FIELD OF INVENTION
This invention relates to novel propulsion means for a watercraft using oscillating foils with ability to provide thrust in any direction.
BACKGROUND OF INVENTION
Oscillating fin propulsion has been used to produce efficient propulsion. This technology appears in U.S. Pat. No. 6,022,249, the text and drawings of which are expressly incorporated herein by reference, which discloses a self-propelled watercraft, such as a kayak, which typically include a hull with a keel, having propulsion means extending below the water line. The propulsion means comprises a pair of fins each having a leading edge and a trailing edge and adapted to oscillate through an arcuate path in a generally transverse direction with respect to the central longitudinal dimension of the watercraft. Foot operated pedals worked from the cockpit are operatively associated with the propulsion means for applying input force to the propulsion means. The propulsion means includes a pair of fins which twist to form an angle of attack for providing forward thrust with respect to the longitudinal dimension of the watercraft while moving in both directions along the arcuate path.
U.S. Pat. No. 9,359,052, the disclosure of which is expressly incorporated herein by reference, also discloses a self-propelled watercraft having propulsion means extending below the water line comprising a pair of flexible fins each rotatable on a substantially horizontal axis and each being adapted to oscillate through an arcuate path in a generally transverse direction with respect to the central longitudinal dimension of the watercraft. Input means are operatively associated with the pair of flexible fins for applying input force to oscillate the pair of flexible fins. An improvement is provided by means for positioning the pair of flexible fins to propel the watercraft forward and to rotate the pair of flexible fins 180° about separate axes which are each disposed at a substantially right angle to the horizontal axis to propel the watercraft aft. When input force is applied, the flexible fins can twist to form an angle of attack for providing forward or aft thrust with respect to the longitudinal dimension of the watercraft while moving the flexible fins in both directions along the arcuate path. However, it is not possible to provide thrust other than in forward or aft directions.
SUMMARY OF THE INVENTION
A propulsion mechanism adapted to be inserted in an opening in the bottom of a watercraft comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, and means operatively associated with said propulsion fins for applying input force whereby as input force is applied, said flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along said arcuate path.
A novel watercraft comprising a propulsion mechanism extending through an opening in the bottom of the watercraft, said propulsion mechanism comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, and means operatively associated with said propulsion fins for applying input force whereby as input force is applied, said flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along said arcuate path.
A propulsion mechanism adapted to be inserted in an opening in the bottom of a watercraft comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, and a pair of pedals operatively associated with said propulsion fins for applying input force whereby as input force is applied, said flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along said arcuate path.
A novel watercraft comprising a propulsion mechanism extending through an opening in the bottom of the watercraft, said propulsion mechanism comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, and a pair of pedals operatively associated with said propulsion fins for applying input force whereby as input force is applied, said flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along said arcuate path.
A propulsion mechanism adapted to be inserted in an opening in the bottom of a watercraft comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, the vertical axis being coupled to elements operable from within the watercraft to steer the watercraft in any direction while being pedaled, and a pair of pedals operatively associated with the propulsion fins for applying input force whereby as input force is applied, the flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along the arcuate path.
A novel watercraft comprising a propulsion mechanism extending through an opening in the bottom of the watercraft, said propulsion mechanism comprising a pair of flexible fins extending below the water line, said pair of flexible fins each adapted to oscillate through an arcuate path on a horizontal axis to propel the watercraft, said horizontal axis being continuously rotatable in either direction about a generally vertical axis to propel said watercraft in any direction, said vertical axis being coupled to elements operable from within the watercraft to steer the watercraft in any direction while being pedaled, and a pair of pedals operatively associated with the propulsion fins for applying input force whereby as input force is applied, the flexible fins can twist to form an angle of attack for providing thrust while moving in both directions along the arcuate path.
In another important aspect, this invention comprises a novel watercraft comprising a propulsion mechanism extending through an opening in the bottom of the watercraft. The propulsion mechanism is adapted to rotate about a generally vertical axis coupled to elements operable from within the watercraft to rotate the propulsion mechanism in any direction. The watercraft has locking means to prevent the propulsion mechanism from rotating. The locking means are adapted to disengage when the elements are operated. A pair of pedals are operatively associated with the propulsion mechanism for applying input force whereby as input force is applied thrust is produced.
A key feature of this invention's design is that the drive can produce thrust in any direction which adds to the maneuverability of the boat. In this invention, the fins are able to rotate as a pair around a single vertical axis. This means the lower section or “lower unit” of the drive comprising the fins is able to be rotated independently of the upper section or “upper unit” comprising the means for applying input force, preferably pedals, allowing the drive to thrust in any direction.
This invention dramatically increases the maneuverability of kayaks, allowing the drive to be used to propel and turn the boat. Optionally, by retaining the rudder, both the drive and the rudder can be used independently to maneuver the boat, further increasing the maneuverability. The lower unit can also be rotated 180 degrees into a reverse position, and then the user can thrust in reverse with the drive and steer with the rudder. The drive can, however, be used as the sole means of propulsion and steering on a watercraft.
The ability to rotate the drive to any direction through 360° is even more beneficial than reverse. It allows the watercraft to rotate about its own axis and move sideways through the water, hold in a location pointing any direction, and provides extremely precise and effective maneuverability.
Another feature of this invention is that an indicator can be placed on top of the device which shows the direction that the watercraft will be thrusted.
This invention uses a four cable transmission system with modifications to allow the rotation of the lower unit. All four cables are redirected to be grouped around and parallel to the vertical axis of the pivot that has been added to the drive. Each set of cables that transmit the force at the same time are located on opposite sides of the vertical axis. Each of the four cables are separated into two lengths of cable, with the break occurring halfway along the vertical length of cable. One set of upper cables is attached to a free-floating horizontal bearing ring. This ring interfaces with another free-floating horizontal bearing ring, with ball bearings between the two rings. This second ring is attached to the lower sections of cable. The second set of upper cables is attached to a smaller horizontal free-floating bearing ring. This ring interfaces with another small free-floating horizontal bearing ring, with ball bearings between flanges on the two rings. This second ring is attached to the lower sections of cable. This smaller horizontal bearing ring assembly is small enough to pass freely inside the larger bearing ring assembly. As input force is applied to the pedals the sections of cable move back and forth, the larger ring bearing moves up and down along the vertical axis. The smaller ring bearing assembly also travels up and down along the vertical axis, in an opposite direction to the larger bearing ring assembly. With each pedal stroke, the smaller ring assembly passes through the larger ring assembly.
These two ring bearing assemblies allow for the lower unit to rotate independently of the upper unit. As the lower unit is pivoted around the vertical axis, the lower bearing rings rotate with the lower cables and lower unit and the upper bearing rings and upper cables do not rotate. The ball bearings between each upper and lower bearing ring allow for free rotation even under high cable tension. The bearing ring assemblies are free to rotate a full 360° at any position along the vertical axis, and can be rotated when the drive is being pedaled or not being pedaled.
Another feature of this invention is the drive steering systems and clutch which allows for the user to control the position of the lower unit of the drive, and therefore the direction of thrust, by operating a steering handle located within arm's reach of the user. This handle rotates around a vertical axis, and the direction the handle is pointing correlates with the direction of thrust from the drive. This handle can be rotated infinitely in either direction. The clutch serves to keep the lower unit fixed while the drive is in use, but to allow the user to turn the lower unit with the handle. Force from the lower unit will not release the clutch. If the lower unit is over forced, as upon hitting a submerged object, there is a built in slip mechanism to allow all parts of the steering system to rotate, including the clutch. This is to avoid high load damaging the clutch or the steering system.
THE DRAWINGS
Turning to the drawings.
FIG. 1 is a top plan view of a preferred watercraft of this invention showing the upper side of the propulsion mechanism of this invention.
FIG. 2 is a perspective view from the upper rear right of the watercraft of FIG. 1.
FIG. 3 is similar to FIG. 2 with parts broken away showing the steering handle and connecting rod attached to the propulsion mechanism as well as the propulsion mechanism received in an opening at the bottom of the watercraft.
FIG. 4 is a side view showing the propulsion mechanism including the parts broken away to show pedal, pedal shaft and two rotatable drums, each carrying a mast bearing a fin, as well as the steering connecting rod.
FIG. 5 is similar to FIG. 3, showing more details of the propulsion mechanism with steering elements.
FIG. 6 is a plan view from the rear of the propulsion mechanism of this invention as it appears from the rear when steered in a bow forward position.
FIG. 7 is similar to FIG. 6 except that the pedals have been operated to cause the drums with fins to rotate, with the right pedal moved forward and the left pedal moved to the rear, thereby causing each of the fins to rotate 90°.
FIG. 8 is a side view of the propulsion mechanism where the pedals are in the position shown in FIG. 6.
FIG. 9 is a side view of the propulsion system where the pedals are in the position shown in FIG. 7.
FIG. 10 is a perspective view taken from the right rear showing the propulsion mechanism with the pedals in the position shown in FIG. 6.
FIG. 11 is similar to FIG. 10 with the pedals in the position shown in FIG. 7.
FIG. 12 is similar to FIG. 10 with additional parts broken away to show the cables and nested bearing ring assemblies.
FIG. 13 is similar to FIG. 11 with further parts broken away to show the larger outer and smaller inner bearing ring assemblies are separated to cause the drums carrying the fins to each rotate 90° as indicated by the arrows.
FIG. 14 is a side view of the propulsion mechanism shown in FIG. 12.
FIG. 15 is a side view of the propulsion mechanism as shown in FIG. 13.
FIG. 16 is similar to FIG. 14 with more parts broken away and added to show more detail.
FIG. 17 is similar to FIG. 15 with more parts broken away and added to show more detail.
FIG. 18 is a perspective view from the upper rear showing the parts shown in FIG. 16.
FIG. 19 is a perspective view from the upper rear showing the fins in the position shown in FIG. 17.
FIG. 20 is a schematic view of the two bearing ring assemblies and cables when the assemblies are nested.
FIG. 21 is a schematic view of the bearing ring assemblies and cables when the bearing ring assemblies have separated as shown by the arrows.
FIG. 22 is a schematic view showing by arrows the direction of rotation of the lower ring of each of the large outer and small inner bearing ring assemblies shown in FIG. 21.
FIG. 23 shows schematically the large outer and small inner bearing ring assemblies when nested with more detail of the attachment points of the cables.
FIG. 24 is a sectional view taken along line 24-24 in FIG. 23 showing the bearings.
FIG. 25 shows the large outer and small inner bearing ring assemblies when separated as indicated by the arrow with more detail of the attachment points of the cable.
FIG. 26 is a view from the upper right rear showing the propulsion mechanism with parts removed to expose the cable connections between the pedal cranks and the nested large and small bearing ring assembly, as well as the cable connections between the rotatable lower ring of each bearing ring assembly and the drums each with attached mast carrying a fin.
FIG. 27 is similar to FIG. 26 except that the pedal shafts have moved to cause the small inner bearing ring assembly to move down and the large outer bearing ring assembly to move up accompanied by the 90° rotation of each fin.
FIG. 28 is similar to FIG. 26, but taken from the lower right rear.
FIG. 29 is similar to FIG. 26, further showing cable connections.
FIG. 30 is an exploded view from the right rear showing the main steering gear ring and the geared fitment which connects to the compression tube shown in FIGS. 3 and 5.
FIG. 31 is similar to FIG. 30 showing the gear elements engaged.
FIG. 32 is a side view of the propulsion mechanism, with parts removed to show the pedal shaft and adjustment arm in a first engaged position.
FIG. 33 shows in side view the lifting of the adjustment arm to disengage and begin to change the position of the pedal shaft.
FIG. 34 shows in side view the pedal shaft and adjustment arm moved to a second position prior to engagement.
FIG. 35 shows in side view the pedal shaft and adjustment arm engaged in the second position.
FIG. 36 is a top plan view of the propulsion mechanism when steered in the straight ahead position as indicated by the arrow on the direction indicator to propel the watercraft forward.
FIG. 37 is another top plan view of the propulsion system steered to propel the watercraft to the left as indicated by the arrow on the direction indicator.
FIG. 38 is a top plan view of the propulsion system steered 90° to the left.
FIG. 39 is a side view from the rear of the propulsion system steered as shown in FIG. 36.
FIG. 40 is a side view from the rear of the propulsion system steered as shown in FIG. 37.
FIG. 41 is a side view from the rear of the propulsion system steered as shown in FIG. 38.
FIG. 42 is a side view of the propulsion system steered 90° to the left.
FIG. 43 is a top view of the propulsion system when steered to the right as shown on the direction indicator.
FIG. 44 is a side view of the propulsion system steered 90° to the right with the pedals moved as indicated by the arrows resulting in the movement of the fins about the horizontal shaft.
FIG. 45 is a top plan view of the propulsion system when steered to the rear to propel the watercraft aft.
FIG. 46 is a top plan view of the propulsion system with the pedals and fins positioned as shown to propel the watercraft aft.
FIG. 47 is a rear plan view of the propulsion system with the fins positioned as in FIG. 45.
FIG. 48 is a rear plan view of the propulsion system with the fins positioned as in FIG. 46.
FIG. 49 is a cutaway view of the propulsion mechanism showing the connection of the direction indicator to the propulsion mechanism.
FIG. 50 is another cutaway view of the propulsion mechanism showing the connection of the direction indicator to the propulsion mechanism.
FIG. 51 shows the toothed belt connecting the steering system to the clutch, the compression tube enclosing the belt being removed.
FIG. 52 is similar to FIG. 51 with parts removed at the steering system and the clutch.
FIG. 53 is an exploded view with parts broken away of the clutch system.
FIG. 54 is an exploded view of the steering mechanism with parts broken away.
FIG. 55 is a top view of the clutch mechanism in cross-sectional view at rest.
FIG. 56 is a top view, indicating by arrows the rotational force on the spur gear, which is attached to the drive, showing the spur gear as it rotates, rotating the trilobe.
FIG. 57 is a top view showing input force on the toothed drum, rotating the tines inside the clutch mechanism, pressing the roller bearings away from the clutch sleeve, releasing the clutch mechanism.
FIG. 58 is a top view showing the tines of the toothed drum pressing the roller bearings into the trilobe in turn rotating the drive.
FIG. 59 is an isometric view of the clutch mechanism at rest with a cutaway in the clutch sleeve to show more detail.
FIG. 60 is an isometric view showing the rotational force on the spur gear, showing the spur gear as it rotates, rotating the trilobe.
FIG. 61 shows input force on the toothed drum rotating the tines inside the clutch mechanism, pressing the roller bearings away from the clutch sleeve, releasing the clutch mechanism.
FIG. 62 shows the tires of the toothed drum pressing the roller bearings into the trilobe in turn rotating the drive.
FIG. 63 is a perspective view of the propulsion system of another embodiment of the invention taken from the right rear.
FIG. 64 is similar to FIG. 63 with additional parts broken away.
FIG. 65 is similar to FIG. 64 with still more parts broken away.
FIG. 66 is a side view with parts removed showing how the propulsion mechanism is supported in the well opening in the bottom of the watercraft.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows a preferred watercraft 10 having a hull 12, a bow 14, a cockpit 16 having a floor 18, a through well or opening 20 in which is received the propulsion mechanism 22 of this invention. The pedals 24 and 26, pedal shafts 28 and 30 and fins 32 and 34 all form part of propulsion mechanism 22. The pedals 18 and 20 are operatively connected to pedal shafts 26 and 28.
As shown in FIG. 4, the supporting structure for the propulsion mechanism is spine 21.
The drums 40 and 42 are rotated about a horizontal axis represented by shaft 45 in FIG. 4. As can be seen in FIGS. 7, 11, 13, 19, 27, 37, 38, 44, 46 and 48, the fins 32 and 34 oscillate on a horizontal axis through an arcuate path to propel the watercraft.
Turning to the invention in more detail, in FIG. 29 the large and small bearing ring assemblies are nested, the smaller bearing ring assembly 36 inside the larger bearing ring assembly 38. Referring to FIGS. 23 and 24, each bearing ring assembly has an upper and lower ring separated by a ring of ball bearings. In FIGS. 23 and 24 the two bearing ring assemblies are nested, one inside the other. As show in FIG. 24, the large bearing ring assembly 38 has an upper non-rotatable ring 44 and a lower rotatable ring 46. The lower ring 46 rotates with respect to the upper non-rotatable ring 44 on ball bearing ring 48. The smaller inner bearing ring assembly 36 also has an upper non-rotatable small ring 50 and a lower rotatable small ring 52. The lower ring 52 rotates on ball bearing ring 53.
Each rotatable ring 46, 52 carries two downwardly extending cables. Rotatable ring 46 carries cables 54 and 56. Rotatable ring 52 carries cables 58 and 60.
As shown in FIGS. 28 and 29, cable 54 runs to the front of drum 40. Cable 56 runs to the rear of drum 42. Likewise, cable 58 runs to the front of drum 42 and cable 60 runs to the rear of drum 40.
Non-rotatable small ring 50 carries two upwardly extending cables 68 and 70. Non-rotatable ring 44 also carries two upwardly extending cable 72 and 74.
As shown in FIG. 29 pedal shafts 28 and 30 rotate about a fixed shaft 76. Shaft 76 carries cable guide elements 78 and 80 which rotate with pedal shaft 28 about shaft 76. Guide elements 82 and 84 rotate with pedal shaft 30 about shaft 76 as shown in FIG. 28.
A pair of pulleys 86 and 88 are carried at the top of central vertical shaft 90. Each pulley supports two of the cables 68 and 72 passing over pulley 86 and cables 70 and 74 passing over pulley 88.
When pedal 24 is advanced cable 72 and large bearing ring assembly 38 is pulled up and cable 68 moves down with small bearing ring assembly 36.
The horizontal shaft 45 carries the drums 40 and 42 to which is joined masts 92 and 94, carrying fins 32 and 34. The horizontal shaft 45 is connected to central vertical shaft 90. The vertical shaft 90 projects upwardly and generally, although not necessarily, forms a substantially right angle to the longitudinal dimension of the watercraft.
The horizontal shaft 45 is continuously rotatable through 360° in either direction about vertical shaft 90.
In the preferred embodiment shown in FIGS. 30, 31, 35, 51 and 52, steering is performed by the occupant of the cockpit by operating handle 104 with steering rod 105 which is coupled to compression tube 106 containing toothed belt 120 through connection 108 to turn pinion gear 110. Pinion gear 110 engages ring or spur gear 112 which is carried by vertical shaft 90.
As shown in FIG. 29, each of the fins is rotatable about its mast, so that the edge of the fin opposite the leading edge can move from one side to the other with respect to the center line of drums 40 and 42. This action results in both fins exerting of forward force or push on the watercraft in both directions of movement of the fins, providing superior efficiency and speed. The extent of travel or movement of the trailing edges is limited by the adjustment provided by tensioners 62 and 64.
As shown in FIGS. 26 and 27, the rear pulley 96 carries cable 98 which runs from attachment 100 connected to pedal shaft 28 to attachment 102 connected to pedal shaft 30. When one pedal is advanced by the application of input force, the other is pulled back. In this way, one bearing assembly is pulled up, the other bearing assembly is pulled down as the pedal is advanced, and the other pedal is pulled back, thereby being made ready to be advanced by input force to the other pedal to pull up the other bearing assembly. These movements repeat as pedaling occurs, the occupant applying input force to one pedal and then the other pedal.
FIGS. 32 to 35 illustrate a preferred feature of the invention. Each of the pedal shafts 28 and 30 carries a pivotally attached arm 114 having at its free end a series of teeth 116 which engage curved rack 118. By raising arm 114 as in FIG. 33 and moving the arm along with the pivotally attached pedal shaft, the teeth 116 can be made to engage at any point up or down the rack 118 as shown in FIG. 34, followed by re-engaging the teeth 116 at the selected location, FIG. 35. In this way, the occupant of the cockpit can adjust the distance from the cockpit to the pedals 24, 26 to suit.
As shown in FIGS. 49 and 50, the direction indicator 97 is attached via a flexible rod 99 to the vertical shaft 90. This vertical shaft 90 is attached to the horizontal shaft 45 so the indicator rotates when the horizontal shaft 45, along with drums 40, 42 and fins 32, 34, rotates.
Turning to the steering system of this invention in more detail, the drive steering system allows for the user to control the position of the lower unit of the drive, and therefore the direction of thrust, by operating a steering handle 104 located within arm's reach of the user. This handle 104 rotates around a vertical axis, and the direction the handle 104 is pointing correlates with the direction of thrust from the drive. This handle 104 can be rotated infinitely in either direction.
The steering system, FIG. 54, comprises a handle 104 affixed to a vertical shaft 105 that enters the hull of the boat. The shaft 105 is then connected to the ring gear 124 of a planetary gear system within housing cover 122 and housing element 123. This planetary gear system both reverses the direction of rotation, and doubles the angular rotation. The sun gear 126 output of this planetary gear system 127 is mated to a toothed drum 128 that interfaces with the toothed belt 120. This belt 120 runs through the compression tube 106 to a clutch system that mates with the drive. Both the steering system and the clutch system are provided with a pair of idler pulleys 109, 111 to tension belt 120. The toothed belt 120 interfaces with a toothed drum 130 on the clutch system, FIG. 53. This drum has tines 132 attached to the bottom of it that extend down into a clutch mechanism. When the user turns the handle 104, these tines press on roller bearings 134, forcing them away from the clutch surface, releasing the clutch and allowing the steering system to rotate. The purpose of the clutch is to keep the propulsion mechanism fixed while the drive is in use, but to allow the user to turn the lower unit with the handle 104. Force from the lower unit will not release the clutch. If the lower unit is over forced (in the case of hitting a submerged object for example) there is a built in slip mechanism to allow all parts of the steering system to rotate, including the clutch. This is to avoid high load damaging the clutch or other components in the steering system. The output shaft from the clutch is mated to a gear 110 that interlocks with a gear 112 on the drive. When the drive is inserted into the drive well 20, these two gears 110 and 112 engage each other. The gear 112 on the drive is twice as big as the clutch gear 110, and these mated gears turn opposite directions. This is why the planetary gear ratio and reversal in the steering system is necessary.
Turning to FIGS. 53 and 55 to 62 in more detail, the Dual Clutch Mechanism—In the propulsion mechanism of this invention rotatable through 360°, there is preferably a dual clutch system which is a subsystem of the steering system located in the well 20, directly next to the drive, interfacing with the lower unit of the drive by way of a 1:2 ratio spur gear. When the drive is put into the well 20, the spur gear 112 on the drive mates slidably with the spur gear 110 on the lower end of the dual clutch mechanism. This spur gear 110 is affixed to the output shaft 136 of the clutch. The purpose of the clutch is to allow rotational force from the steering handle 104 to rotate the lower unit of the drive, while resisting any rotational torque from the lower unit of the drive on the clutch output shaft 136. This allows the drive to be locked in position whenever the user is not actively turning the drive with the steering handle 104.
Toothed Drum (input)—This is the drum 130 that interfaces with the belt drive. It is the input of the dual clutch mechanism. It is a toothed drum 130 with three tines 132 that extend down from the lower surface of the drum 130 and into the clutch mechanism. When the toothed drum 130 is rotated, the tines 132 protruding into the clutch mechanism contact the roller bearings 134, pulling them away from the clutch sleeve 138, allowing free rotation of the clutch output shaft 136.
Roller Bearings 134—There are six roller bearings 136, located inside the clutch mechanism.
Clutch sleeve 138 is the cylindrical component that surrounds the roller bearings. The inside wall of the clutch sleeve 138 acts as a fixed clutch surface and interfaces with the roller bearings 136.
Trilobe—This is the lobed component 140 in the center of the clutch mechanism. It is affixed to the output shaft 136 of the clutch. Its function is to translate rotational force from the spur gear 110 into a camming action of the roller bearings 134 between the clutch sleeve 138 and the trilobe 140. This action locks the output shaft 136 of the clutch mechanism, holding the drive in position.
Spur Gear—This spur gear 110 interfaces with the spur gear 112 on the drive, and is affixed to the output shaft 136 of the clutch mechanism.
FIGS. 56 and 60 indicate, by arrows, the rotational force on the spur gear 110 showing the spur gear as it rotates, rotating the trilobe 140, the cam features on the trilobe pressing three of the roller bearings 134 into the inner wall of the clutch sleeve 138, locking the mechanism. If the spur gear were to be forced in the other direction, the other three roller bearings would lock between the trilobe 140 and the clutch sleeve 138.
Clutch Overide Bracket—The above described elements of the clutch mechanism are held in bracket 142 which is secured by bolts 144. The bracket 142 attaches the clutch sleeve 138 to the well 20. It clamps around a smaller cylindrical section 139 of the clutch sleeve 138. This clamping force can be adjusted to create a specific amount of holding force. If the drive is over powered, to avoid any mechanical failure in the clutch mechanism, the clutch sleeve 138 will slip in the clutch override bracket 142, allowing the drive and steering handle 104 to turn.
Turning to FIGS. 63 to 65, there another embodiment of the invention is shown. In this embodiment, the two bearing ring assemblies are not present and, hence, the vertical axis 90 about which the drums with fins are continuously rotatable is limited to about 90° to the left and right. While less preferred, this embodiment does afford the user a wide choice in change of direction using the above-described steering mechanism.
The manually operated steering system shown in detail in FIG. 54 can be replaced by an electronic system to operate the drive belt 120 of FIGS. 51 and 52. Alternatively, the manually operated steering system can be coupled with an electrically powered assist to decrease the input load required of the user to steer.
Turning to FIG. 66, this view shows that the propulsion mechanism is supported at its forward extremity at an area 146 in well 20 and at its rear at area 148.