuration for a differential adjuster shaft, which is referred to differential adjuster shaft 2, is shown in
Another alternate configuration for a differential adjuster shaft, which is referred to differential adjuster shaft 3, is shown in
Another alternate configuration for a differential adjuster shaft, which is referred to differential adjuster shaft 4, is shown in
In addition, for differential adjuster shaft 4, it is difficult to accurately control the relative rotational position between the differential shafts using the differential brake 217. Since when differential C pinion shaft 2212-M3-S1 is rotating, it does not stop immediately after the brake is applied. In order to better control differential adjuster shaft 4 using the same locking and releasing method an index wheel mechanism shown partially in
The physical description of the index wheel mechanism is described below. A partial top-view of the index wheel mechanism is shown in
The operation of the index wheel mechanism, which is used to either lock or release index wheel 221, is described below. The locking position of the index wheel mechanism is shown in
Furthermore, since the index wheel mechanism is rotating relative to the frame where its controlling computer is attached, the ring and brush connection described earlier can be used to direct signals from the computer to the solenoids. An alternate index wheel 221B is shown in
If friction torque transmitting members are used then an alternate configuration for a differential adjuster shaft, which is referred to as differential adjuster shaft 5, can be used. A configuration for a CVT that uses a differential adjuster shaft 5 is shown as a top-view in
Furthermore, in order to change the transmission ratio unless the axial position of the cones can be changed, the axial position of the transmission pulleys need to be changed. In order to emphasize the function of the differential adjuster shaft in addressing the transition flexing and transmission ratio change issue, such detail have been previously omitted. In the following paragraphs, details on how to allow the axial position of the differential adjuster shaft mounted transmission pulleys to be changed will be described. The following details can be applied to any of the differential adjuster shafts described earlier.
A simple method to allow the axial position of the differential adjuster shaft mounted transmission pulleys to be changed can be achieved by simple connecting the differential adjuster shaft and its adjuster shaft, if applicable, to a mover frame 230, which is connected to the mover gear rack 231 which engages a transmission ratio gear that is used to control the transmission ratio, see
Another configuration that allows the axial position of the differential adjuster shaft mounted transmission pulleys to be changed is shown in
In order to support the differential adjuster shafts, support bearings positioned so that they do not interfere with its operation of can be used. As before, the method of supporting the shafts will not be explained in this disclosure, since the technique to do this is well known and a details for this will unnecessarily complicated the description for the invention without adding to the essence of the invention.
Another simple method to reduce/eliminate transition flexing is by using a spring-loaded adjuster that biases a spring-loaded adjuster mounted torque transmitting member towards a neutral position from which it can rotate clockwise and counter-clockwise relative to the shaft on which it is attached. Here first a spring-loaded adjuster AS1171, which can be used to replace the adjusters AD1A 101A or AD1B 101B of CVT 1.1 will be described, then a spring-loaded adjuster AS2172 that can be used as an adjuster AD4104 for CVT 2.4 will be described. It is also recommended that the spring-loaded adjusters are mounted such that they will not affect the accuracy of the sensors of their CVT.
Another simple method to reduce/eliminate transition flexing is by having a parallel gap in the slots where the attachment pins used to attach a torque transmitting member to its cone assembly are inserted; and using a spring-loaded adjuster to bias the attachment pins of the gap mounted torque transmitting member towards the center of the gap. This allows for some rotational movement of the gap mounted torque transmitting member in instances where the pitch diameter of the gap mounted torque transmitting member is increased and decreased. In order to achieve this, a spring-loaded adjuster AS1171 is needed. The spring-loaded adjuster AS1171 consists mainly of a spring-loaded adjuster shaft 171-M2 that can rotate relative to a spring-loaded adjuster body 171-M1, and is biased by an adjuster spring 171-M3 towards a neutral position, see
In order to securely fix the axial position of the spring-loaded adjuster shaft 171-M2 relative to the spring-loaded adjuster body 171-M1, a spring-loaded adjuster cap 171-M5 is used. The spring-loaded adjuster cap 171-M5 is shaped like a short cylinder, which has a top surface but not a bottom surface. The top surface of the spring-loaded adjuster cap has a hole at its center, which diameter is slightly larger than the diameter of the spring-loaded adjuster shaft 171-M2, but smaller than the diameter of the spring-loaded adjuster flange 171-M2-S1. And the inner side surface of the spring-loaded adjuster cap 171-M5 has internal threads that can engage with the external threads of the spring-loaded adjuster body 171-M1.
The spring-loaded adjuster 171 is assembled by first inserting the adjuster spring 171-M3 into the spring-loaded adjuster body 171-M1 such that the bottom square shaped loop of the spring-loaded adjuster spring is fully inserted into the square shaped notch of the spring-loaded adjuster body. Then the spring-loaded adjuster shaft 171-M2 is slid into the spring-loaded adjuster body 171-M1, in a manner such that the open end of the spring-loaded adjuster shaft is facing the open end of the spring-loaded adjuster body, and the top square shaped loop of the spring-loaded adjuster spring 171-M3 is fully inserted into the square shaped notch of the spring-loaded adjuster shaft 171-M2. Then the spring-loaded adjuster cap 171-M5 is inserted through the top-end of the spring-loaded adjuster shaft 171-M2 and tighten unto the spring-loaded adjuster body 171-M1 through the engagement of the internal threads of the spring-loaded adjuster cap with the external threads of the spring-loaded adjuster body. The spring-loaded adjuster cap 171-M5 should be tighten unto the spring-loaded adjuster body 171-M1 until the inner top surface of the spring-loaded adjuster cap pushes the spring-loaded adjuster flange 171-M2-S1 of the spring-loaded adjuster shaft 171-M2 towards the top surface of the spring-loaded adjuster body 171-M1, so that axial movements between the spring-loaded adjuster shaft 171-M2 and the spring-loaded adjuster body 171-M1 is minimized. Since the spring-loaded adjuster shaft has to rotate relative to the spring-loaded adjuster body, friction between the engaging surfaces of the spring-loaded adjuster cap, the spring-loaded adjuster shaft, and the spring-loaded adjuster body should be minimized. This can be done by coating the engaging surfaces of the spring-loaded adjuster flange of the spring-loaded adjuster shaft with bronze. However in order to prevent the spring-loaded adjuster cap from loosening, no low friction coating should be applied to internal and external threads. Next in order to be able to properly mount the telescopes of a gap mounted torque transmitting member and a constrainer mechanism to the spring-loaded adjuster shaft 171-M2, the shaft end attachment 171-M4 is attached to the spring-loaded adjuster shaft. In order to achieve this, the hexagonal notch at the outer top surface of the spring-loaded adjuster shaft 171-M2 is pressed into the hexagonal cavity of the shaft end attachment mounting plate 171-M4-S3. Here the dimension of the hexagonal cavity should be slightly smaller than the dimension of the hexagonal notch, so that sufficient friction between them, as to prevent any axial movements between them, is developed when separating forces encountered during normal operation is applied to them.
The spring-loaded adjuster AS2172, shown in
In this section a design for a mechanical adjuster AM1181, that can be used as an adjuster AD4104, and a mechanical adjuster AM2182, that can be used as transition flexing adjuster AD1101 is described. Since it is simpler, here the mechanical adjuster AM1181, which is for CVT 2.5, will be described before the mechanical adjuster AM2182, which is for CVT 1.1, is described.
Like the electrical adjuster 160, the mechanical adjuster AM1181, which is shown in
The adjuster output member of the mechanical adjuster AM1181 is shaped like disk, and it will be referred to as the output disk 181-M8. The output disk 181-M8 has two opposite positioned bolt holes, which will be used to attach a cone assembly or a transmission pulley to the output disk. In addition, output disk 181-M8 has an output disk arm 181-M8-S1, which is a radial extension that has a hole. And in order to balance the centrifugal force due the output disk arm 181-M8-S1, and portions of the centrifugal forces due to link AM1-M6181-M6 and link AM1-M7181-M7, an output disk counter-weight 181-M8-S2 is shaped opposite of the output disk arm 181-M8-S2 on the surface of output disk 181-M8. In order to control the relative rotation between cam sleeve 181-M2 and output disk 181-M8, a link AM1-M6181-M6 and link AM1-M7181-M7, which connect the cam sleeve to the output disk, are used. Link AM1-M6181-M6 is shaped like a monkey wrench. It has a middle shape, and two end shapes. Each end shape, which is labeled as link shape AM1-M6-S1181-M6-S1, is shaped like a square plate that has a hole. And the middle shape, which is labeled as link shape AM1-M6-S2181-M6-S2, is shaped like a slender rectangular plate that has a controller slot. The end shapes are parallel relative to each other but the middle shape is positioned diagonally relative to the end shapes. The other link, link AM1-M7181-M7 is shaped like flat and slender bar that has two link holes at each of its ends. In addition, the ends of link AM1-M7181-M7 have a half disk shape, which center is positioned at the center of the holes of link AM1-M7181-M7.
In order for link AM1-M6181-M6 and link AM1-M7181-M7 to connect the cam sleeve 181-M2 to the output disk 181-M8, one end of link AM1-M6181-M6 is connected to follower 181-M4 by inserting a link bolt 181-M9 through the hole of follower 181-M4, and then securing that bolt using a link nut 181-M12. And the other end of link AM1-M6181-M6 is connected to one end of link AM1-M7181-M7 by inserting a link bolt 181-M9 through the other hole of link AM1-M6181-M6 and a hole of link AM1-M7181-M7, and then securing that link bolt using a link nut 181-M12. And the other end of link AM1-M7181-M7 is connected to the output disk arm 181-M8-S1 by inserting a link bolt 181-M9 through the other hole of link AM1-M7181-M7 and the hole of the output disk arm 181-M8-S1, and then securing that link bolt using a link nut 181-M12. The surfaces of the link bolts and the link nuts that are in contact with follower 181-M4, link AM1-M6181-M6, link AM1-M7181-M7, or output disk arm 181-M8-S1, are preferably coated with a low friction material such as oil-impregnated bronze, so that the link AM1-M6181-M6 and link AM1-M7181-M7 can rotate without much frictional resistance.
In order to control the relative rotation between cam sleeve 181-M2 and output disk 181-M8, a controller rod 181-M10 is used. The controller rod 181-M10 is a slender steel rod that is bent repeatedly such that a zigzag profile is formed. The zigzag profile consist of two alternating shapes, a pivot shape 181-M10-S1 and a parallel shape 181-M10-S2, that can be slid through the controller slot of link AM1-M6181-M6. The angle between the pivot shape 181-M10-S1 and the parallel shape 181-M10-S2 should be 90°. The pivot shapes 181-M10-S1 are positioned perpendicular to the long surfaces of link AM1-M6181-M6, so that they can act as pivots for link AM1-M6181-M6. And the parallel shapes 181-M10-S2 are positioned parallel to the long surfaces of link AM1-M6181-M6, so that they can act as constrainers for link AM1-M6181-M6. The function of the controller rod 181-M10 is to properly adjust the rotation of the output disk 181-M8 relative to the cam sleeve 181-M2 due the profile of the cam 181-M1, by adjusting the pivot location of link AM1-M6181-M6 or by constraining link AM1-M6181-M6. By changing the axial position of the controller rod 181-M10 relative to link AM1-M6181-M6, it can be selected whether a pivot shape 181-M10-S1 or a parallel shape 181-M10-S2 is positioned inside the controller slot of link AM1-M6181-M6. In instances where a pivot shape 181-M10-S1 is located in the controller slot of link AM1-M6181-M6, the position of the pivot for link AM1-M6181-M6 can be changed by changing the axial position of the controller rod 181-M10 relative to link AM1-M6181-M6. And changing the position of the pivot for link AM1-M6181-M6, by changing the axial position of controller rod 181-M10 relative to link AM1-M6181-M6, changes the amount of relative rotation between cam sleeve 181-M2 and output disk 181-M8 due to the profile of cam 181-M1. Furthermore, by inserting a parallel shape 181-M10-S2 into the controller slot of link AM1-M6181-M6, link AM1-M6181-M6 is constrained from pivoting, so that despite the profile of cam 181-M1, no relative rotation between cam sleeve 181-M2 and output disk 181-M8 exist. When follower 181-M4 is in contact with a diameter D1 of cam 181-M1, a positive angle, which is referred to as the controller angle, is formed between the flat profile of the controller rod 181-M10 and the controller slot of link AM1-M6181-M6. The controller angle increases as the pivot is moved towards the follower 181-M4. The amount of relative rotation between the cam sleeve 181-M2 and the output disk 181-M8 increases proportionally with an increase in the controller angle. The diameters D1 should be selected as to eliminate transition flexing. When the follower 181-M4 is in contact with a diameter DC of cam 181-M2, link AM1-M6181-M6 is aligned such that the flat profile of controller rod 181-M10 is parallel to the controller slot of link AM1-M6181-M6. In this configuration the axial position of controller rod 181-M10 relative to link AM1-M6181-M6 can always be changed.
Furthermore, the zigzag profile of the controller rod 181-M10 and its pattern of axial movements relative to link AM1-M6181-M6 should be designed based on the information shown in
Also the controller rod 181-M10 has to be slid through the controller slot of link AM1-M6181-M6, which is rotating with the cam sleeve 181-M2, which in turn is rotating with shaft SH010. Hence, the controller rod 181-M10 has to be attached such that it rotates with shaft SH010 but can be moved axially relative to shaft SH010. In order to achieve this a controller rod mechanism, that consist of the controller rod 181-M10, a controller rod counter-weight 181-M11, a controller rod slider 181-M13, and a controller rod disk 181-M14, is used. Here in order to constrain the rotational position of the controller rod 181-M10 relative to the controller rod counter-weight 181-M1, the back end of the controller rod 181-M10 and the back end of an controller rod counter-weight 181-M11 are connected to the controller rod slider 181-M13, which slides freely on shaft SH010 and is positioned in the back of the controller rod disk 181-M14. And the front end of the controller rod 181-M10 and the front ends of the controller counter-weight 181-M11 are connected to the controller rod disk 181-M14, which is positioned in front of the cam sleeve 181-M2. As described earlier the controller rod counter-weight 181-M11 is slid through controller rod counter-weight arm 181-M2-S5 of cam sleeve 181-M2 so that the controller rod counter-weight 181-M11 rotates with cam sleeve 181-M2. And since controller rod 181-M10 and controller rod counter-weight 181-M11 are rotatably constrained relative to each other, controller rod 181-M10 is rotatably constrained relative to cam sleeve 181-M2. Therefore, controller rod 181-M10 rotates with cam sleeve 181-M2.
The controller rod 181-M10 and the controller rod counter-weight 181-M11, except their ends, are made from a round wire. And in order to avoid any vibrations due to unbalanced centrifugal forces, the weight of controller rod 181-M10 should be identical to the weight of controller rod counter-weight 181-M11. In order to attach controller rod 181-M10 and controller rod counter-weight 181-M11 to controller rod slider 181-M13 and controller rod disk 181-M14, the front-end and the back-end of the controller rod and the controller rod counter-weight are shaped like a straight square wire. The controller rod slider 181-M13 is shaped like a hollow cylinder with an plain end and a flanged end. The inner diameter of the controller rod slider 181-M13 is slightly larger than the diameter of shaft SH010, so that only significant relative axial movements between the controller rod slider 181-M12 and shaft SH010 is allowed. Furthermore, the plain end of the controller rod slider 181-M13 is facing away from cam sleeve 181-M2 and the flanged end of the controller rod slider is facing towards the cam sleeve. To the flanged end of the controller rod slider 181-M13, the back end of the controller rod 181-M10 and the back end of the controller rod counter-weight 181-M11 are attached. In order to achieve this, the flanged end of the controller rod slider has two opposite positioned square holes into which the back end of the controller rod and the back end of the controller counter-weight are securely pressed in. They are attached opposite of each other so that the centrifugal force of the controller rod is canceled out by the centrifugal force of the controller rod counter-weight. In addition, the controller rod and the controller rod counter-weight are also aligned so that their center-axis is parallel to the center-axis of shaft SH010. And the front end of the controller rod 181-M10 and the front end of the controller rod counter-weight 181-M11 are attached to the controller rod disk 181-M14, which also has two opposite positioned square holes into which the front end of the controller rod and the front end of the controller rod counter-weight are securely pressed in. And in order to control the axial position of the controller rod mechanism, a member of the controller rod mechanism can be connected to a member of the CVT where it is used, that moves axially with the torque transmitting members as the transmission ratio is changed, so that the axial position of the controller rod is automatically adjusted as the transmission ratio is changed. This method is shown in
A configuration of a CVT, where a mechanical adjuster AM1181 can be utilized is shown in
The following configuration of a CVT, as shown in
The following control scheme can be used to properly control the controller rod motor and the transmission ratio changing actuator. First of all as described earlier, the axial position of the controller rod 181-M10 should only be changed when follower 181-M4 is in contact with the diameter DC of cam 181-M1, otherwise stalling of the controller rod actuator or slipping of its limiting clutch has to occur. Although not absolutely necessary, it is nice to prevent this by attaching a rotational position sensor on one of the cone assemblies of the CVT shown in
For the mechanical adjuster AM1181, shown in
A configuration where two mechanical adjusters AM2182 are used to reduce/eliminate transition flexing for a CVT 1.3 is shown in
Also for a cone assembly CS424, such as cone assembly CS4A/B/C/D 24A/B/C/D, no non-torque transmitting member is used. Hence in order to maintain the longitudinal shape of the transmission belts as the transmission ratio is changed, guiding wheels 200 or a guides can be mounted on the tense side of the transmission belts such as shown
In order to compensate for the inaccuracy or absence of any adjusters in order to reduce/eliminate transition flexing another method besides relaying on the flexibility of the transmission belts or using spring-loaded adjusters is by having gaps between the teeth of the torque transmitting members and the torque transmitting devices coupled to them. This method will be referred to as the “gaps between teeth” method. Here, the pitch, p, of the teeth of the torque transmitting members and the pitch, p, of the teeth of their transmission belts are equal, but the width of the space between the teeth are slightly wider than the width of the teeth so that gaps between the teeth are formed. It is recommended that the gaps are wide enough so that despite the inaccuracy of the adjusters, transition flexing can be eliminated. A partial sectional view of a torque transmitting member about to be engaged with a transmission belt, where between their teeth gaps, g1 and g2, exist is shown in
In order to reduce/eliminate transition flexing, when only one torque transmitting member is engaged, the adjuster(s) ensure that when the torque transmitting member about to be engaged is mated with its transmission belt, the teeth of that torque transmitting member are positioned between the teeth of its transmission belt but not touching the teeth of its transmission belt. Here a “gap offset value” can be added to the value of adjustments needed as based on the graphs in FIGS. 21A/B/C. The “gap offset value” is based on the amount of rotational adjustments needed in order to position the torque transmitting member or tooth about to be engaged in the middle of the space between the teeth of its transmission belt instead of being engaged with the teeth of its transmission belt. If the torque transmitting member or tooth currently engaged is engaged with the teeth or tooth of its transmission belt, the adjustments based on the graphs in FIGS. 21A/B/C will position the torque transmitting member or tooth about to be engaged so that it is engaged with the teeth of its transmission belt. In order to position the torque transmitting member or tooth about to be engaged in the middle of the space between the teeth of its transmission belt, the transmission belt about to be engaged has to be moved relative its torque transmitting member which is about to be engaged by an amount that corresponds to (“the width of a tooth shape of a torque transmitting member that is positioned between a space between two teeth of its transmission belt” minus “the width of a space between two teeth of its transmission belt”) divided by two, this rotational adjustment is designated as the “gap offset value”, which should be programmed into the controlling computer so that to each adjustment value obtained from the graph in
If the leading surfaces of the teeth of the engaged torque transmitting members are engaged with the teeth of their transmission belt during normal operation, then to each “phase arc length for cone assembly CS3C 23C” and “phase arc length for cone assembly CS3D 23D” values obtained from the graph in
If the trailing surfaces of the teeth of the engaged torque transmitting members are engaged with the teeth of their transmission belt during normal operation, then to each “phase arc length for cone assembly CS3C 23C” and “phase arc length for cone assembly CS3D 23D” values obtained from the graph in
If based on experimentation a different “gap offset value” works better than the one described previously, than that “gap offset value” can be programmed into the controlling computer. The “gap offset value” can be any value as long as the teeth of the transmitting members about to be engaged are positioned between the teeth of their transmission belt without any interference. And once one or several teeth of the torque transmitting member about to be engaged is positioned between the teeth of its transmission belt, the adjuster adjust the relative rotational position between the torque transmitting member about to be engaged and its transmission belt so that the teeth are touching the teeth of their transmission belt such that the engagement between the teeth can be used for desired torque transmission. This can be done by adjusting the rotational position of the transmission pulley of the transmission belt about to be engaged, adjusting the rotational position of the cone assembly about to be engaged by adjusting the rotational position of the other transmission pulley, or by a combination of the two previous adjustment methods for example. Once the teeth are engaged as desired, the adjuster can stop rotating. This type of adjustment will be referred to as “engagement adjustment”.
Ideally “engagement adjustment” should start once one tooth of the torque transmitting member about to be engaged is positioned between the teeth of its transmission belt. And ideally engagement adjustment should stop once the teeth of that torque transmitting member are touching the teeth of their transmission belt. If this kind of adjustment is not practical because of accuracy limitations, then engagement adjustment can start during a window when say two to three teeth of the torque transmitting member about to be engaged are positioned between the teeth of its transmission belt, or during an even later and larger window. This can be done by adding a delay value in degrees as to when “engagement adjustment” should start after the beginning of engagement statuses 3 and 7. However, the delay value selected should be small enough so that engagement between the teeth about to be engaged occurs before the currently engaged torque transmitting member disengages. Also a second delay value that starts at the end of the delay value discussed previously can be used to program when “engagement adjustment” should stop. Engagement adjustment can be stopped at any time before that torque transmitting member disengages with its transmission belt. Engagement adjustment is not absolutely necessary, but it can eliminate shock loads if the “gaps between teeth” method is used. In order to control the adjuster(s) to perform “engagement adjustment”, the controlling computer uses the delay value and second delay value described in this paragraph in conjunction with the engagement statuses described previously.
Also here because of the space between the teeth of the torque transmitting member and the transmission belt, in instances when the output shaft is pulling the input shaft, which might occur due to friction in the engine and inertia that wants to keep the output shaft rotating, the currently engaged teeth of the torque transmitting member will rotate relative to its transmission belt so that under this condition the engaged surfaces are different than the engaged surfaces during normal operation. For example for a certain configuration, under this condition the leading surfaces are engaged instead of the trailing surfaces, which are engaged during normal operation. This problem can be avoided by avoiding having the output shaft pulling the input shaft, which can be done by mounting a one way clutch between the output shaft and the output device being rotated, so that the output shaft can rotate the output device in the driving direction but the output device can not rotate the output shaft in the driving direction, and by ensuring that the friction in the output shaft is larger than in the engine. A one way clutch which can be locked or which direction can be reversed on command can be used in case reverse rotation is required. Another method to solve this problem is by using a tension measuring load-cells on the tense side and slack side of the transmission belt or transmission belts. Here a tension measurement on the side that is slack during normal operation that is larger than that of the side that is tense during normal operation indicates that the output shaft is pulling the input shaft, and this information can then be used by the controlling computer to appropriately control the adjuster(s).
In order to account for transition flexing and transmission ratio change rotation, the cone assemblies and transmission pulleys of a CVT, which rotational positions need to be adjusted can be mounted using friction clutches, which slip once their torque limit is exceeded. Slipping of the friction clutches allow the rotational position of the cone assemblies and transmission pulleys mounted on them to be adjusted. Although simple and cheap, this method of adjustment might cause significant energy loses due to frictional slippage and limit the amount of torque that can be transmitted. However, the friction clutch mounting method can be used as a safety measure in case the adjusters malfunction.
For CVT 2.1, torque sensors are used to measure the pulling loads on the transmission pulleys. Another method to measure, or in this case estimate, the pulling load on a transmission pulley is by measuring the tension in the tense side of transmission belt BL232 via a load cell 135, see
Furthermore, the angle between the horizontal plane and the tense side of transmission belt BL232 will be referred to as angle α1 and angle α2. Smaller values for angle α1 and angle α2 are preferred, so that a load cell 135 with a smaller load rating can be used. In order to determine the tension in transmission belt BL232, besides monitoring the measurement of load cell 135, the controlling computer of the CVT also needs to determine the angle α1 and angle α2. This can be done by programming the values for angle α1 and angle α2 for every transmission ratio, which is monitored, into the computer. Another method that can be used is by programming into the computer an equation for angle α1 and angle α2 based on the transmission ratio.
In this section some additional embodiments for CVT 1 and CVT 2 or parts for CVT 1 and CVT 2 are described. The adjuster systems and the adjustment methods described earlier in this disclosure can be used for all of the additional embodiments described below.
In the sliding cone mounting configuration, in order to change the transmission ratio, the axial positions of the cones relative to their frame are changed, while the axial positions of the torque transmitting members and the transmission pulleys are held fixed relative to their frame. Using the sliding cone mounting configuration, the design for some CVT's can be simplified. Especially the design where a differential adjuster shaft is used.
A portion of the sliding cone mounting configuration is shown as a partial top-view in
In addition, in case the sliding cone configuration is used for a CVT 1.2 or CVT 2, in order to properly maintain the tension of the transmission belts the tensioning mechanism shown in
In case a chain is preferred instead of a belt, then a torque transmitting member that can accommodate a chain can be designed. For example, if a slightly modified bicycle chain is used, then links forming a torque transmitting member chain or a single tooth link can be used. The front-view of a modified bicycle chain link is shown in
Furthermore, in order to attach a torque transmitting member chain to a cone assembly, the end links of the torque transmitting member chain each have a base to which a link attachment plate is attached. Each link attachment plate is identical to the attachment plate 1048 described in the Mover Mechanism section of this disclosure except that the disk shape at the top end of attachment plate 1048 is omitted. Hence the link attachment plates can be used to secure the end links to their cone and mover telescope in the same manner as an attachment plate 1048 is used to secure the ends of a torque transmitting member to its cone and mover telescope. The end link configuration for a link A 270, and its link A attachment plate 270-S5, which in its cone assembly's assembled state is slit into a slot of its cone and attached to a mover telescope, is shown as a side-view as seen from the right side of the link in
In addition, in order to maintain the shape of the torque transmitting member chain, it is recommended that the torque transmitting member chain is maintained under slight tension. Hence the engaging surfaces of the slots should be narrow enough and have sufficient depth to maintain the proper alignment of the link attachment plates.
Also, a molded torque transmitting member made out of flexible material, such as rubber for example, can also be used to accommodate a chain. In cases, where torque transmission is between the side surfaces of the torque transmitting members and their transmission belts, the neutral-axis of the torque transmitting members and their transmission belts coincide, almost coincide, or can be easily made to coincide by proper reinforcement placement or dimensioning. As should be known by somebody skilled in the art, the location of the neutral-axis of a torque transmitting member can easily be adjusted by adjusting the location of the reinforcement, as shown in
For the designs described above for optimum performance, the surface of the cone utilizing a torque transmitting member chain, a single link tooth, or a chain torque transmitting member, should be shaped to accommodate the base(s) of the torque transmitting member chain links, single link tooth, or a chain torque transmitting member so that during operation no or minimal deformation of the transmission chain occurs as it comes in and out of contact with its torque transmitting member. This can be achieved by increasing the thickness of the side surface(s) of the cone which are never covered a torque transmitting member chain, single link tooth, or chain torque transmitting member, as to compensate for the thickness of the base(s) of the torque transmitting member chain links, single link tooth, or a chain torque transmitting member.
Using the description above, somebody skilled in the art should be able to construct a torque transmitting member for other chains, such as an inverted chain for example. And he/she should also be able to construct a torque transmitting member made out of chain links for various transmission belts. Here for smooth operation, the bending axis of the torque transmitting member made out of chain links, which location is determined by the location of the chain rivet holes, should coincide with the neutral-axis of its transmission belt.
Previously it was mentioned that a torque transmitting member can be constructed out of two separate side members. For smooth operations, it is recommended that the location of the height center-line of the teeth used for torque transmission of the side members and the neutral-axis of the side members, which under this configuration will be referred to as torque transmitting side members, are located in the same horizontal plane, see
A detailed view of a torque transmitting side member 280, which can be used as a left torque transmitting side member, is shown in
An example of other CVT's that can benefit from the concepts and adjuster systems of this disclosure are slightly modified CVT 2s that instead of the cone assemblies with torque transmitting members, uses a single tooth cone, which is a cone that has one fixed tooth 290-S3 that elongates from the single tooth cone smaller end 290-S1 to the cone's larger end on the single tooth cone side surface 290-S2, as shown as a top-view in
One method to increase the transmission ratio range for a single tooth cone CVT 2 is by using a supporting wheel, which is used to increase the coverage of the transmission belt on the surface of its cone for transmission ratios where it is required. In order to properly adjust the position of the supporting wheel as the transmission ratio is changed, a slide and a slider similar to the ones used for a tensioning wheel can be used for the supporting wheel. An example of this configuration is shown in
Another method to increase the transmission ratio range for a single tooth cone CVT 2 is by using an adjuster to compensate for the limited coverage of the single tooth cones. Here in instances where the transmission belts are not providing sufficient coverage, the adjuster(s) rotate the cone currently not engaged in the direction that the cone is rotating a sufficient amount so that the cone currently not engaged comes into engagement before the cone currently engaged comes out of engagement.
Also in order to prevent bending of a tooth of a transmission belt due to the moment created by the force applied by the fixed tooth on a tooth of the transmission belt, a supporting surface can be shaped on the side surface of a single tooth cone, see
And a specialized transmission belt that can be used with a supported single tooth cone is shown as a top-view in
Many variation of a single tooth cone can be devised. For example, instead of being straight, the fixed tooth and the supporting surface, if used, can be positioned at an angle relative to the surface of their cone; or an involute or modified involute shaped surfaces can be used for the fixed tooth and/or the supporting surface; or an inverted chain which has links for which a tooth profile is cut out, which engagement with the fixed tooth help maintain the orientation of the link currently engaged during torque transmission, can also be used. Such an inverted chain can be construct from links and pins in a similar manner as the chains described in the Torque Transmitting Member for Chain section are constructed. However here, it is desirable to have the centers of the pins of the chain located at the height mid-point of the tooth cut out profile at the mid-cross-sections of the link or mid-section of a pair of parallel links. If this the case, then torque transmission does not cause the link transmitting torque to bend out of its ideal alignment. This allows the tooth cut-out profile of a link to be slightly wider than its mating fixed tooth, since the engagement of the back surface of the fixed tooth with the tooth cut-out profile of a link is not needed in order to main ideal alignment of that link.
Basically a cone with a single fixed tooth, can be treated like a cone with a torque transmitting member except that here the coverage provided by a fixed tooth is most likely less than the coverage provided by a torque transmitting member. Also here an inverted belt or chain has to be used as a transmission belt. The main disadvantage of a cone with a single fixed tooth over a cone with a torque transmitting member is that here uneven wear of the fixed tooth can cause problem during transmission ratio change; and an inverted belt or chain is most likely less efficient in transmitting torque than a belt or chain that can be used with a cone with a torque transmitting member.
Since the adjusters can minimize transition flexing, it is desirable to stiffen the transmission belt using reinforcement. A reinforced transmission belt 300 is shown as a top-view in
Below is an alternate belt, which will be referred to as the pin belt that can be used as a means for coupling for a CVT 2. This belt, which is shown as side-view in
A cone assembly that can be used with this belt and a chain is a cone assembly with a one tooth or two oppositely placed teeth, although many other conceivable cone assemblies could also be used. A design for a cone assembly with one tooth is shown as a front-view for which the front half surface of a cone 440 and its larger end cover 445 has been removed in
In order to mount the tooth carriage 450 to cone 440, two radial slides 460 and one longitudinal slide 480 are used. The radial slides 460 are parallel to each other and extend radially outwards from spline 430. They are fixed to a radial slides sleeve 461 that can freely slide and freely rotate relative to spline 430. The radial slides 460 should be long enough so that they are engaged with their tooth carriage at the smallest pitch diameter and the largest pitch diameter of their cone. Although this is not absolutely required, in order to reduce the vibration due to the centrifugal force of the tooth carriage 450 and its mounting parts, a radial counter-balance slide 462 is fixed opposite of the radial slides 460 on the radial slides sleeve 461. The dimension of the radial counter-balance slide 462 should designed so that it weighs the same amount as the two radial slides 460, and it should be positioned in between the two radial slides an equal distance from each radial slide. The radial counter-balance slide 462 is used to control the axial position of a counter-balance 464 described later. Furthermore, at each end of the radial slides sleeve 461, an oversized flange is shaped. The longitudinal slide 480 is parallel to the centerline of longitudinal cut 440-S1 of cone 440, on the removed surface of cone 440. Because of the radial slides 460, which are positioned so that they can extend out through the longitudinal cut 440-S1 of the cone, the longitudinal slide cannot be placed directly below the longitudinal cut of the cone, hence the longitudinal slide 480 is placed either sufficiently in front of the longitudinal cut or to the back of the longitudinal cut. The ends of the longitudinal slide are threaded for mounting purposes. In order to mount-the longitudinal slide to the cone 440, the smaller end of the cone, see
Although this is not absolutely necessary, in order to reduce or eliminate vibrations due to the centrifugal forces, a counter-balance longitudinal slide 482 is mounted opposite of the longitudinal slide 480. However, unlike the longitudinal slide, which is parallel to the tapered surface of the cone, the counter-balance longitudinal slide is parallel to spline 430, this will simplify the design considerably, although using this configuration, the counter-balance 464, which should have the same weight as the tooth carriage 450 and which has a vertical hole that can engage with the radial counter-balance slide 462, mounted on the counter-balance longitudinal slide 482, will not always be positioned perfectly opposite of the tooth carriage 450, hence the cone assembly will not always be perfectly balanced. In order to perfectly balance the cone assembly, a set-up identical to the tooth carriage, except that its tooth carriage is toothless while still having the same weight can be used. The counter-balance longitudinal slide 482 is mounted to the cone assembly in a similar manner as longitudinal slide 480. Here for cone 440, a counter-balance longitudinal slide hole 440-S5, through which one end of the counter-balance longitudinal slide 482 can be slid through, exist. And for the larger end cover 445, an end cover counter-balance longitudinal slide hole 445-S2 exist.
A slightly modified cone 440 that has two oppositely positioned tooth carriages 450, which are both toothed, can be used in a CVT 1. For this CVT 1 an adjuster can be used to increase the duration at which the transmission ratio can be changed, but no adjuster can be used to reduce/eliminate transition flexing. Therefore, sufficient flexing in the pin belts needs to be allowed or the transmission ratios where transition flexing occurs can be skipped.
In order to mount the tooth carriage 450 to the radial slides 460, the tooth carriage has two parallel radial slider holes 450-S2, which should have an inner surface made out of a low friction material, that are straddling the tooth 450-S1 of the tooth carriage 450. Here the radial slides are simply slid into the radial slider holes of the tooth carriage. In order to mount the tooth carriage to the longitudinal slide 480, a longitudinal slider hole 450-S3, which should also have an inner surface made out of a low friction material, exists on the tooth carriage. Here the longitudinal slide is simply slid into the longitudinal slider hole 450-S3. Also, in order to mount the radial slides sleeve 461 to spline 430, radial slides sleeve 461 is slid onto spline 430 and then its axial position is secured by two spline collars 470 that are sandwiching the radial slides sleeve 461. For better performance, a radial slides sleeve axial bearing 72, which is a washer shaped item made out a low friction material, is placed between each spline collar 470 and the radial slides sleeve 461. In order secure the axial position of the spline collar 470 and hence the axial position of radial slides sleeve 461, at the positions where a spline collar 470 needs to be attached, a portion of the outer surface of spline 430 is machined down. The spline collar 470, which is of the split collar type (two halves joined and secured by set screws), has the profile of the machined down portion of spline 430. An end-view of a spline collar 470 mounted on a machined down portion of spline 430 is shown in
Furthermore, a CVT needs two cones 440 in order to operate. The mounting of each cone is slightly different. Hence one cone assembly is labeled as front sliding tooth cone assembly 420A and the other cone assembly is labeled as back sliding tooth cone assembly 420B. Front sliding tooth cone assembly 420A is identical to back sliding tooth cone assembly 420B, the only difference between them is the front end portions of their cones used for mounting purposes, and the back end portions of their larger end covers used for mounting purposes. For front sliding tooth cone assembly 420A, shown in
In order to transmit torque from or to the cone assemblies a gear 500, shown in
An assembled CVT 2 input/output shaft utilizing a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B is shown as a side-view in
In order to assemble the CVT, first spline shaft extension 432 is securely pressed into spline 430, so that it is axially and radially fixed to spline 430. Then gear 500 is secured to spline shaft portion B 432-S2 of spline shaft extension 432 using a set-screw. Next spline 430 is slid into a spline bearing A 490A until the left shoulder of spline shaft extension 432 engages with the side surface of spline bearing A 490A facing it, obviously it should be a surface that allows the left shoulder of spline shaft extension 432 to rotate easily relative to the frame on which spline bearing A 490A is mounted. Next spline bearing A 490A is secured to a frame using bolts that engage with a spline bearing A mounting base 490A-S1. Next the spline bearing B 490B is slid into spline shaft portion C 432-S3 until the right shoulder of spline shaft extension 432 engages with the side surface of spline bearing B 490B facing it, obviously it should be surface that allows the right shoulder of spline shaft extension 432 to rotate easily relative to the frame on which spline bearing B 490B is mounted. Next spline bearing B 490B is secured to a frame using bolts that engage with a spline bearing B mounting base 490B-S1.
Once spline 430 is secured into position, front sliding tooth cone assembly 420A and back sliding tooth cone assembly 420B will be mounted on spline 430. In order to reduce the stress on spline 430, the cone assemblies are supported by cone supporting members. A cone supporting member is shaped like a 90 degree L with equal length legs. At the intersection of the legs a cone bearing, which has a round shaft shape low friction inner surface, exist. At the end of each leg a support slider, which also has a round shaft shape low friction inner surface, exist. Here, the cone bearings will be slid into the front or back portion of the cone assemblies; and one support slider will be slid unto a vertical supporting pipe 510, which is shaped like a round pipe, and the other support slider will be slid unto a horizontal supporting pipe 515, which is also shaped like a round pipe. Therefore, first a cone axial bearing 492 is slid into the front cone bearing shaft 440A-S2. Then cone bearing A 491A-S1 of cone supporting member A 491A is slid into the front cone bearing shaft 440A-S2. Next another cone axial bearing 492 is slid into the front cone bearing shaft 440A-S2. And finally a cone locking ring 493 is inserted into front cone locking ring groove 440A-S3. Here due to engagement of the front cone bearing stop surface 440A-S1 and the cone locking ring 493 with the cone axial bearings 492 sandwiching the cone bearing A 491A-S1, the axial position of front sliding tooth cone assembly 420A is fixed relative to the axial position of cone bearing A 491A-S1. Next the vertical support slider A 491A-S3, which is connected to cone bearing A 491A-S1 by a vertical support rod A 491A-S2, is slid into the vertical supporting pipe 510, while at the same time the horizontal support slider A 491A-S5, which is connected to the cone bearing A 491A-S1 by a horizontal support rod A 491A-S4, is slid into the horizontal supporting pipe 515, see
Next the longitudinal slide 480 is slid through the cone slide mounting hole 440-S3, bolted to the front surface of that hole, and temporarily support. Then the counter-balance longitudinal slide 482 is also bolted on to the front surface of the cone and temporarily supported, see
Next a cone axial bearing 492, is slid unto front cone larger end cover bearing shaft 445A-S3 and this end of front sliding tooth cone assembly 420A is supported by sliding in cone bearing B 491B-S1 of cone supporting member B 491B into front cone larger end cover bearing shaft 445A-S3, see
Then a cone axial bearing 492 is slid onto back cone bearing shaft 440B-S2 of back sliding tooth cone assembly 420B, see
Then the larger end of back sliding tooth cone assembly 420B is supported by first sliding in a cone axial bearing 492 into the back cone larger end cover bearing shaft 445B-S2 and then sliding in cone bearing C 491C-S1 of cone supporting member C 491C unto back cone larger end cover bearing shaft 445B-S2, while at the same time the vertical support slider C 491C-S3, which is connected to the cone bearing C 491C-S1 by a vertical support rod C 491C-S2, is slid into the vertical supporting pipe 510, and the horizontal support slider C 491C-S5, which is connected to the cone bearing C 491C-S1 by a horizontal support rod C 491C-S4, is slid into the horizontal supporting pipe 515, see
In order to attach the actuator used to change the transmission ratio to the CVT 2 input/output shaft described above, a cone supporting member actuator bar 1700 is attached to each cone supporting member, which for the CVT 2 input/output shaft described above are cone supporting member A 491A, cone supporting member B 491B, and cone supporting member C 491C. For each cone supporting member, the cone supporting member actuator bar 1700 is positioned so that it connects the horizontal support slider, which slides on a horizontal supporting pipe 515, with the vertical support slider, which slides on a vertical supporting pipe 510, of a cone supporting member. The cone supporting member actuator bar 1700 can be seen in
The design methods for the tooth carriage cone assembly described above, can also be used to design a cone assembly with one torque transmitting member, which here is labeled as pin belt torque transmitting member 590, and one non-torque transmitting member, which here is labeled as pin belt non-torque transmitting member 690 and is used to counter-balance the centrifugal force of pin belt torque transmitting member 590 and help maintain the alignment of the transmission belt when the transmission belt is not engaged with the torque transmitting member. Here this cone assembly, which labeled as front pin belt cone assembly 520A is shown in as a front-view where portions of it front surface has been removed in
The pin belt torque transmitting member 590 and its parts are shown as a top-view in
The reinforcement plates are flat channel shaped plates that have a round flange 591-S1 on which a pin belt tooth 591-S2, is shaped on both its inner facing surfaces. A pin belt tooth 591-S2 is shaped from a tubular section for which a radial section is removed. It consists of a tubular section, which starts at the center height of a round flange 591-S1 and ends near the bottom of round flange 591-S1, but extends slightly beyond the bottom of round flange 591-S1, see
In addition, for reinforcement plate 591, near each round flange, a hole for a reinforcement wire 594 exist. For increased strength, once mounted on the reinforcement wires, before being coated with rubber, the reinforcement plates can be bonded to the reinforcement wires using epoxy. For smooth engagement and optimal performance, the neutral-axis of pin belt torque transmitting member 590 is positioned so that the centers of the round flanges 591-S1 are located on the neutral-axis, and the reinforcement wires 594 should also be located on the neutral-axis. And the area of the left channel side is identical to the area of the right channel side, although this might be ignored if this increases the cost of pin belt torque transmitting member 590 significantly. Also since the rubber surfaces of torque transmitting member are not used for torque transmission, in order minimize friction loses and wear, they have a low friction surface.
Furthermore, in order secure pin belt torque transmitting member 590 to front pin belt cone assembly 520A, the leading end of pin belt torque transmitting member 590, has a leading plate 592 molded in it. Leading plate 592, see
In addition, in order to secure the trailing end, of pin belt torque transmitting member 590 to front pin belt cone assembly 520A, at the trailing end, a trailing plate 593 is molded into pin belt torque transmitting member 590. Trailing plate 593, shown in
Also the pin belt torque transmitting member 590, has an extension 595, see
Also, the arc length of a pin belt torque transmitting member 590 should be short enough so that for the CVT where it is used, its transmission belt will never cover the entire non-torque transmitting arc of its cone. However, the arc length of pin belt torque transmitting member 590 should be long enough so that for the CVT where it is used, at least a torque transmitting surface of at least one pin belt torque transmitting member 590 is always engaged with its transmission belt.
Furthermore, an increase in lateral stiffness of pin belt torque transmitting member 590 allows more torque to be transmitted when a load in the direction from trailing plate 593 to leading plate 592 is applied to pin belt torque transmitting member 590. Since this allows more load to be carried through the engagement of the lower portion of trailing plate sleeve 593-S1 with trailing end cuts 540-S6. Without sufficient lateral stiffness of pin belt torque transmitting member 590, a too big of a load carried through the engagement of trailing plate sleeve 593-S1 with trailing end cuts 540-S6 would cause too much lateral bending of pin belt torque transmitting member 590.
The lateral stiffness of pin belt torque transmitting member 590 can be increased by the following or combination of the following, by increasing the width of pin belt torque transmitting member 590; by increasing the stiffness of the rubber of pin belt torque transmitting member 590; by increasing the size of the reinforcements of pin belt torque transmitting member 590, by increasing the lateral distance between the reinforcements of pin belt torque transmitting member 590; by adding additional reinforcements, which like the reinforcements of pin belt torque transmitting member 590 should also be located at the neutral-axis of pin belt torque transmitting member 590, to pin belt torque transmitting member 590; and/or by having reinforcement shapes shaped on the outside side surfaces of pin belt torque transmitting member 590, similar to the lateral bending reinforcement 280-S2 of the torque transmitting side member 280 described in the Torque Transmitting Side Members section of this disclosure and shown in
Front pin belt cone assembly 520A and back pin belt cone assembly 520B, described later, are primarily designed to carry a large amount of load in the direction from leading plate 592 to trailing plate 593. The load in this direction should be carried when the input shaft of the CVT where the cone assemblies are used is pulling the output shaft of that CVT. Front pin belt cone assembly 520A and back pin belt cone assembly 520B are not designed to carry a large amount of load in the direction from trailing plate 593 to leading plate 592, which should be carried when the the output shaft of the CVT where the cone assemblies are used is pulling the input shaft of that CVT. The load in in the direction from trailing plate 593 to leading plate 592 can be limited by using friction clutches, or even eliminated by using one-way clutches.
The pin belt non-torque transmitting member 690 and its parts are shown in
Furthermore, if its desirable to use friction to transmit torque than a torque transmitting member similar to pin belt torque transmitting member 590, labeled as alternate friction torque transmitting member 1590, shown as a top-view in
As described earlier, alternate friction torque transmitting member 1590 should have a cross-section that has a cut-out portion that has the shape of a tapered base V-belt. For smooth engagement and optimal performance, the neutral-axis of alternate friction torque transmitting member 1590 is positioned so that when it is engaged with its tapered base V-belt, the neutral-axis of the tapered base V-belt used with alternate friction torque transmitting member 1590 is located on the neutral-axis of alternate friction torque transmitting member 1590. Also, the reinforcement wires of alternate friction torque transmitting member 1590 should be located on the neutral-axis of alternate friction torque transmitting member 1590; and the reinforcement wires of its tapered base V-belt should also be located on the neutral-axis of that tapered base V-belt. A drawing that shows a cross-sectional-view of alternate friction torque transmitting member 1590 that is engaged with its V-belt, which is labeled as V-belt 1600, is shown in
In order to have a wedging action between alternate friction torque transmitting member 1590 and its tapered base V-belt so as obtain proper frictional engagement, the width of the base of the cut-out portion of alternate friction torque transmitting member 1590 is slightly less than the width of the base of its tapered base V-belt. For optimal torque transmission, the surface finish or surface coating of alternate friction torque transmitting member 1590 should be selected such that a large coefficient of friction between alternate friction torque transmitting member 1590 and its tapered base V-belt can be obtained. Also if alternate friction torque transmitting member 1590 is used instead of pin belt torque transmitting member 590, than for its non-torque transmitting member instead of pin belt non-torque transmitting member 690, an alternate friction non-torque transmitting member 1690 is used. Alternate friction non-torque transmitting member 1690 is identical to alternate friction torque transmitting member 1590, except that instead of having a cut-out portion that has a base with a width that is slightly less than the width of the base of its tapered base V-belt, it has a cut-out portion that has a base with a width that is slightly more than the width of the base its tapered base V-belt so as to eliminate the wedging action. In order to maintain the radial position of the tapered base V-belt when it is engaged with alternate friction non-torque transmitting member 1690, the increase in the width of the base of the cut-out portion of alternate friction non-torque transmitting member 1690 has to accompanied by a corresponding increase in height of the base of the cut-out portion of alternate friction non-torque transmitting member 1690. Also the surfaces of alternate friction non-torque transmitting member 1690 that engage with its tapered base V-belt should have a low-friction surface finish. If a leveling loop, which was described earlier, is used, alternate friction torque transmitting member 1590 and alternate friction non-torque transmitting member 1690 can be used with a regular V-belt. A drawing that shows a cross-sectional-view of alternate friction non-torque transmitting member 1690 that is engaged with its tapered base V-belt, which is labeled as tapered base V-belt 1600, is shown in
The pin belt cone 540 used for front pin belt cone assembly 520A is shown as a front-view in
In addition, pin belt cone 540 also has two oppositely positioned trailing end cuts 540-S6. In the cone's assembled state, into the trailing end cuts 540-S6, the lower portions of the sleeves of trailing plate 593 and non-torque trailing plate 693 into which the trailing end slides 565-S1 of the trailing end slides sleeve 565 are inserted, are inserted. The trailing end cuts 540-S6 are shaped so that for a pin belt torque transmitting member 590 attached between a leading end cut 540-S1 and a trailing end cut 540-S6, the neutral-axis arc length of that pin belt torque transmitting member 590 remains constant as that pin belt torque transmitting member 590 is moved to different axial locations on the surface of its cone; in addition, that pin belt torque transmitting member 590 should also wrap tightly around the surface of its cone without lifting. The exact shape of the trailing end cuts 540-S6 can be easily obtained experimentally by attaching the leading end of pin belt torque transmitting member 590 to the assembled cone and tracing the movement of the trailing plate sleeve 593-S1. For experimental purposes, a specialized pin belt torque transmitting member 590, for which the trailing plate sleeve 593-SI does not extend beyond the bottom surface of pin belt torque transmitting member 590, can be used. Somebody skilled in the art should also be able to determine the shape of the trailing end cuts 540-S6 mathematically.
Also the percentage of circumferential surface of the axial section of pin belt cone 540 covered by its pin belt torque transmitting member 590 and its pin belt non-torque transmitting member 690 decreases as the pitch diameter is increased. In order to provide a level resting surface for the transmission belt at the surface of pin belt cone 540 that will not be covered by pin belt torque transmitting member 590 and pin belt non-torque transmitting member 690, leveling surfaces 540-S7 are glued on to the surface of pin belt cone 540. The leveling surfaces 540-S7 are rubber sheets that have the same thickness as the thickness of the base of pin belt torque transmitting member 590 and pin belt non-torque transmitting member 690, and are shaped as to cover as much surface of pin belt cone 540 without interfering with the operation of pin belt torque transmitting member 590 and pin belt non-torque transmitting member 690. Two identical leveling surfaces 540-S7 are glued on the surface of pin belt cone 540 opposite from each other.
As in the configuration for a CVT 2 input/output shaft utilizing a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, in addition to a pin belt cone 540, a back pin belt cone 540B is also needed. Except the front shaft and shoulder portions of back pin belt cone 540B, which are identical to back cone 440B, back pin belt cone 540B is identical to pin belt cone 540, see
The pin belt cone larger end cover 545 for pin belt cone 540, which can be seen in
Back pin belt cone 540B and back pin belt cone larger end cover 545B are used for a back pin belt cone assembly 520B. The only difference between back pin belt cone assembly 520B and front pin belt cone assembly 520A is the front end portions of their cones used for mounting purposes, and the back end portions of their larger end covers used for mounting purposes.
CVT 2 input/output shaft utilizing a front pin belt cone assembly 520A and a back pin belt cone assembly 520B is identical to CVT 2 input/output shaft utilizing a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, except that here instead of front sliding tooth cone assembly 420A, a back sliding tooth cone assembly 420B, and a spline 430, here a front pin belt cone assembly 520A, a back pin belt cone assembly 520B, and a pin belt cone assembly spline 530 are used. Since the teeth of front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B are positioned opposite of each other on their CVT 2 input/output shaft, the torque transmitting members of front pin belt cone assembly 520A and a back pin belt cone assembly 520B are also positioned opposite of each other on their CVT 2 input/output shaft. Also if a pin belt cone assembly with two oppositely positioned torque transmitting members, toothed or friction dependent, or a sliding tooth cone assembly with two oppositely positioned sliding teeth is used, than the mounting of a single cone assembly on a shaft/spline as shown as a top-view in
In order to assemble pin belt cone assembly 520A or back pin belt cone assembly 520B, first the trailing end slides 565-S1 of trailing end slides sleeve 565 are inserted into the trailing end cuts 540-S6 of a pin belt cone 540, then a radial slides sleeve axial bearing 472 is placed in front of trailing end slides sleeve 565. Next pin belt cone 540, radial slides sleeve axial bearing 472, and trailing end slides sleeve 565 are aligned with pin belt cone assembly spline 530 and slid onto with pin belt cone assembly spline 530. Then spline collar 470 is mounted on the designated cut on pin belt cone assembly spline 530 that is positioned near the smaller end of the pin belt cone 540.
The other parts, except the pin belt torque transmitting member 590 and the pin belt non-torque transmitting member 690, are then assembled in a similar manner as the parts for front sliding tooth cone assembly 420A are assembled. For example, in order to mount torque transmitting member carriage 550A and non-torque transmitting member carriage 550B, first the torque transmitting member slides 560-S2 of torque transmitting member radial slider sleeve 560 are inserted into the radial slider holes of torque transmitting member carriage 550A and non-torque transmitting member carriage 550B. Next, the torque transmitting member carriage 550A and non-torque transmitting member carriage 550B are aligned with their pin belt longitudinal slide 580 and the torque transmitting member radial slider sleeve 560 is aligned with pin belt cone assembly spline 530. Then torque transmitting member carriage 550A and non-torque transmitting member carriage 550B are slid onto their pin belt longitudinal slide 580 and torque transmitting member radial slider sleeve 560 is slid onto pin belt cone assembly spline 530. Once the torque transmitting member carriage 550A, non-torque transmitting member carriage 550B, and trailing end slides sleeve 565 are in position, pin belt torque transmitting member 590 and the pin belt non-torque transmitting member 690 can be mounted by sliding the leading plate sleeves onto the radial sliders and into the radial slider holes of their carriages and securing them using torque leading plate locking rings 600, and by sliding the trailing plate sleeves into the trailing end slides and into the trailing end cuts and securing them using a ball clamp 620 or dome shaped nut 621.
Pin transmission belt 630, see
CVT 2 input/output shaft utilizing a front pin belt cone assembly 520A and a back pin belt cone assembly 520B and the CVT 2 input/output shaft utilizing a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, can than be used to construct a CVT 2 by coupling each cone assembly to a matching transmission pulley or sprocket.
If front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B are used, then each cone assembly can be coupled to a sprocket that can properly engage with the transmission belts used front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B. Here the pitch of the teeth of the sprocket should match the pitch of its transmission belts. And the width of the teeth of the sprocket should match the width of the tooth of tooth carriage 450, which should be slightly less than the distance between the inner surfaces of belt member 1411 and belt member 2412 of its transmission belts.
If front pin belt cone assembly 520A and a back pin belt cone assembly 520B are used, then for each transmission pulley of a cone assembly, a twin sprocket pulley 700, shown as a front-view in
A CVT constructed from a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B is shown as a partial top-view in
Also in order for the CVT to operate properly, it needs to be ensured that at any instance during the operation of the CVT, at least one tooth of a tooth carriage 450 is engaged with its transmission belt. In order to ensure this and in order to maintain the axial alignment of the transmission belts, spring-loaded slider pulley assemblies 720 are used. A spring-loaded slider pulley assembly 720, shown in
In
Also in order to maintain the tension in the transmission belts, each transmission belt has a tensioner pulley assembly 740. A tensioner pulley assembly 740 is identical to a spring-loaded slider pulley assembly 720, except that it has a pulling spring and/or a pulling weight instead of a pushing spring. In addition, the sliding range of a tensioner pulley assembly 740 might also be different than the sliding range of a spring-loaded slider pulley assembly 720. Here the pulling spring and/or a pulling weight of a tensioner pulley assembly 740 is used to maintain the tension in a transmission belt. The pulling force of tensioner pulley assembly 740 should be large enough so that sufficient tension in its transmission belt is maintained so that no movements in the tensioner pulley assembly 740, hence no change in the shape of the transmission belt, occurs during normal operation and in instances where the direction of rotation is reversed such that the normally slack side of the transmission belt, where tensioner pulley assembly 740 is pulling, becomes the tense of the transmission belt, which occur in instances where the output shaft is pulling the input shaft. In other words, the pulling force of tensioner pulley assembly 740 should be larger than the force that tends to pull the slider of tensioner pulley assembly 740 out due to the tension in the transmission belt. However, the pushing force of spring-loaded slider pulley assembly 720 used to provide sufficient engagement coverage, such as spring-loaded slider pulley assembly C 720C, should be considerably larger than the pulling force of its tensioner pulley assembly 740 so that the pulling force of tensioner pulley assembly 740 will not affect the position of that spring-loaded slider pulley assembly C 720C, see
In case front pin belt cone assembly 520A and a back pin belt cone assembly 520B are used instead of front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, then the same CVT configuration shown in
In case the configuration shown in
In addition since for cone assemblies with torque transmitting members, as described earlier, no instance should exist where a complete non-torque transmitting arc is covered by its transmission belt, the spring-loaded slider pulley assemblies 720 should be repositioned to ensure this. Also in case extension 595 gets in the way, it can simply be removed.
The spring-loaded slider pulley assemblies 720 and tensioner pulley assembly 740 used for a CVT using a front pin belt cone assembly 520A and a back pin belt cone assembly 520B are identical to the spring-loaded slider pulley assemblies 720 and tensioner pulley assembly 740 used for a CVT using a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, except that spring-loaded slider pulley 720-M4 is replaced with a pin belt spring-loaded slider pulley 720-M4A, which is shown as a partial end-view in
In addition, cross-sections for various alternate pin transmission belts that can be used with front pin belt cone assembly 520A and back pin belt cone assembly 520B are shown in
Pulleys that can be used as spring-loaded slider pulleys, which are pulleys that are pressed by the spring-loaded slider pulley assemblies 720 against the surfaces of the cones and are used to maintain the axial alignment of the transmission belts and provide coverage, if required, for pin transmission belt A 630A, pin transmission belt B 630B, and pin transmission belt C 630C are shown in
It is recommended that the inner side surfaces of these pulleys, which engage with the side surfaces of their pin transmission belts, have a low friction coating, so as to minimize frictional losses. For optimum performance, friction between the inner side surfaces of these pulleys and the side surfaces of their pin transmission belts should be minimized. Hence for pin belt spring-loaded slider pulley A 721A and pin belt spring-loaded slider pulley B 721B, the distance between the inner side surfaces of these pulleys should not be narrower than distance between the side surfaces of their pin transmission belts. Also, here due to its V-shape, pin belt spring-loaded slider pulley C 721C should have the least amount of friction, since sliding friction between the inner side surfaces of this pulley with the surfaces of its pin transmission belt is minimized because contact between the side surfaces only occur at one section, which is the section where the transmission belt is closest to the center of rotation of pin belt spring-loaded slider pulley C 721C; and at this section, no relative sliding between side surfaces has to occur. Obviously like pin belt spring-loaded slider pulley 720-M4A, shown in
For the tensioning pulleys of tensioner pulley assemblies 740, which are used to apply tension to the slack side of the transmission belts, like for the spring-loaded slider pulleys described in the previous paragraph, for optimum performance it is desirable to have the friction between the inner side surfaces of the tensioning pulleys and the side surfaces of their transmission belts minimized. This can be achieved by utilizing alignment wheels pulley assembly 730 shown as a front-view in
As described earlier, tensioner pulley assembly 740 is identical to spring-loaded slider pulley assembly 720, except that it has a pulling spring and/or a pulling weight instead of a pushing spring. There fore, it also has a clevis on which a pulley or in this case an alignment wheels pulley assembly can be mounted. The clevis for tensioner pulley assembly 740 is labeled as tensioner pulley clevis 740-M3. Tensioner pulley clevis 740-M3 is identical to spring-loaded slider pulley clevis 720-M3, except that it has square holes for a square rod 732 instead of round holes for a spring-loaded slider shaft 720-M5 that spring-loaded slider pulley clevis 720-M3 has. And obviously if tensioner pulley clevis 740-M3 is used for an alignment wheels pulley assembly 730, the dimension of tensioner pulley clevis 740-M3 has to be adjusted accordingly so that an alignment wheels pulley assembly can be mounted on it as shown in
In the assembled state of alignment wheels pulley assembly 730, alignment wheels pulley shaft 731 is placed between the two parallel plates of tensioner pulley clevis 740-M3, and secured by sliding, a square rod 732, which has slightly smaller dimensions than the square cut of alignment wheels pulley shaft 731 through the square cut of alignment wheels pulley shaft 731 and square holes of the parallel plates of tensioner pulley clevis 740-M3. Once slid through, each end of square rod 732 is then secured in place using a square rod locking pin 733 that is slid into a matching hole at each end of square rod 732. In the alignment wheels pulley assembly 730 assembled state, a tensioning pulley 734 is positioned on the alignment wheels pulley shaft round shape 731-S2 of alignment wheels pulley shaft 731. Obviously all items on alignment wheels pulley shaft 731 are inserted into alignment wheels pulley shaft 731 before alignment wheels pulley shaft 731 is positioned between the two parallel plates of tensioner pulley clevis 740-M3. At the center of tensioning pulley 734 a tensioning pulley sleeve bearing 734-M1 is pressed in. Tensioning pulley sleeve bearing 734-M1 extends slightly to the left and right surface of tensioning pulley 734, so as to minimize friction between tensioning pulley 734 and the alignment frames 735 placed to the left and right of tensioning pulley 734. The top shape of each alignment frame 735 is shaped like a square frame that can be tightly slid into an alignment wheels pulley shaft square shape 731-S1 of alignment wheels pulley shaft 731. At the midpoint of the bottom surface of each alignment frame 735 a round shaft, that extends vertically downwards, is shaped. The bottom portion of the round shaft of each alignment frame 735 has a smaller diameter then the upper portion of the round shaft. Also, near the bottom end of the bottom portion of the round shaft of each alignment frame 735, a cut for an alignment wheel locking ring 736 exists. Into the bottom portion of the round shaft of each alignment frame 735, an alignment wheel 737 is slid in. The axial positions of the alignment wheels 737 are then secured by inserting a alignment wheel locking ring 736 into the designated cuts of the bottom portions of the round shafts of the alignment frames 735. The inner and side surfaces of the alignment wheels 737 have a low friction coating, so that alignment wheels 737 can rotate without much friction relative to their alignment frames 735 and their alignment wheel locking rings 736. Since the alignment wheels 737 are wider than the alignment frames 735, in order to allow the alignment wheels 737 to rotate properly, an alignment frame spacer 738 is positioned between each parallel plate of tensioner pulley clevis 740-M3 and alignment frame 735.
The alignment wheels pulley assembly 730 like a regular tensioning pulley should be mounted on a tensioner pulley assembly 740 such as shown in
If desired, in order to position the pulleys that maintain the axial alignment, engagement coverage, and tension of the transmission belts, instead of the spring-loaded sliders, sliders that slide on slides as described in the Sliding Cone Mounting Configuration section and similarly used for the tensioning wheels 1105 described in Continuous Variable Transmission Variation 2 (CVT 2) section can be used. If the required pushing force of a spring-loaded slider pulley assembly 720 used to provide sufficient engagement coverage, such as spring-loaded slider pulley assembly C 720C shown in
In order to control the adjusters of the CVT's described above, the methods described earlier can be used. Although the configuration of the CVT shown in
Also in order to use the control methods described in the Gap In Teeth section, a gaps method pin belt torque transmitting member 590A can be used. A gaps method pin belt torque transmitting member 590A, shown as a front-view in
Furthermore, in order to prevent damage to the CVT in case the adjusters did not properly position the transmission belt about to be engaged so as to allow smooth engagement, a “tension measurement engagement correction” method can be used. Here the adjustments/corrections provided is based on the amount of tension in the tense side of the transmission belts. The amount tension in the tense side of the transmission belts can be measured by torque sensors mounted on the input shaft/spline of the CVT, which measure the torque on the input shaft/spline of the CVT, or by maintaining pulleys that are positioned and configured so that they can measure the tension in the tense side of the transmission belts. In order for this method to work, the transmission belts should be able to resist flexing that compensates for improper engagement. Here a sudden increase in tension or sudden increase in torque can be an indication that improper engagement occurred. In order to determine whether the increase in tension or torque is an indication of improper engagement, a high torque limit value and/or high torque change limit value, programmed into the controlling computer can be used. Or if a tension measuring load-cell is used than a high tension limit value and/or high tension change limit value, programmed into the controlling computer can be used. The values for the high limit values can be obtained experimentally.
If “tension measurement engagement correction” method is used for a CVT that uses gaps method pin belt torque transmitting members 590A, because of the shape of the quarter circular pin belt teeth 591-S2A, initial improper engagement can only occur between the back portion of the leading circular pin belt tooth 591-S2A and its transmission belt, since circular pin belt teeth 591-S2A do not have a front portion. Hence improper engagement can only occur when the cone assembly about to be engaged is to early. Therefore, when the controlling computer senses that improper engagement occurred through the tension measurement in the transmission belt just engaged, or the torque measurement for the cone assembly just engaged, it rotates the transmission belt just engaged, which is not properly engaged, forward relative to its cone assembly or it rotates its cone assembly, which is not properly engaged, backward relative to its transmission belt, until the tension and/or torque measurement has dropped to an acceptable level. Here rotating forward means rotating in the direction the input and output shaft/spline are rotating and rotating backward means rotating in the opposite direction the input and output shaft/spline are rotating. The controlling computer can use the tension measurement of the currently engaged transmission belt or torque measurement of the currently engaged cone assembly before improper engagement occurred as a reference value, a sudden jump in tension and/or torque measurement is an indication of improper engagement. A high limit tension and/or torque measurement value can also used.
If “tension measurement engagement correction” method is used for a CVT that uses pin belt torque transmitting members 590 or other torque transmitting members, then once the controlling computer senses improper engagement, it first has to guess whether it is because the cone assembly about to be engaged is positioned to early or to late relative to its transmission belt and make arbitrary adjustments, and then based on the feed-back from the tension measuring load- cell or torque sensor it can determine whether cone assembly is positioned to early or to late and then provide adjustments until the tension and/or torque measurement has dropped to an acceptable level. For example, in case the torque transmitting member is positioned to early relative to its transmission belt, then because of the increased tension in the respective transmission belt or increased torque in the respective cone assembly, the adjuster arbitrarily rotates the respective transmission belt forward relative to its cone assembly, which is the proper direction. Then the controlling computer should sense that the tension in the respective transmission belt starts to decrease and hence keep on rotating in the same direction until the tension and/or torque measurement has dropped to an acceptable level. In case in the same situation, the adjuster arbitrarily rotates the respective transmission belt backward relative to its cone assembly, then the controlling computer should sense that the tension in the respective transmission belt starts to increase or stay level, and based on this information, the controlling computer knows that it is rotating the respective transmission belt in the wrong direction, hence it immediately changes direction and keeps on rotating in that direction until the tension and/or torque measurement has dropped to an acceptable level. In case the torque transmitting member is positioned to late relative to its transmission belt, then the controlling computer uses the same procedures described before in order to reduce the respective tension and/or torque measurement, except that here, in order to reduce the respective tension and/or torque measurement the adjuster needs to rotate the respective transmission belt backwards relative to its torque transmitting member, while rotating the respective transmission belt forward relative to its cone assembly increases the respective tension and/or torque measurement.
In order to ensure that the procedures described in the previous paragraph operate properly, it needs to be ensured that when the adjuster rotates in the proper direction the respective tension and/or torque measurement decreases and it also needs to be ensured that when the adjuster rotates in the wrong direction the respective tension and/or torque measurement increases. In order to ensure this, all surfaces of the pin belt teeth 591-S2 that come into contact with the teeth of its transmission belt, are shaped so that the contact surface increase in height as it is positioned further to the left and further to the right from the lowest point, which located at the vertical symmetry line of round flange 591-S1. An example of a tooth shape which end surfaces are reshaped to ensure this is shown in
Furthermore although during normal operation at no instance should a transmission belt cover the entire surface of its cone not covered by its torque transmitting member; an emergency transmission ratio, where this is the case can be added in case one transmission belt fails. For smooth operation for the emergency transmission ratio, the circumferential arc length of the surface of the cone not covered by its torque transmitting member, as measured at the pitch-line of its torque transmitting member, should be a multiple of the width of a tooth of its teeth. Also when the emergency transmission ratio is used a warning signal should be send to the user. A warning signal alarm should also be send when continuous or excessive improper engagement occurs.
Also if only quarter circular pin belt teeth 591-S2A are used for a torque transmitting member then in order to ensure smooth and proper operation, instances where the output shaft is pulling the input shaft should be minimized or eliminate. This can be done by mounting a one way clutch between the output shaft and the output device being rotated, so that the output shaft can rotate the output device in the driving direction but the output device can not rotate the output shaft in the driving direction, and by ensuring that the friction in the output shaft is larger than in the engine. A one way clutch which can be locked or which direction can be reversed on command can be used in case reverse rotation is required. In addition, if desired the pins on the transmission belts can be replaced with involute tooth shaped pieces that engage with an involute tooth shape or involute tooth shaped pieces mounted on the torque transmitting members.
In addition for the CVT's described previously, if friction torque transmitting members, which are not toothed are used, then a CVT that does not need adjusters can be constructed by using a configuration that is identical to the configuration for a CVT 2.
A link labeled as single tooth cone link A 800A that can be used to form a chain that can be used with a single tooth cone is shown as a side-view in
Also it needs to be ensured that when the chain is positioned at the smallest circumference of its cone, no bottom surfaces of any links are interfering with the tooth of its single tooth cone. This can be done by selecting the proper smallest circumference of the single tooth cone, or by slightly modifying the shape and dimension of the links. A shape of an alternate single tooth cone link A 800A, which is labeled as alternate single tooth cone link A 810A is shown in
A single tooth cone, labeled as chain single tooth cone 820, and its tooth, labeled as chain single tooth cone tooth 820-S1, is shown as a front-view in
Shown in
A transmission pulley, labeled as chain transmission pulley 850, that can be used with a chain constructed in manner the shown in
In case the cone has only one tooth, then changes in the pitch of the teeth of the chain can be allowed. For the chain portion shown in
Since the chain is formed by links, it will not form a perfectly round segment, whereas the cone is perfectly round, hence the graphs shown in FIGS. 21A/B/C are not perfect for this application. In order to deal with this, the “gaps between teeth” method described earlier can be used to compensate for this. Modified graphs based on the graphs shown in FIGS. 21A/B/C, which are dependent on transmission ratio can also be made. A modifying term for the graphs, which can dependent on the transmission ratio and compensate for the fact that the chain will not form a perfectly round segment can be obtained experimentally and/or mathematically. An experimental method can also used, by moving the chain from the smaller end to the larger end of its cone and observing the required adjustments needed at different diameters and then programming these values into the controlling computer.
Besides the chain described in the previous paragraphs, a blocks transmission belt 842, shown as a front-view in
As can be seen from
Since the transmission belt described in the previous paragraph will not form a perfectly round segment, the graphs shown in FIGS. 21A/B/C are not perfect for this application. In order to deal with this, the “gaps between teeth” method described earlier can be used to compensate for this. Modified graphs based on the graphs shown in FIGS. 21A/B/C, which are dependent on transmission ratio can also be made. A modifying term for the graphs, which can dependent on the transmission ratio and compensate for the fact that the chain will not form a perfectly round segment can be obtained experimentally and/or mathematically. An experimental method can also used, by moving the chain from the smaller end to the larger end of its cone and observing the required adjustments needed at different diameters and then programming these values into the controlling computer.
For a CVT constructed out of single tooth cone, opposite teeth cone, or any other cone or cone assembly described in this disclosure, the transmission ratios where adjustment (rotational adjustment) to reduce/eliminate transition flexing is required can be skipped so that no adjusters to reduce/eliminate transition flexing are required. The transmission ratios where no adjustments (rotational adjustment) to reduce/eliminate transition flexing are required can be obtained through experimentation, mathematics, or other methods; it is believed that somebody skilled in the art should know how to do this.
Another method to obtain a function to reduce/eliminate transition flexing for a cone/cone assembly or a pair or more of cones/cone assemblies, which provides the controlling computer with the amount of adjustment to reduce/eliminate transition flexing required for a given arc length of the critical non-torque transmitting arc and engagement status, can be obtained experimentally. In order to do this, a test transmission belt that can flex without breaking and for which the tension increases as the test transmission belt flexes more for all transmission ratios where transition flexing occur can be used. The test transmission belt(s) should be used to couple a cone/cone assembly or a pair or more of cones/cone assemblies mounted on the output shaft of a “Test CVT” with transmission pulley(s) mounted on the input shaft of that “Test CVT”; here each cone/cone assembly should be coupled by a test transmission belt to transmission pulley. Then using the “Test CVT” the following test procedures can be performed: while the “Test CVT” is running at a preferably very low speed and a preferably very low or if possibly zero brake torque at the output shaft, first the “Test CVT” is placed at its lowest transmission ratio then the transmission ratio is increased to its highest transmission ratio in small increments. For each transmission ratio, while no transmission ratios changing operation occur, it is observed using sensors that measure the torque transmitted by the input shaft, visually, or using other methods at which transmission ratios where no adjustment (rotational adjustment) to reduce/eliminate transition flexing is required. Here for transmission ratios where no or very little adjustment to reduce/eliminate transition flexing is required, the torque transmitted by the input shaft is very low since the brake torque at the output shaft is very low; but for transmission ratios where significant amount of adjustment to reduce/eliminate transition flexing is required, the torque transmitted by the input shaft should be considerably larger since the input shaft needs to flex the test transmission belt. This fact can be used to estimate the transmission ratios where no adjustment to reduce/eliminate transition flexing is required. Since the transmission ratio is increased in increments, the estimation of the transmission ratios where no adjustment to reduce/eliminate transition flexing is required might not be accurate. The accuracy of an estimated transmission ratio where no adjustment to reduce/eliminate transition flexing is required can be increased by further experimentation, such as by increasing and decreasing an estimated transmission ratio where no adjustment to reduce/eliminate transition flexing is required by smaller increments and observing using sensors that measure the torque transmitted by the input shaft, visually, or using other methods at which transmission ratio the best engagement between the test transmission belt(s) and its/their cone/cone assembly or cones/cone assemblies occur. The fact that the torque transmitted by the input shaft gets lower as the engagement between the test transmission belt and its cone or cone assembly gets better can be used here. From previous portions of this disclosure, it is known that the amount of adjustment required (if provided so that the rotational adjustment is only provided in the direction of rotation where the amount of adjustment required increases linearly as the transmission ratio is increased from a transmission ratio where no adjustment is required to the next transmission ratio where no adjustment is required) increases linearly as the transmission ratio is increased from a transmission ratio where no adjustment is required to the next transmission ratio where no adjustment is required, as depicted by the graph shown in
Somebody skilled in the art should be able to construct a CVT 1 or a CVT 2 using the items described in this section based on the description of this disclosure. If the items described in this section are used to construct a CVT 2, then the same basic configuration used for a CVT 2 using a front sliding tooth cone assembly 420A and a back sliding tooth cone assembly 420B, as described in the Alternate CVT's section and shown in
If the configuration shown in
Obviously the engagement statuses for the cone assemblies, as discussed in the Adjuster System for CVT 2 section, can be modified so that they can be used for single tooth cones, such as, 1) single tooth cone A engaged and single tooth cone B not engaged, 2) single tooth cone A engaged and single tooth cone B almost engaged, 3) single tooth cone A engaged and single tooth cone B engaged, 4) single tooth cone A almost not engaged and single tooth cone B engaged, 5) single tooth cone A not engaged and single tooth cone B engaged, 6) single tooth cone A almost engaged and single tooth cone B engaged, 7) single tooth cone A engaged and single tooth cone B engaged, 8) single tooth cone A engaged and single tooth cone B almost not engaged. Also somebody skilled in the art should be able to apply the methods described in this disclosure, such as the engagement statuses, to other CVT's 1 and CVT's 2.
In order to maintain the axial position of a transmission belt or a chain of a CVT where the cones move axially and the transmission belts are stationary, guides for moving cones 900, which is shown as a front-view in
In order to maintain the axial position of a transmission belt or a chain of a CVT where the cones are stationary and the transmission belts move axially, guides for stationary cones 920, which is shown as an end-view in
Also if desired the movements of the guiding plates for guides for moving cones 900 and guides for stationary cones 920 can be controlled by connecting their connector bars to their mover frame used to control the transmission ratio. For the guiding plates for guides for moving cones 900, the connector bar should be connected to its mover frame in manner such that it is axially maintained stationary relative to its mover frame but is allowed to slide vertically relative to its mover frame. Here a similar set-up used to control the position of the tensioning sliders described in the Sliding Cone Mounting Configuration section can be used. For the guiding plates for guides for stationary cones 920, the connector bar should be connected to its mover frame in a manner such that its moves axially with its mover frame but is allowed to slide vertically relative to its mover frame. Here a similar set-up used to control the position of the tensioning wheels described in the Continuous Variable Transmission Variation 2 (CVT 2) section can be used.
The guides for moving cones 900 can be used to maintain the axial alignment of a transmission belt for all CVT's where the change in transmission ratio is achieved by moving the cones. And guides for stationary cones 920 can be used to maintain the axial alignment of a transmission belt for all CVT's where the change in transmission ratio is achieved by moving the transmission belt.
An example on how to use guides for moving cones 900 is shown in
The most recommended configuration of the invention based on optimal performance is the configuration for CVT 2.4. The recommended cone assemblies and associated parts used to construct the CVT 2.4, are the front pin belt cone assembly 520A, the back pin belt cone assembly 520B, and their associated parts as described in the Alternate CVT's section of this disclosure.
The configuration for this CVT allows the use of positive engagement devices that can theoretically engage perfectly due to the compensation for transition flexing. In addition, the transmission ratio can virtually, although maybe not actually, be changed at any instances due to the compensation of transmission ratio change rotation. Also the usage of two adjusters for CVT 2.4 minimizes the torque requirement of the adjusters by allowing the usage of the over adjustment method to compensate for transmission ratio change rotation, and by allowing the compensation for transition flexing by providing adjustments in the direction opposite of the direction the shaft on which the adjusters are mounted is rotating.
It is also recommended to use a configuration where the shaft on which the transmission pulleys, referred to as twin sprocket pulleys in the Alternate CVT's section, are mounted is the input shaft. Since one method to prevent damage to the CVT if improper engagement occurs is by having the means for conveying rotational energy on the input shaft mounted on friction clutches; and for CVT 2.4, it is easier to mount the transmission pulleys on friction clutches than the cone assemblies. Care should be taken to mount any applicable sensors in a manner such that slippage of the friction clutches will not affect the accuracy of any sensors.
Also, for the configuration where the shaft on which the transmission pulleys are mounted is the input shaft, the cone assemblies start engagement on the slack side of the transmission belts; here the tensioner pulley assemblies, used to maintain tension in the transmission belts, can provide some relief in instances where improper engagement occur. For optimum performance it should be ensured that the tensioner pulley assemblies can provide sufficient relief for all transmission ratios. And the stiffness or weight of the tensioner pulley assemblies should be selected such they only provide relief in instances where improper engagement occur. It also needs to be ensured that the relief provided by the tensioner pulley assemblies will not affect the accuracy of any sensors of the CVT.
Also a vertical linear positional sensor can be mounted on each tensioning pulley, which is a pulley or pulley assembly of a tensioner pulley assembly; and a relationship between the correct vertical position of each tensioning pulley and the transmission ratio, for each transmission ratio, which can be obtained experimentally, can be programmed into the controlling computer. The linear positional sensors can be used to alarm the controlling computer when improper engagement occurs.
The linear positional sensors can also be used to provide feedback for controlling the adjuster(s) when they are used to correct for improper engagement, in the same manner as the torque sensors are used to provide feedback in the “tension measurement engagement correction” method. Here in order to correct for improper engagement, the adjuster(s) try to provide adjustments that move the tensioning pulley that is incorrectly positioned back to its correct vertical position, or move the tensioning pulleys that are incorrectly positioned back to their correct vertical position. In order to do this, the controlling computer first guesses the proper rotation of the adjuster(s). Here if the incorrectly positioned tensioning pulley(s) moves towards its correct vertical position then the controlling computer assumes that it has rotated the adjuster(s) in the correct direction and continuous to rotate the adjuster(s) in that direction until the incorrectly positioned tensioning pulley(s) is positioned back at its correct vertical position. And if the incorrectly positioned tensioning pulley(s) moves away from its correct vertical position then the controlling computer assumes that it has rotated the adjuster(s) in the incorrect direction and start rotating the adjuster(s) in the opposite direction.
Safety precautions in case deviations are encountered can also be used. If for example the incorrectly positioned tensioning pulley moves towards its correct vertical position then before the incorrectly positioned tensioning pulley is positioned at its correct vertical position, the incorrectly positioned tensioning pulley suddenly moves away from its correct vertical position; then here as a safety precaution, the rotating adjuster might be stopped, rotated in the opposite direction and stopped if the incorrectly positioned tensioning pulley still moves away from its correct vertical position, rotated in the opposite direction and if this doesn't move the incorrectly positioned tensioning pulley to its correct vertical position reverse direction again, and so forth. The most practical safety precautions and corrections for this method and other methods described in this disclosure can probably be obtained experimentally, since unforeseeable errors might occur due to the unique interaction of the components for each system, where each system has its own inherent flaws. Also when a deviation from expected operations is encountered, it is recommended that the type of deviation encountered is recorded in a retrievable memory device and a warning is sent to the operator of the device that utilizes the CVT.
In order to use the linear positional sensors as feedback for controlling the adjuster(s) to correct for improper engagement, proper tooth shapes need to be used, such as the tooth shapes described in the “tension measurement engagement correction” method for example.
If the shaft on which the transmission pulleys are mounted is the output shaft, then the cone assemblies start engagement on the tense side of the transmission belts. Here, if desired safety tensioners, which are located on the tense side of the transmission belts in the same manner as the tensioner pulley assemblies are located on the slack side of the transmission belts, can be used. The safety tensioners can be used to provide relief and feedback for correction in instances where improper engagement occur, in the same manner as the tensioner pulley assemblies. For optimum performance it should be ensured that like the tensioner pulley assemblies, the safety tensioners can provide sufficient relief for all transmission ratios. The safety tensioners should be designed such that they are fully extended as to apply no tensioning load on the transmission belts when no torque is transmitted by the CVT. In addition, the safety tensioners should be stiff enough so that the tension in the transmission belts under maximum operational load will not affect the position of the pulleys mounted on the safety tensioners so that the safety tensioners only provide relief in instances where improper engagement occur. It also needs to be ensured that relief of the tensioner pulley assemblies will not affect the accuracy of any sensors of the CVT.
However other configurations for a CVT described in this disclosure have some merit as well. For example, for a configuration for a CVT 3, which uses a cone assembly with two friction torque transmitting members 1046F that is coupled by a friction belt 1067F to a friction pulley 1098F, there is no need for an adjuster to compensate for transition flexing and if some instances where the transmission ratio can not be changed is acceptable, than no adjusters are needed. If no adjusters are needed then no controlling computer, sensors, and source of electrical power are needed.
The most suitable configuration of a CVT for a given application depends mainly on the following requirements: torque transmission efficiency and rating, transmission ratio changing responsiveness, endurance, simplicity, weight, cost, and electrical power availability. For example, for an automobile, torque transmission efficiency and rating, transmission ratio changing responsiveness, and reliability is important. And since electrical power is readily available in an automobile, the configuration for CVT 2.4 as described in this section might be ideal here. If increased reliability is desired than torque sensors or other items described in this disclosure can be added to that CVT 2.4. However this will increase the cost of the CVT. For a bicycle on the other hand torque transmission efficiency and rating, and transmission ratio changing responsiveness might not be so important. While weight and no need for an electrical power source is critical. Hence for a bicycle, the configuration for CVT 3 as described in this section might be ideal.
In order to design a CVT using the methods described in this disclosure, it is recommended that the designer first determines the unadjusted configuration of the CVT, which is the configuration of the CVT that does not use any adjusters. Next, if desired or required, the designer adds adjusters to the unadjusted configuration of the CVT based on the performance requirement of the CVT.
In order to determine the unadjusted configuration of the CVT, the designer first determines the desired qualities of the CVT the designer wants to build. From there the designer can construct a CVT using one or several cone assemblies 1026 or 1026 (A/B/C) according to the designer's need, by mounting one or several cone assemblies 1026 or 1026 (A/B/C) to a first shaft, or first group of shafts, and coupling them, directly or by the use of a rotational energy conveying device such as a transmission belt or chain, with one or several rotational energy conveying devices, including but not limited to pulleys, other cone assemblies, or sprockets, mounted on a second shaft, or second group of shafts, in a manner such that for all axial positions of the torque transmitting arc(s) at least a portion of a torque transmitting arc, formed by the torque transmitting surfaces of torque transmitting member(s) 46, of at least one cone assembly 1026 or 1026 (A/B/C) mounted on the first shaft, or first group of shafts, is always coupled to a torque transmitting surface of a rotational energy conveying device mounted on the second shaft, or second group of shafts. Also, the designer needs to ensure that changing the axial position of the torque transmitting member(s) relative to their cone 1024 or cone 1024A changes the transmission ratio of the CVT.
In addition, the designer also needs to ensure that for the CVT that the designer has designed, for every transmission ratio of the CVT, an instance exist where the transmission ratio can be changed without any significant circumferential sliding between the torque transmitting surfaces of the torque transmitting member(s) 46 and the torque transmitting surfaces(s) of the rotational energy conveying device(s) engaged with them. This can easily be done through experimentation.
Next, in order to be able to change the transmission ratio, the designer adds a mechanism controlled by an actuator or manually that can change the axial position of the torque transmitting member(s) 1046 and the rotational energy conveying device(s) directly or indirectly engaged to them relative to the surface of the cones 1024 or cones 1024A when their axial positions can be changed without causing any significant circumferential sliding between the torque transmitting surfaces of the torque transmitting member(s) and the torque transmitting surfaces(s) of the rotational energy conveying device(s) engaged with them. If required or desired a computer can be used to control the actuator to perform the relative axial position change specified in the previous sentence as specified in the previous sentences. Otherwise stalling of the actuator or slippage at the actuator can be used to ensure that the relative axial position change specified in this paragraph is performed as specified.
Next the designer designates the input shaft of the CVT, which is the shaft that will be coupled to the driving source; and the output shaft of the CVT, which is the shaft that will be coupled to the member to be driven. The first shaft, or a shaft from the first group of shafts, can be selected as the input shaft; and the second shaft, or a shaft from the second group of shafts, can be selected as the output shaft. The input and output shafts can be reversed if necessary.
Once the unadjusted configuration of the CVT has been determined, one or several adjusters can be added to increase the performance of that CVT. The adjuster system described in this disclosure can also be used to improve the performance of other CVT's that are not described in this disclosure that also suffer from either or both transition flexing and a limited duration at which the transmission ratio can be changed.
In order to use an adjuster system described in this disclosure to improve the performance of a CVT that suffers from either or both transition flexing and a limited duration at which the transmission ratio can be changed, the designer uses one or several adjusters, which can adjust the rotational position of a torque transmitting device, such as a torque transmitting member of a cone assembly, a transmission pulley, a cone assembly, etc., relative to another torque transmitting device. The adjuster(s) should be mounted so that transition flexing can be eliminated and/or so that the duration at which the transmission ratio can be changed can be substantially increased.
In order to eliminate transition flexing, the amount of adjusters needed depend on the configuration of the CVT. One method of eliminating transition flexing is to adjust the rotational position of the alternating torque transmitting device(s) that causes transition flexing. Here an alternating torque transmitting device is a device that alternates between transmitting torque and not transmitting torque. For CVT 1, the alternating torque transmitting devices are the torque transmitting members. And for CVT 2, the alternating torque transmitting devices are the cone assemblies and the transmission pulleys, since they alternately transmit torque to/from a shaft from/to a transmission belt. Each alternating torque transmitting devices is coupled to a common torque transmitting device, which is a torque transmitting device that transmits torque to/receives torque from at least two alternating torque transmitting devices. For CVT 1, the common torque transmitting devices are the transmission belt, the input shaft, and the output shaft. And for CVT 2, the common torque transmitting devices are the input shaft and the output shaft.
Another method to eliminate transition flexing is to adjust the rotational position of the common torque transmitting devices. For example, for a CVT that comprises of a cone assembly with one torque transmitting member that is sandwiched by two gears, which are coupled to a common output shaft and alternately transmit torque from the torque transmitting member of the cone assembly, transition flexing can be eliminated by adjusting the rotational position of the cone assembly. The rotational position of the cone assembly should only be adjusted when the torque transmitting member of the cone assembly is only engaged with one gear. Also, for this configuration, the adjusting rotation at the cone assembly also affects the rotation of the gear with which it is engaged, unless there are instances where there is no torque being transmitted between the gears and the cone assembly. Hence, here it might be better to adjust the rotational position of a gear before it is coupled to the common output shaft.
When adjusters are used to adjust the rotational position of the alternating torque transmitting devices, then in most cases the following method can be used to determine how many adjuster are needed for a common torque transmitting device and how to mount them. When for a common torque transmitting device two alternating torque transmitting devices, which are coupled to each other, are used to transmit torque, then only one adjuster, which can be used on any of the alternating torque transmitting devices, is needed.
When more than two torque transmitting members are used, then the amount of adjusters needed depend on the configuration of the CVT. When for a rotational position two alternating torque transmitting devices can simultaneously be transmitting torque to/receiving torque from their common torque transmitting device, than one of those torque transmitting devices need to be mounted on an adjuster, so that its rotational position can be adjusted relative to the rotational position of the other alternating torque transmitting device. And when for a rotational position three alternating torque transmitting devices can simultaneously be transmitting torque to/receiving torque from their common torque transmitting device, than most likely two of those alternating torque transmitting devices need to be mounted on an adjuster, so that the rotational position of those two alternating torque transmitting devices can be adjusted relative to the rotational position of the non-adjuster mounted alternating torque transmitting device. So basically, if for a rotational position, n number of alternating torque transmitting devices can be simultaneously transmitting torque to/receiving torque from their common torque transmitting device, than most likely n−1 of those alternating torque transmitting devices need to be mounted on an adjuster. For all other rotational positions, the same rule applies. By determining all the different configurations of how the alternating torque transmitting devices can transmit torque to/receive torque from their common torque transmitting device and how many common torque transmitting devices are used, the amount of adjusters needed and how to mount them can be determined. Here for each common torque transmitting device, most likely the configuration obtained consist of groups of adjuster mounted alternating torque transmitting devices, preferably the same amount of adjuster mounted alternating torque transmitting devices in each group, that alternate with non-adjuster mounted torque transmitting devices to form a sequential and continuous torque transmitting means where at any instance only one non-adjuster mounted torque transmitting devices is transmitting torque.
Furthermore, in most cases the amount of adjusters needed determined from the method described in the previous paragraph can be reduced by coupling the alternating torque transmitting devices, which need to be mounted on adjusters but are never simultaneously engaged to a common torque transmitting device, to a common adjuster. The common adjuster can then be used to adjust the rotational position of the alternating torque transmitting device about to be engaged or engaged. Also here the common adjuster needs to be able to adjust the rotational position of the alternating torque transmitting device about to be engaged before it becomes engaged. For configuration where an instance exist where an alternating torque transmitting device coupled to a common adjuster is engaged while another alternating torque transmitting device coupled to the same common adjuster is about to come into engagement, the time available for the common adjuster to provide the adjustment can be very short so that an adjuster fast enough is needed. This time can be increased by using more adjusters, which can be common adjusters or otherwise.
And when adjusters are used to adjust the rotational position of the common torque transmitting device(s), then in most cases the rotational position of the common torque transmitting device(s) need to be adjustable. This can be achieved by using an adjuster for each common torque transmitting device. For certain configurations this can also be achieved by using one adjuster to adjust the rotational position of one or several common torque transmitting devices. A possible scenario for this method is having an adjuster adjust the rotational position of a shaft on which one or several common torque transmitting device(s) are mounted. In this case, in instances where the rotational position of a common torque transmitting device is being adjusted, it should not be engaged with any alternating torque transmitting device. Since here there might be instances where no torque is transmitted between a common torque transmitting devices and an alternating torque transmitting device, it is recommended to adjust the rotational position of the alternating torque transmitting device(s) instead.
Furthermore, adjusters can also be used to substantially increase the duration at which the transmission ratio of a CVT can be changed. One method to achieve this is to use an adjuster to mount each cone assembly to its shaft/spline. If the transmission ratio needs to be changed, these adjusters can then be used to rotate the cone assemblies relative to their shaft such that are maintained in a moveable configuration. This method is used for CVT 1.1 described earlier.
In a configuration of a CVT where a complete non-torque transmitting arc, which is the space of a cone assembly that is not covered by a torque transmitting member, is never completely covered by its coupled torque transmitting device, then the duration at which the transmission ratio can be changed can be substantially increased by compensating for transmission ratio change rotation. This method is used in CVT 2.1. In order to compensate for transmission ratio change rotation, the rotation of the alternating torque transmitting device(s), for which changes in transmission ratio causes them to rotate differently than a referenced alternating torque transmitting device, need to be adjusted using adjuster(s). The adjustement should aim to eliminate any difference in rotation of the alternating torque transmitting devices due to change in transmission ratio. Or the rotation of the alternating torque transmitting devices engaged or coupled to the alternating torque transmitting devices mentioned in the previous sentence need to be adjusted in the same manner.
In order to determine the transmission ratio change rotation of an alternating torque transmitting device, first all other alternating torque transmitting devices should be removed from the CVT while the rest of the CVT should be left alone. Next the CVT should be placed in either its highest or lowest transmission ratio. Then the alternating torque transmitting device, for which its transmission ratio change rotation needs to be determined, should be positioned so that it can transmit torque at a recorded initial rotational position. Next the transmission ratio should be changed while the rotation of that alternating torque transmitting member as the transmission ratio is changed is recorded. The recorded results provide the amount of transmission ratio change rotation for that initial rotational position. Using the same method the amount of transmission ratio change rotation for different initial rotational positions can be determined. From the collected data an equation that estimates the amount of transmission ratio change rotation for different initial rotational positions and different initial and final transmission ratios can be constructed. Mathematics can also be used to obtain such equation. An example on how to obtain such equation mathematically can be found in the Adjuster System for CVT 2 section and the CVT 2.2 section of this disclosure. Based on those examples, it should not be difficult for someone with a mathematics background to obtain such equation for different configurations of CVT's.
When the transmission ratio change rotation of each alternating torque transmitting device is different, then the method to determine the amount of adjusters needed and the basic configuration on how to mount them is identical to the method used in the case where adjusters are used to adjust the rotational position of the alternating torque transmitting devices in eliminating transition flexing.
In order to properly control the adjusters to compensate for transmission ratio change rotation the following methods can be used. The first method is by controlling the adjusters so that the differences in torque being transmitted by the alternating torque transmitting devices that are transmitting torque are within a predetermined range. In that predetermined range, the difference in torque being transmitted by the torque transmitting devices due to transmission ratio change rotation can be compensated by flexing of the torque transmitting devices used to transmit torque and no damaging stresses in the parts of the CVT occur. And when the differences in torque being transmitted exceed the predetermined range, stalling of the transmission ratio changing actuator should occur. If this method is used, then each alternating torque transmitting device need to have a device that measures the torque being transmitted by it, such as a torque sensor or load cell for example. Another method to compensate for transmission ratio change rotation is to determine the equations that estimates transmission ratio change rotation for each alternating torque transmitting device, and then control the adjusters based on those equations to compensate for the difference(s) in transmission ratio change rotation between the alternating torque transmitting devices. One method of adjustment is by having referenced alternating torque transmitting devices, which rotations are not adjusted, and adjusted alternating torque transmitting devices, which rotations are adjusted. The amount of adjustment rotation for an adjusted alternating torque transmitting devices is calculated by subtracting the amount of transmission ratio change rotation of that adjusted alternating torque transmitting device from the amount of transmission ratio change rotation of its referenced alternating torque transmitting device. Although not absolutely necessary, it is preferred that counter-clockwise rotations are considered positive and clockwise rotations are considered negative. Since the torque transmitting devices are rotating, the amount of adjustments required continuously change. Hence the value for the amount of adjustments needed should be updated at short enough intervals so that the amount of adjustments provided are accurate enough to prevent excessive stalling of transmission ratio changing actuator. An example on how to use this method is discussed in the explanation for CVT 2.2. Furthermore, in case every alternating torque transmitting device is mounted on an adjuster, another method of adjustment is to cancel out transmission ratio change rotation for each alternating torque transmitting device by having the adjusters provide their alternating torque transmitting devices an equal amount of rotation as their transmission ratio change rotation but directed in the reverse direction.
Also in order to determine the proper direction of rotation in order to compensate for transmission ratio change rotation and the adjuster that is providing a releasing torque when the over adjustment method is used to compensate for transmission ratio change rotation, the following trial and error experimentation method can be used. In order to conduct the experiment, the input shaft of a CVT 2.3, which partially comprises of torque transmitting member 1, torque transmitting member 2, transmission pulley 1, and transmission pulley 2, is connected to a very slowly rotating source of rotation such as an engine or motor for example; and the output shaft of the CVT is connected to a friction clutch, which friction is large enough such that there is an observable distinction between a releasing torque and a pulling torque that needs to be provided by an adjuster. It needs to be ensured that the transmission ratio changing actuator will stall or slip when insufficient or improper adjustments is provided by the active adjuster. And it also needs to be ensured that the operating speeds of the adjusters are larger than required in order to compensate for transmission ratio change rotation during all instances of the experiment. In addition, the torque of the adjusters should be large enough as to be able to provide pulling torque, but limited such that the adjusters cannot cause damaging stresses in the parts of the CVT. Next for all the different rotational positions and transmission ratio changes (increasing/decreasing), which are Decreasing Pitch Diameter and Torque Transmitting Member 1 on Upper Half, Decreasing Pitch Diameter and Torque Transmitting 1 on Lower Half, Increasing Pitch Diameter and Torque Transmitting 1 on Upper Half, and Increasing Pitch Diameter and Torque Transmitting Member 1 on Lower Half, the experimentations described in the remainder of this paragraph are performed. First, the adjuster for transmission pulley 1 is rotated clockwise, if this allows transmission ratio change, then for that rotational position and for that transmission ratio change (increasing/decreasing) the correct rotation of the adjuster for transmission pulley 1 is clockwise. If this does not allow transmission ratio change, then the adjuster for transmission pulley 1 is rotated counter-clockwise; since the clockwise rotation of the adjuster did not allow transmission ratio change, this should allow transmission ratio change, so that for that rotational position and for that transmission ratio change (increasing/decreasing) the correct rotation of the adjuster for transmission pulley 1 is counter-clockwise. The amount of torque required by the adjuster for transmission pulley 1 as to allow transmission ratio change should be obtained from the torque sensor for that adjuster. Next, the adjuster for transmission pulley 2 is rotated clockwise, if this allows transmission ratio change, then for that rotational position and for that transmission ratio change (increasing/decreasing) the correct rotation of the adjuster for transmission pulley 2 is clockwise. If this does not allow transmission ratio change, then the adjuster for transmission pulley 2 is rotated counter-clockwise; since the clockwise rotation of the adjuster did not allow transmission ratio change, this should allow transmission ratio change, so that for that rotational position and for that transmission ratio change (increasing/decreasing) the correct rotation of the adjuster for transmission pulley 2 is counter-clockwise. The amount of torque required by the adjuster for transmission pulley 2 as to allow transmission ratio change should be obtained from the torque sensor for that adjuster. By comparing the amount of torque required by the adjuster for transmission pulley 1 as to allow transmission ratio change with the amount of torque required by the adjuster for transmission pulley 2 as to allow transmission ratio change for that rotational position and for that transmission ratio change (increasing/decreasing), it can be determined which adjuster needs to provide a releasing torque and which adjuster needs to provide a pulling torque for that rotational position and for that transmission ratio change (increasing/decreasing). Here the adjuster that needs to provide less torque to allow transmission ratio change is the adjuster that needs to provide a releasing torque, while the other adjuster is the adjuster that needs to provide a pulling torque.
Furthermore, as discussed in detail in the Adjuster System for CVT 2 section, it is preferred that an adjuster only needs to rotate in the direction that requires a releasing torque. If the shaft/spline on which an adjuster is mounted is the input shaft, than the direction that only requires a releasing torque is the direction opposite from the rotation of the input shaft. If the shaft/spline on which an adjuster is mounted is the output shaft, than the direction that requires only a releasing torque is the direction of rotation of the output shaft. A configuration where an adjuster is only required to provide a releasing torque can be achieved by using an adjuster on each alternating torque transmitting device. This method is described in the CVT 2.3 section and the CVT 2.4 section of this disclosure. And for a CVT that consist of a cone assembly with one torque transmitting member that is sandwiched by two gears, here each gear need to have an adjuster that can adjust its rotational position relative to the rotational position of its shaft, which is coupled to the shaft of the other gear. Besides using an adjuster on each alternating torque transmitting member, another method to having an adjuster compensate for transmission ratio change rotation by only providing a releasing torque can be achieved by using a differential between each alternating torque transmitting device and have an adjuster control the rotational position of one differential shaft relative to the other. Examples of this method are described in the Differential Adjuster Shaft for CVT 2 section of this disclosure. And for a CVT that consist of a cone assembly with one torque transmitting member that is sandwiched by two gears, each gear needs to be coupled to a differential shaft of a differential, while the input/output shaft is coupled to the housing of the differential.
Once the proper configuration for the adjuster utilizing CVT has been determined, the designer needs to determine what kind of adjuster the designer wants to or can use. The most versatile adjuster is the electrical adjuster, which can be used to eliminate transition flexing, maintain a cone assembly in a moveable configuration, and compensate for transmission ratio change rotation in almost all applications. However, in order to properly control an electrical adjuster, the designer needs to use a computer and various sensors, such as transmission ratio sensors, rotational position sensors, relative rotational position sensors, torque sensors, etc. The methods of utilizing the sensors and the methods for controlling an electrical adjuster are described in detail in the previous sections of this disclosure.
Another, less versatile, adjuster that might be useful for some CVT's is the mechanical adjuster. This adjuster can only be used to eliminate transition flexing. For the mechanical adjuster, it is not absolutely necessary, although it might be beneficial, to use a computer and various sensors in order to control it. Hence this adjuster might be preferred in machines where electrical power is not available, such as bikes for example.
Another adjuster that can be used, is the spring-loaded adjuster. This adjuster can be used to eliminate transition flexing and allow some relative rotation that slightly increase the moveable duration of a CVT. This adjuster is the simplest and most likely cheapest of the adjusters described in this disclosure. However, for this adjuster, shock loads occur when the pins of its gap mounted torque transmitting member hit a surface of the cone assembly that forms that gap. These shock loads might be negligible in low torque applications. But in high torque applications, unless properly damped, these shock loads can significantly decrease the live of the CVT and can cause undesirable driving conditions. However, damping these shock loads can also significantly reduce the efficiency of the CVT.
Based on the description in this disclosure, a machine designer can determine how to properly mount adjusters so that transition flexing can be eliminated and/or so that the duration at which the transmission ratio can be changed can be substantially increased in CVT's suffering from these problems.
Accordingly the reader will see that the cone assemblies and adjuster systems of this disclosure can be used to construct various Continuous Variable Transmissions (CVT's), which have the following advantages over existing Variable Transmissions:
Although the description above contains many specificities, these should not be construed as limiting the scope of the invention but as merely providing illustrations of some of the presently preferred embodiments of this invention. For example, by using a gear cone assembly, which is identical to a cone assembly 1026 described in the General Cone section, except for having a torque transmitting member with a square shaped cross-section instead of a channel shaped one, such that it can be coupled to a gear, one or several gear cone assemblies on a driver shaft can be coupled to one or several gears on one or several driven shafts and vice-versa. For example, if the arc length of the torque transmitting member at the largest end of its gear cone assembly is not less than half of the circumference of that gear cone assembly, than a CVT can be constructed where two gears, which are attached so that they can engage with the teeth of the torque transmitting member, are positioned as to sandwich that gear cone assembly. Also a CVT, which consist of several gear cone assemblies, which engage directly with each other can also be designed.
Also the designs in this disclosure are only exemplification on how to utilize the invention. Many other designs utilizing this invention, such as designs that use other types/designs of pulleys, sprockets, belts, chains, teeth, or any other part of this invention can be conceived.
Also, although in this disclosure only cones or cone assemblies with one or two oppositely positioned torque transmitting devices are shown. Cones or cone assemblies with more than one or two torque transmitting devices can also be used as long as for the CVT where they are used, an instance exist where only one torque transmitting device is engaged with it means for coupling. For example, a CVT 3 using a cone or cone assembly with three teeth, evenly spaced on its cone or cone assembly, can be constructed as long an instance where only tooth is engaged with its chain or belt exist. Or a CVT 2 with three single tooth cones or three cone assemblies with one tooth that are mounted on a shaft in a manner such that the teeth are 120 degrees from each other can also be constructed as long an instance where only one tooth is engaged with its chain or belt exist. Obviously more teeth can be used as long as an instance where only one tooth is engaged with its chain or belt exists. In the same manner a CVT 3 using a cone assembly with three torque transmitting members or a CVT 2 using three cone assemblies, each with a torque transmitting member, can be constructed.
Given the time and need, detailed designs for the configurations mentioned, as well as many other configurations could be conceived.
Furthermore, besides improving the performance of CVT's utilizing the cones and cone assemblies described in this disclosure, the adjuster systems described in this disclosure can also be used to improve the performance of other CVT's that suffer from either or both transition flexing and/or a limited duration at which the transmission ratio can be changed. First of all, they can eliminate or significantly reduce transition flexing. Excessive cycles of transition flexing can reduce the life of a CVT. Furthermore, the adjuster systems of this invention can also be used so that the duration at which the transmission ratio can be changed can be substantially increased so as to improve the transmission ratio changing responsiveness of a CVT. In addition, the adjuster systems of this invention can also improve the engagement between a means for transmitting torque, such as a pulley, sprocket, or gear for example, and another a means for transmitting torque, such as a belt, chain, or another gear for example, by compensating for tooth wear for example.
The methods for improving the performance of CVT's described in this disclosure can also be used with other CVT's that instead of using cone assemblies or cones, use pulleys, push-belt pulleys, gears, or other torque transmission devices for which utilizing the described methods will increase perform of the CVT's. Other type of sensors, other type of adjusters, other type of cones or cone assemblies, other type of belts or chains, or alternates for any other parts used in the designs described in this disclosure that have the same or similar functions, can also be used.
It is believed that sufficient information and explanation has been provided for somebody skilled in the art to make use of the invention. If there are items that are not described or described incorrectly, most likely due to time limitations in preparing the disclosure, somebody skilled in the art should be able to use established scientific principles and/or experimentations to overcome the issues caused by this.
Regarding the terms used in the claims: the term means for conveying rotational energy or rotational energy conveying device refers to an item that is rotating and transmitting rotational energy; examples of a means for conveying rotational energy or rotational energy conveying device are a cone, a cone assembly, a gear, a sprocket, and a transmission pulley. The term means for coupling refers to an item that is used to couple one means for conveying rotational energy/rotational energy conveying device to another means for conveying rotational energy/rotational energy conveying device; examples of a means for coupling are a transmission belt, and a chain. The term critical non-torque transmitting arc length refers to the arc length of the critical non-torque transmitting arc.
Accordingly, the scope of the invention should be determined not by the embodiments illustrated, but by the appended claims and their legal equivalents.
This invention is a Continuation-in-part (CIP) of U.S. patent application Ser. No. 12/231,983, which was filed on Sep. 8, 2008.
Number | Date | Country | |
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Parent | 12231983 | Sep 2008 | US |
Child | 12459853 | US |