Vehicles may use an engine drive system to drive various features in an internal combustion engine. For example, a typical engine drive system for a dual overhead camshaft arrangement includes a timing belt that engages various sprockets to rotate both camshafts and a crankshaft rotate.
For example, U.S. Pat. No. 4,674,452 describes a camshaft driving system for a dual overhead cam engine. The system includes a chain that engages a crankshaft and an intake camshaft. Further, the intake camshaft includes a gear that meshes with an exhaust camshaft gear such that an exhaust camshaft is driven in synchronization with the intake camshaft.
The inventors herein have recognized various issues with the above system. In particular, engaging toothed gears to synchronize the rotation of the camshafts also causes center distance limitations due to noise, vibration, and harshness (NVH) constraints and package constraints.
As such, one example approach to address the above issues is to couple the camshafts with a coupling device. In this way, it is possible to indirectly couple the camshafts, while reducing timing band load.
Specifically, in one embodiment, the coupling device engages a first camshaft via a drive pin and a second camshaft via a driven pin such that a position of the first camshaft is mirrored from a position of the second camshaft. This configuration enables the camshafts to rotate in opposing directions without directly engaging the camshafts with toothed sprockets. In this way, it is possible to engage only one drive camshaft with a timing band and the drive camshaft indirectly drives a driven camshaft that is not engaged with the timing band. Further, by rotating the camshafts in opposing directions, it is possible to take advantage of torque cancellation. As such, torque cancellation can reduce the timing band load resulting in improved durability, performance and fuel economy.
Note that various bands may be used, such as timing chain, a timing belt, or various other types of elastic and/or inelastic flexible bands. Further, the band may mate to toothed or un-toothed pulleys on the various shafts. Further still, additional bands may also be used, if desired.
It should be understood that the summary above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.
The following description relates to an engine drive system that uses a sprocket coupling device to couples a first camshaft to a second camshaft such that the camshafts rotate in opposing directions. This arrangement allows a timing band to engage only one camshaft, while the sprocket coupling device enables a kinetic energy of the first camshaft to be transferred to the second camshaft. By rotating the camshafts in opposite directions, it is possible to take advantage of torque cancellation. Further, torque cancellation can reduce loading on the timing band which increases durability of the band, performance of the engine drive system, and as a result fuel economy is improved. Further, this engine drive system allows for a more compact design with a lower weight than traditional designs due to the resulting geometric configuration.
Various accessory drives may be included in the disclosed engine drive system. For example, an oil pump and a balance shaft may be driven by the disclosed engine drive system, if desired. Additionally, the engine drive system may include various pulleys, idlers and tensioning devices to further ensure a reflex wrap angle, if desired.
Combustion cylinder 30 of a multi-cylinder engine may include combustion cylinder walls 32 with piston 136 positioned therein. Piston 136 may be coupled to crankshaft 140 so that reciprocating motion of the piston is translated into rotational motion of the crankshaft. Crankshaft 140 may be coupled to crankshaft sprocket 194 and crankshaft 140 may also be coupled to at least one drive wheel of a vehicle via an intermediate transmission system (not shown). Further, a starter motor (not shown) may be coupled to crankshaft 140 via a flywheel to enable a starting operation of the multi-cylinder engine. Crankshaft 140 may be lubricated with oil contained within oil sump 192.
Combustion cylinder 30 may receive air via intake passage 142 and may exhaust combustion gases via exhaust passage 148. Intake passage 142 and exhaust passage 148 may selectively communicate with combustion cylinder 30 via respective intake valve 152 and exhaust valve 154. In some embodiments, combustion cylinder 30 may include two or more intake valves and/or two or more exhaust valves.
In this example, intake valve 152 and exhaust valve 154 may be stimulated by camshafts 181 and 183 respectively, shown here as including camshaft lobes. Intake valve 152 and exhaust valve 154 may be further controlled by one or more cam actuation systems (not shown) which may each include one or more cams and may utilize one or more of cam profile switching (CPS), variable cam timing (VCT), variable valve timing (VVT) and/or variable valve lift (VVL) systems that may be operated by a controller to vary valve operation. The position of intake valve 152 and exhaust valve 154 may be determined by position sensors and intake valve 152 and/or exhaust valve 154 may be controlled by electric valve actuation.
Fuel injector 166 is shown coupled directly to combustion cylinder 30 for injecting fuel directly therein in proportion to the pulse width of signal FPW received from a controller. In this manner, fuel injector 166 provides what is known as direct injection of fuel into combustion cylinder 30. The fuel injector may be mounted on the side of the combustion cylinder or in the top of the combustion cylinder, for example. Fuel may be delivered to fuel injector 166 by a fuel delivery system (not shown) including a fuel tank, a fuel pump, and a fuel rail. In some embodiments, combustion cylinder 30 may alternatively or additionally include a fuel injector arranged in intake passage 142 in a configuration that provides what is known as port injection of fuel into the intake port upstream of combustion cylinder 30.
The engine drive system 100, as shown in
In one example, band 190 may engage toothed sprockets, where holes in the band align with the teeth of the sprocket. In another example, band 190 may contact a device without teeth such that a surface of the band may be in contact with a surface of the device, where the surface of the device may include a groove. Band 190 may contact each device with a wrap angle, which for one or more devices is a reflex wrap angle. Here, the wrap angle corresponds to an arc length of contact between the band 190 and the various sprockets, pulleys, etc. and a reflex wrap angle may be 180 degrees or more, but less than 360 degrees. Additionally, band 190 may engage some devices with a wrap angle that is smaller than a reflex wrap angle.
Camshaft 181 is shown coupled to band 190 via camshaft sprocket 185. Camshaft 181 and camshaft sprocket 185 are coupled such that they rotate together in a direction R1. Further, sprocket 185 is shown coupled to a coupling device 102 via a drive pin 104.
Camshaft 183 is shown coupled to camshaft sprocket 187, and notably, camshaft sprocket 187 does not engage with band 190. Further, camshaft sprocket 187 is coupled to the coupling device via a driven pin 106. As described in more detail below, the coupling device may be coupled to both camshaft sprockets such that camshaft sprocket 187 is rotated in an opposite direction from camshaft sprocket 185. Therefore, camshaft 183 and camshaft sprocket 187 are coupled such that they rotate together in a direction R2, which is opposite from direction R1. By rotating the camshafts in opposite directions, it is possible to take advantage of torque cancellation. Further, torque cancellation can reduce loading on band 190 which increases durability of the band, performance of the engine drive system, and as a result fuel economy is improved.
Camshaft sprockets 185 and 187 are shown with a diameter that is twice the diameter of crankshaft sprocket 194 to provide desired timing of intake valve 152 and exhaust valve 154 during the four-stoke combustion cycle. Alternatively, camshaft sprockets 185 and 187 may be another size, if desired.
Crankshaft 140 is shown coupled to band 190 via crankshaft sprocket 194 such that crankshaft 140 and crankshaft sprocket 194 rotate together. Further, crankshaft 140 and corresponding crankshaft sprocket 194 rotate in a direction R1. In this way, crankshaft 140 is configured such that its direction of rotation is the same as camshaft 181 and opposite that of camshaft 183.
Tensioning device 198 is shown engaged with band 190. Tensioning device 198 may employ various pulleys, springs, levers and other adjustment mechanisms to actively adjust the tension of band 190 which may ensure a reflex wrap angle around each sprocket, idler, pulley and the like. However, it will also be appreciated that engine drive system 100 may include sprockets, idlers and pulleys with a smaller wrap angle.
It will be appreciated that the drive system may include additional and/or alternative components than those illustrated in
Further, the engine drive system may include an idling device. For example, the idling device may be a pulley or a sprocket. It will be appreciated that engine drive system 100 may include more than one idling device 189 and each idling device may engage band 190 with a first contacting side 127 and/or a second contacting side 129.
Further, it is to be appreciated that one or more of the aforementioned accessory drives, tensioning devices, sprockets, pulleys, and/or idlers may engage first contacting side 127 or second contacting side 129 of band 190. Thus, it will be appreciated that band 190 is not limited to a path as illustrated in
As described above,
Camshaft sprocket 185 may be coupled to drive pin 104, as shown. Drive pin 104 may be attached to a surface 105 of camshaft sprocket 185 at a position between a center 108 of the sprocket and a perimeter 110 of the sprocket. For example, a center of drive pin 104 may be a distance 112 from the center 108. Therefore, drive pin 104 may rotate about center 108 when the vehicle is in operation. As such, drive pin 104 may rotate about an axis (e.g. a camshaft axis) at a radius that is less than a radius of sprocket 185.
Camshaft sprocket 187 may be coupled to a driven pin 106, as shown. Driven pin 106 may be attached to a surface 107 of camshaft sprocket 187 at a position between a center 114 of the sprocket and a perimeter 116 of the sprocket. For example, a center of driven pin 106 may be a distance 118 from the center 114. Therefore, driven pin 106 may rotate about center 114 when the vehicle is in operation. As such, driven pin 106 may rotate about an axis (e.g. a camshaft axis) at a radius that is less than a radius of sprocket 187.
As shown, sprocket coupling device 102 may be a rhombus-like shape. For example, coupling device 102 may be a rhombus with rounded corners 120. Further, the rounded rhombus may include sides 122 that are concave. Further, coupling device 102 may have two axes of symmetry. For example, coupling device may be symmetrical with respect to a horizontal axis 123 and a vertical axis 125, as shown. However, in some embodiments, the coupling device may have more than two axes of symmetry, one axis of symmetry, or the coupling device may be asymmetrical. Further, a horizontal section 124 may be longer than a vertical section 126. Further still, vertical section 126 may be wider than horizontal section 124. However, it will be appreciated that the relative shapes and sizes of the horizontal and vertical sections may differ from the illustrative embodiment without departing from the scope of this disclosure.
Further, coupling device 102 may include a plurality of apertures wherein each aperture is configured to engage a pin such that the pin is slidingly engaged with the coupling device. For example, coupling device 102 may include a first aperture 128 that engages drive pin 104, a second aperture 130 that engages driven pin 106, and a third aperture 132 that engages a fixed pin 134. Fixed pin 134 may be attached to the engine, and therefore, fixed pin 134 may couple the coupling device to the engine. As such, the fixed pin may be a static component of the cam drive mechanism. However, the static fixed pin may enable the coupling device to move vertically. As such, the fixed pin may slidingly attach the coupling device to the engine.
First aperture 128 may be an oblong shape that has a longer horizontal length than a vertical length. For example, the horizontal length may be smaller than a diameter of sprocket 185. Further, the vertical length may be slightly greater than a diameter of drive pin 104. Additionally, aperture 128 may have rounded corners. For example, aperture 128 may have a curvature at each end 136 that is approximately equal to a curvature of drive pin 104. However, it will be appreciated that the relative curvatures of the coupling device and each aperture may differ to some degree. In this way, aperture 128 accommodates drive pin 104 such that drive pin 104 is free to move within first aperture 128.
For example, aperture 128 may enable drive pin 104 to move within a defined space of aperture 128. Thus, aperture 128 may track a movement of drive pin 104. For example, aperture 128 may enable drive pin 104 to move horizontally. In this way, aperture 128 tracks the movement of drive pin 104 and constrains the movement of drive pin 104 to the horizontal direction. Further, since drive pin 104 is driven by band 190 engaging with sprocket 185 in the rotational direction R1, drive pin 104 drives a movement of coupling device 102.
Second aperture 130 may be an oblong shape that has a longer horizontal length than a vertical length, similar to first aperture 128. For example, the horizontal length may be smaller than a diameter of sprocket 187. Further, the vertical length may be slightly greater than a diameter of driven pin 106. Additionally, aperture 130 may have rounded corners. For example, aperture 130 may have a curvature at each end 138 that is approximately equal to a curvature of drive pin 106. In this way, aperture 130 accommodates driven pin 106 such that driven pin 106 is free to move within second aperture 130.
For example, second aperture 130 may enable driven pin 106 to move within a defined space of second aperture 130, similar to first aperture 128 and drive pin 104. Thus, aperture 130 may track a movement of driven pin 106. For example, aperture 130 may enable driven pin 106 to move horizontally. In this way, aperture 130 tracks the movement of driven pin 106 and constrains the movement of driven pin 106 to the horizontal direction. Further, since sprocket 187 does not engage with band 190, driven pin 106 is driven by the movement of coupling device 102, and thus, the movement of driven pin 106 enables sprocket 187 to rotate in the direction R2. As described above, direction R2 is opposite from direction R1. In other words, sprocket 185 may rotate in a clockwise direction and sprocket 187 may rotate in a counter clockwise direction.
Third aperture 132 may be configured to allow vertical movement of coupling device 102. Since third aperture 132 is configured to engage fixed pin 134, which is a static pin (e.g., attached to engine 10), the coupling device may be constrained such that the coupling device may only move along vertical axis 125.
In this way, coupling device 102 is coupled to both sprocket 185 and sprocket 187. Further, the first and second apertures enable horizontal movement of the drive pin and the driven pin respectively, and the third aperture enables vertical movement of the coupling device. Thus, the combined tracking features of the coupling device enable rotational movement of sprockets 185 and 187. Further, since sprocket 185 is rotatably engaged with band 190 and sprocket 187 is not rotatably engaged with band 190, coupling device 102 is configured to transfer kinetic energy from sprocket 185 to sprocket 187. For example, coupling device 102 may be configured to transfer the rotation of sprocket 185 to sprocket 187 such that sprocket 187 rotates in a direction that is opposite from sprocket 185, as described in more detail below with respect to
It will be appreciated that first and second apertures may be equivalent in shape and size. Further, second aperture 130 may be a reflection of first aperture 128 across vertical axis 125. Third aperture 132 may have similar dimensions as first and second apertures, or third aperture 132 may have a different dimension. As one example, third aperture 132 may have a vertical length that is greater than a horizontal length of the first and second apertures. It will be appreciated that third aperture 132 may vary from first and second apertures in other ways, if desired. For example, fixed pin 134 may have a greater diameter or a smaller diameter than the drive pin and the driven pin. Thus, the third aperture may be an appropriate size to accommodate such a fixed pin.
It will be appreciated that cam drive mechanism 100 is provided by way of example, and thus, is not meant to be limiting. Rather, cam drive mechanism 100 is provided to illustrate a general concept, as coupling device 102 may be various geometric configurations to couple one cam sprocket to another to enable the cam sprockets to rotate in opposing directions. Thus, it is to be understood that the cam drive mechanism illustrated in
For example,
As shown, cam drive mechanism 200 includes a coupling device 202. Similar to coupling device 102, coupling device 202 may have two axes of symmetry. For example, coupling device 202 may be symmetrical about horizontal axis 123 and vertical axis 125. However, in some embodiments, the coupling device may have more than two axes of symmetry, one axis of symmetry, or the coupling device may be asymmetrical. Further, coupling device 202 may include a plurality of apertures to engage various pins similar to coupling device 102.
Coupling device 202 may be a cross-like shape. For example, coupling device 202 may be two rounded rectangles that share a common center. In other words, coupling device 202 may be two rounded rectangles that coalesce to form the cross-like shape such that two axes of symmetry are maintained. As shown, a horizontal section 204 may be longer than a vertical section 206, and the two sections may intersect at right angles 208. However, it is to be understood that coupling device 202 may have another geometry without departing from the scope of this disclosure. For example, the horizontal and vertical sections may coalesce such that another angle is formed at the intersection of such sections. As another example, the intersection may include a concave or convex surface that transitions between the horizontal and vertical sections. Further, ends 210 may have a similar curvature as compared to an end curvature of each aperture. However, ends 210 may have a curvature that is different from the end curvature of each aperture.
It will be appreciated that cam drive mechanism 200 is provided by way of example, and thus, is not meant to be limiting. Rather, cam drive mechanism 200 is provided to illustrate a general concept, as coupling device 200 may be various geometric configurations to couple one cam sprocket to another to enable the cam sprockets to rotate in opposing directions. Thus, it is to be understood that the cam drive mechanism illustrated in
Further,
At the 0° cam degree position, drive pin 104, fixed pin 134, and driven pin 106 may be aligned such that each pin aligns with horizontal axis 123, as shown. In other words, horizontal axis 123 may bisect drive pin 104, fixed pin 134, and driven pin 106. Since the drive pin and the driven pin are dynamic pins, these pins may be temporarily aligned with horizontal axis 123. Therefore, drive pin 104 and driven pin 106 may be periodically bisected by horizontal axis 123. Conversely, the fixed pin may be permanently associated with horizontal axis 123 since fixed pin 134 is a static pin.
Further, the center of drive pin 104 may be a distance 302 from the center of driven pin 106. Distance 302 may be a shortest distance between the drive pin and the driven pin, as compared to positions other than the 0° cam degree position.
At the 90° cam degree position, drive pin 104 and driven pin 106 may be aligned with each other such that each pin aligns with horizontal axis 304, as shown. In other words, horizontal axis 304 may bisect drive pin 104 and driven pin 106. Further, horizontal axis 304 may be spaced apart from horizontal axis 123 by a vertical distance 306.
Further, at the 90° cam degree position, the center of drive pin 104 may be a distance 308 from the center of driven pin 106. Distance 308 may be greater than distance 302.
In this way, a rotation of sprocket 185 in the direction R1 drives a vertical movement of coupling device 202 in a direction generally indicated by arrow 307. Since the coupling device is coupled to both sprockets 185 and 187, and a position of sprocket 187 is mirrored from sprocket 185 about vertical axis 125, the vertical movement of coupling device 202 drives rotational movement of sprocket 187 in the direction R2.
At the 180° cam degree position, drive pin 104, fixed pin 134, and driven pin 106 may be aligned such that each pin aligns with horizontal axis 123, as shown. In other words, horizontal axis 123 may bisect drive pin 104, fixed pin 134, and driven pin 106, similar to the 0° cam degree position.
Further, at the 180° cam degree position, the center of drive pin 104 may be a distance 310 from the center of driven pin 106. Distance 310 may be greater than distances 302 and 308. Further, distance 310 may be a longest distance between the drive pin and the driven pin, as compared to positions other than the 180° cam degree position.
In this way, a rotation of sprocket 185 in the direction R1 drives a vertical movement of coupling device 202 in a direction generally indicated by arrow 309. Since the coupling device is coupled to both sprockets 185 and 187, and a position of sprocket 187 is mirrored from sprocket 185 about vertical axis 125, the vertical movement of coupling device 202 drives rotational movement of sprocket 187 in the direction R2.
At the 270° cam degree position, drive pin 104 and driven pin 106 may be aligned with each other such that each pin aligns with horizontal axis 312, as shown. In other words, horizontal axis 312 may bisect drive pin 104 and driven pin 106. Further, horizontal axis 312 may be spaced apart from horizontal axis 123 by a vertical distance 314. Further, a value of vertical distance 314 may be approximately equal to a value of vertical distance 306. In other words, the 270° cam degree position may be a reflection of the 90° cam degree position over horizontal axis 123.
Further, at the 270° cam degree position, the center of drive pin 104 may be a distance 316 from the center of driven pin 106. Distance 316 may be greater than distance 302. Further, a value of distance 316 may be approximately equal to a value of distance 308.
In this way, drive pin 104 (and likewise sprocket 185) rotates in a direction R1, which drives a vertical movement of the coupling device in a direction generally indicated by arrow 311, which also drives a rotational movement of driven pin 106 (and likewise sprocket 187) in a direction R2, opposite of R1. In other words, sprocket 185 indirectly drives the rotation of sprocket 187 due to the geometric configuration of the coupling device. Since the coupling device couples both sprockets such that sprocket 185 is a mirror image of sprocket 187 at each cam degree position, the sprockets may rotate in opposing directions. Therefore, band 190 may engage sprocket 185 and a rotation of this sprocket can be transferred to sprocket 187 without sprocket 187 being rotatably engaged with band 190.
It will be appreciated that the cam drive mechanism has other various positions, and the 0°, 90°, 180° and 270° cam degree positions are provided as non-limiting examples. For example, it will be appreciated that a 360° cam degree position may be approximately equal to the 0° cam degree position. Further, the cam drive mechanism may rotate such that all cam degree positions between 0° and 360° are enabled. Further still, the can drive mechanism may continue to rotate while the vehicle is in operation to drive various components of the engine.
It will be appreciated that the cam drive mechanisms illustrated in
It will be appreciated that the configurations and routines disclosed herein are exemplary in nature, and that these specific embodiments are not to be considered in a limiting sense, because numerous variations are possible. For example, the above technology can be applied to V-6, I-4, I-6, V-12, opposed 4, and other engine types. The subject matter of the present disclosure includes all novel and non-obvious combinations and sub-combinations of the various systems and configurations, and other features, functions, and/or properties disclosed herein.
The following claims particularly point out certain combinations and sub-combinations regarded as novel and non-obvious. These claims may refer to “an” element or “a first” element or the equivalent thereof. Such claims should be understood to include incorporation of one or more such elements, neither requiring nor excluding two or more such elements. Other combinations and sub-combinations of the disclosed features, functions, elements, and/or properties may be claimed through amendment of the present claims or through presentation of new claims in this or a related application. Such claims, whether broader, narrower, equal, or different in scope to the original claims, also are regarded as included within the subject matter of the present disclosure.
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Number | Date | Country | |
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20130139773 A1 | Jun 2013 | US |