JP5989882B2 - Transmission, vehicle equipped with the transmission, and motorcycle equipped with the transmission - Google Patents

Description

  The present invention relates to a transmission including a first clutch and a second clutch provided in independent torque transmission paths, a vehicle including the transmission, and a motorcycle including the transmission.

  Conventionally, a transmission including a first clutch and a second clutch provided in independent torque transmission paths has been known. Patent Document 1 discloses a motorcycle including such a transmission. The transmission is provided with a first transmission path and a second transmission path for transmitting the torque of the crankshaft to the drive shaft. The first transmission path includes a first clutch, a first main shaft, and an odd-numbered transmission gear mechanism. The second transmission path includes a second clutch, a second main shaft, and an even-numbered transmission gear mechanism. In the above transmission, the other clutch is disconnected while one clutch is connected, and the gear positions of both transmission gear mechanisms are changed. According to this transmission, it is possible to perform a shift without interrupting torque transmission.

  By the way, for example, when an abnormality occurs in the actuator that drives the clutch and neither the first transmission path nor the second transmission path transmits torque, the driving force of the engine is not transmitted to the drive shaft. In this case, no load is applied to the crankshaft, and the motorcycle enters a so-called idle state.

  In the transmission of Patent Document 1, the first clutch and the second clutch are both normally closed type clutches so that the idle running state does not occur even when an abnormality occurs in the actuator. The normally closed type clutch is a type of clutch that is not in a disconnected state unless it receives external force. In the above transmission, if an abnormality occurs during a shift, control of both actuators is stopped. Thereby, both clutches are automatically connected. Therefore, even if an abnormality occurs in one clutch, the driving force of the engine can be transmitted to the drive shaft via the other clutch, and an idling state can be avoided.

JP 2010-133555 A

  According to the above transmission apparatus, if an abnormality occurs during a gear shift, the control of both actuators is uniformly stopped regardless of the location and content of the abnormality. However, it is more preferable if a fail-safe operation according to the location and content of the abnormality is possible.

  The present invention has been made in view of such a point, and the object of the present invention is to provide a fail-safe operation that includes a first clutch and a second clutch and avoids an idling state when an abnormality occurs and the location and content of the abnormality. An object of the present invention is to provide a transmission that can be executed in accordance with the above.

  The transmission according to the present invention includes a first clutch and a second clutch to which torque of a crankshaft is transmitted, a first actuator and a second actuator that respectively connect and disconnect the first clutch and the second clutch, and the first clutch A first input shaft to which torque of the crankshaft is transmitted via the first clutch and the second clutch, a second input shaft, an output shaft for outputting torque, and the first input shaft; An odd-stage transmission gear mechanism having an input gear and an output gear provided on the output shaft and engageable with the input gear; an input gear provided on the second input shaft; and an output gear provided on the output shaft; An even-numbered transmission gear mechanism having an output gear engageable with the input gear, and a third actuator for changing gear positions of the odd-numbered gear and the even-numbered transmission gear mechanism. And a first transmission path for transmitting the abnormality of the first actuator or the torque of the crankshaft to the output shaft via the first clutch, the first input shaft, and the odd-stage transmission gear mechanism. A first abnormality detecting device for detecting the abnormality of the second actuator, the abnormality of the second actuator, or the torque of the crankshaft via the second clutch, the second input shaft, and the even-numbered transmission gear mechanism. A second abnormality detecting device that detects an abnormality of the second transmission path that transmits to the output shaft; and when the first abnormality detecting device detects an abnormality while shifting, the second clutch is in a connected state. During the period, the torque of the crankshaft is transmitted to the output shaft via at least one of the first transmission path and the second transmission path, and the second clutch is in the connected state. When the second actuator and the third actuator are controlled so that the torque of the crankshaft is transmitted to the output shaft via the two transmission paths, and the second abnormality detection device detects an abnormality during shifting. The torque of the crankshaft is transmitted to the output shaft via at least one of the first transmission path and the second clutch during a period until the first clutch is in a connected state, and the first clutch A fail-safe device that controls the first actuator and the third actuator so that the torque of the crankshaft is transmitted to the output shaft via the first transmission path when connected. It is.

  According to the present invention, in a transmission including a first clutch and a second clutch provided in independent torque transmission paths, a fail-safe operation for avoiding an idling state when an abnormality occurs, Can be executed according to.

1 is a side view of a motorcycle. It is sectional drawing of a drive unit. It is a conceptual diagram of the main elements of a drive unit. It is a figure explaining the state of a transmission and torque transmission when a gear position is 1st gear. It is a figure explaining the state of a transmission and torque transmission when a gear position is 2nd gear. It is a figure explaining the state of a transmission and torque transmission in case a gear position is the 3rd speed. It is a figure explaining the state of a transmission and torque transmission in case a gear position is 4th. It is a figure explaining the state of a transmission and torque transmission in case a gear position is 5th. It is a figure explaining the state of a transmission and torque transmission in case a gear position is 6 speed. It is the figure which looked at a part of 1st clutch from the right side. FIG. 11 is a partial cross-sectional view taken along line E-F-G in FIG. 10. (A) is the figure which looked at the boss | hub part of the center hub of a 1st clutch from the right side, (b) is the RR line | wire partial sectional view of (a). (A) is the figure which looked at the plate of the 1st clutch from the right side, (b) is the SS sectional view taken on the line of (a). (A) is a diagram showing the first cam and the second cam when forward torque is applied, (b) is a diagram showing the first cam and the second cam when reverse torque is applied, (c) ) Is a diagram showing the first cam and the second cam when reverse torque exceeding the upper limit is applied. It is a time chart showing an example of basic shift operation. It is a figure explaining the state of a transmission and torque transmission in the middle of gear shifting operation from the 2nd speed to the 3rd speed. It is a figure explaining the state of a transmission and torque transmission in the middle of gear shifting operation from the 2nd speed to the 3rd speed. It is a figure explaining the state of a transmission and torque transmission in the middle of gear shifting operation from the 2nd speed to the 3rd speed. It is a figure explaining the state of a transmission and torque transmission in the middle of gear shifting operation from the 2nd speed to the 3rd speed. It is a time chart showing other examples of speed change operation. It is a flowchart which shows the outline | summary of the process which a fail safe apparatus performs. It is a time chart of 1st fail safe operation | movement. It is a figure which shows an engine throttle valve, an ignition device, and a fuel injection valve. It is a time chart of 2nd fail safe operation | movement.

  Embodiments of the present invention will be described below. The transmission according to the present embodiment is mounted on a motorcycle 100 as shown in FIG. However, the transmission according to the present invention may be mounted on a vehicle other than the motorcycle 100. The transmission according to the present invention may be mounted on a device other than the vehicle. In the following description, front, rear, left, and right mean front, rear, left, and right, respectively, when viewed from a passenger seated on the seat 9 of the motorcycle 100. Symbols F, Re, L, and R in the figure represent front, rear, left, and right, respectively.

<Configuration of motorcycle>
As shown in FIG. 1, the motorcycle 100 includes a main frame 1 and a head pipe 2 provided at a front end portion of the main frame 1. A drive unit 20 is supported on the main frame 1. A front fork 3 is rotatably attached to the head pipe 2. A handle 5 is attached to the top of the front fork 3. A front wheel 4 is supported at the lower part of the front fork 3.

  A shift switch 15 is provided on the handle 5. The shift switch 15 is an input device that operates the transmission 7 and is operated by a passenger. The shift switch 15 has a shift up button and a shift down button (not shown). When the occupant presses the upshift button, the transmission 7 performs an upshift operation, and the gear position of the transmission 7 is increased by one step. When the occupant presses the downshift button, the transmission 7 performs a downshift operation, and the gear position of the transmission 7 is lowered by one step.

  The main frame 1 extends rearward and obliquely downward. A rear arm 11 is provided at the rear of the main frame 1. A rear wheel 12 is supported on the rear arm 11.

  Above the drive unit 20, a seat 9 and a fuel tank 9a are arranged. An ECU (Electronic Control Unit) 10 is disposed between the fuel tank 9 a and the drive unit 20. The ECU 10 is a control device that controls the operation of each part of the motorcycle 100. The ECU 10 also serves as a control device for the transmission 7. In addition, the installation location of ECU10 is not necessarily limited.

<Configuration of drive unit>
FIG. 2 is a cross-sectional view of the drive unit 20, and FIG. 3 is a conceptual diagram of main elements of the drive unit 20. As shown in FIG. 2, the drive unit 20 includes an engine 6 having a crankshaft 60 and a transmission 7. Hereinafter, although the structure of the drive unit 20 is demonstrated, the structure disclosed by Unexamined-Japanese-Patent No. 2010-133555 can be utilized as a structure of the drive unit 20. FIG. The disclosure content of the above publication is included in this specification.

<Configuration of transmission>
As shown in FIG. 2, the transmission 7 includes a first clutch 74 and a second clutch 75 to which the torque of the crankshaft 60 is transmitted, a first main shaft 71 connected to the first clutch 74, A second main shaft 72 connected to the clutch 75 and a drive shaft 73 for outputting torque are provided. Between the first main shaft 71 and the drive shaft 73, an odd-numbered transmission gear mechanism 51 is interposed. Between the second main shaft 72 and the drive shaft 73, an even-numbered transmission gear mechanism 52 is interposed.

  When the first clutch 74 is connected, the torque of the crankshaft 60 is transmitted to the drive shaft 73 via the first clutch 74, the first main shaft 71, and the odd-numbered transmission gear mechanism 51. When the second clutch 75 is connected, the torque of the crankshaft 60 is transmitted to the drive shaft 73 via the second clutch 75, the second main shaft 72, and the even-speed transmission gear mechanism 52. The first clutch 74, the first main shaft 71, and the odd-numbered transmission gear mechanism 51 constitute a first transmission path that transmits the torque of the crankshaft 60 to the drive shaft 73. The second clutch 75, the second main shaft 72, and the even-numbered transmission gear mechanism 52 constitute a second transmission path for transmitting the torque of the crankshaft 60 to the drive shaft 73.

  A sprocket 76 is fixed to the drive shaft 73. A drive chain 13 (see FIG. 1) is wound around the sprocket 76. The drive chain 13 is wound around a gear fixed to a rotating shaft (not shown) of the rear wheel 12. The torque of the drive shaft 73 is transmitted to the rear wheel 12 through the sprocket 76, the drive chain 13, and the gear.

  As shown in FIG. 3, the transmission 7 includes a first actuator 77 that drives the first clutch 74 and a second actuator 78 that drives the second clutch 75. The ECU 10 controls the first actuator 77 to connect / disconnect the first clutch 74, and controls the second actuator 78 to connect / disconnect the second clutch 75.

  The odd speed transmission gear mechanism 51 has input gears 81 a, 83 a, 85 a provided on the first main shaft 71 and output gears 81 b, 83 b, 85 b provided on the drive shaft 73. The even-numbered transmission gear mechanism 52 has input gears 82 a, 84 a, 86 a provided on the second main shaft 72 and output gears 82 b, 84 b, 86 b provided on the drive shaft 73.

  The input gear 81a and the output gear 81b, the input gear 82a and the output gear 82b, the input gear 83a and the output gear 83b, the input gear 84a and the output gear 84b, the input gear 85a and the output gear 85b, the input gear 86a and the output gear 86b, respectively 1st, 2nd, 3rd, 4th, 5th and 6th gear groups are formed. The first, third, and fifth gear groups can be switched between a state where torque can be transmitted from the first main shaft 71 to the drive shaft 73 and a state where torque cannot be transmitted via the gear group. . Each of the second, fourth, and sixth gear groups can be switched between a state where torque can be transmitted from the second main shaft 72 to the drive shaft 73 and a state where torque cannot be transmitted via the gear group. . Hereinafter, a state where torque can be transmitted is referred to as an “engaged state”, and a state where torque cannot be transmitted is referred to as a “non-engaged state”. The engaged state is a state in which the input gear rotates with the main shaft and the output gear rotates with the drive shaft. The non-engaged state is a state in which the input gear idles with respect to the main shaft or the output gear idles with respect to the drive shaft. Torque is transmitted from the first main shaft 71 or the second main shaft 72 to the drive shaft 73 at a predetermined gear ratio by appropriately selecting a gear group to be engaged from the first to sixth gear groups. be able to.

  The input gear 81a is configured to rotate together with the first main shaft 71. The output gear 81 b is configured to rotate relative to the drive shaft 73. The input gear 82 a is configured to rotate together with the second main shaft 72. The output gear 82 b is configured to rotate relative to the drive shaft 73. The input gear 83a is configured to rotate together with the first main shaft 71. The output gear 83 b is configured to rotate relative to the drive shaft 73. The input gear 84 a is configured to rotate with the second main shaft 72. The output gear 84 b is configured to rotate relative to the drive shaft 73. The input gear 85 a is configured to rotate relative to the first main shaft 71. The output gear 85 b is configured to rotate with the drive shaft 73. The input gear 86 a is configured to rotate relative to the second main shaft 72. The output gear 86 b is configured to rotate with the drive shaft 73.

  The transmission 7 includes a shift cam 14 and shift forks 141, 142, 143, and 144 that move to the left or right as the shift cam 14 rotates. The shift cam 14 is driven by a third actuator 79.

  The input gear 83a is movable to the left and right by being guided by the shift fork 142. The input gear 83a can engage with the input gear 85a by moving to the right. The input gear 83a and the input gear 85a rotate together by engaging with each other. The input gear 84a is movable to the left and right by being guided by the shift fork 143. The input gear 84a can be engaged with the input gear 86a by moving to the left. The input gear 84a and the input gear 86a rotate together by engaging with each other. The output gear 85b is movable to the left and right by being guided by the shift fork 141. The output gear 85b can be engaged with the output gear 81b by moving to the right. The output gear 85b and the output gear 81b rotate together by engaging with each other. The output gear 85b can engage with the output gear 83b by moving to the left. The output gear 85b and the output gear 83b rotate together by engaging with each other. The output gear 86b is movable to the left and right by being guided by the shift fork 144. The output gear 86b can engage with the output gear 82b by moving to the left. The output gear 86b and the output gear 82b rotate together by engaging with each other. The output gear 86b can engage with the output gear 84b by moving to the right. The output gear 86b and the output gear 84b rotate together by engaging with each other.

  The ECU 10 appropriately rotates the shift cam 14 by controlling the third actuator 79. As the shift cam 14 rotates, the shift forks 141 to 144 appropriately move to change the position of the input gear 83a, the input gear 84a, the output gear 85b, or the output gear 86b. Thereby, the gear positions of the transmission gear mechanisms 51 and 52 are changed. 4, 5, 6, 7, 8, and 9 are diagrams for explaining the state of the transmission 7 and the transmission of torque, and the gear position of the transmission 7 is 1st, 2nd, 3rd, respectively. The cases of speed, fourth speed, fifth speed, and sixth speed are shown.

<Configuration of clutch>
As shown in FIG. 2, the first main shaft 71 and the second main shaft 72 are aligned on the same straight line. The first main shaft 71 is disposed on the right side, and the second main shaft 72 is disposed on the left side. The first clutch 74 is provided at the right end portion of the first main shaft 71. The second clutch 75 is provided at the left end portion of the second main shaft 72. The first clutch 74 and the second clutch 75 have the same configuration. Below, the detail of the 1st clutch 74 is demonstrated and description of the 2nd clutch 75 is abbreviate | omitted.

  FIG. 10 is a right side view of a state in which a clutch spring 21 and a pressure plate 22 described later are removed from the first clutch 74. 11 is a cross-sectional view taken along the line D-F-G in FIG. A symbol m in FIG. 11 represents the center line of the first clutch 74.

  As shown in FIG. 11, the first clutch 74 includes a driven gear 40, a clutch housing 23, a plurality of friction plates 24, a plurality of clutch plates 25, a clutch boss 26, a pressure plate 22, and a clutch spring 21. .

  A collar 40 a is fitted around the first main shaft 71. The driven gear 40 is supported by the collar 40a via a needle bearing 40b. The driven gear 40 is rotatable with respect to the first main shaft 71. The driven gear 40 meshes with the crankshaft 60 (see FIG. 2) and rotates together with the crankshaft 60. The clutch housing 23 is configured to rotate together with the driven gear 40. Therefore, the clutch housing 23 rotates with the crankshaft 60.

  The friction plate 24 is formed in an annular shape. Splines are formed on the outer peripheral portion of the friction plate 24 and the inner peripheral portion of the clutch housing 23, respectively. The friction plate 24 is supported by the clutch housing 23 by engaging both the splines. The friction plate 24 can move to the left and right with respect to the clutch housing 23, but rotates integrally with the clutch housing 23.

  The clutch boss 26 includes a plate 27 and a center hub 28 assembled to the plate 27. The plate 27 has a boss portion 27b, and the first main shaft 71 passes through the boss portion 27b. The plate 27 is fixed to the first main shaft 71. The plate 27 rotates together with the first main shaft 71. The center hub 28 is disposed on the right side of the plate 27 and assembled to the boss portion 27b.

  The clutch plate 25 is formed in an annular shape. The center hub 28 has a boss portion 28a and a cylindrical portion 28b provided on the outer peripheral portion of the boss portion 28a. Splines are formed in the inner peripheral portion of the clutch plate 25 and the outer peripheral portion of the cylindrical portion 28b of the center hub 28, respectively. The clutch plate 25 is supported by the center hub 28 by engaging both the splines. The clutch plate 25 can move to the left and right with respect to the center hub 28, but rotates integrally with the center hub 28. Each clutch plate 25 is disposed between adjacent friction plates 24. The friction plates 24 and the clutch plates 25 are alternately arranged toward the left.

  The center hub 28 is assembled so as to be movable leftward and rightward with respect to the plate 27. A nut 30 is attached to the right end portion of the first main shaft 71 via a leaf spring 29. The center hub 28 is biased leftward by a leaf spring 29. That is, the center hub 28 is biased toward the plate 27 side.

  A boss portion 28a of the center hub 28 is provided with a long hole 31 (see FIG. 10) opened along the circumferential direction and a convex first cam 32 protruding leftward. A stud 33 extending rightward from the plate 27 passes through the long hole 31. The plate 27 is formed with a concave second cam 34 recessed leftward. The first cam 32 is detachably engaged with the second cam 34. A plurality of first cams 32 and second cams 34 are arranged at predetermined intervals along the circumferential direction. As shown in FIG. 10, a plurality of the long holes 31 are also formed at predetermined intervals along the circumferential direction.

  The pressure plate 22 is urged to the left by the clutch spring 21. The pressure plate 22 is supported by the pull rod 70 via a bearing 70a. When the pull rod 70 is pulled to the right, the pressure plate 22 moves to the right. As a result, the pressure plate 22 has no force to press the friction plate 24 and the clutch plate 25 together, and the first clutch 74 is disengaged. When the pull rod 70 is moved leftward, the pressure plate 22 moves leftward. The pressure plate 22 receives the urging force of the clutch spring 21 and presses the friction plate 24 and the clutch plate 25 together. As a result, the first clutch 74 is connected.

  A spline 35 is formed on the left portion of the pressure plate 22, and a spline 36 that meshes with the spline 35 is formed on the cylindrical portion 28 b of the center hub 28. The pressure plate 22 can move to the left and right with respect to the center hub 28, but rotates integrally with the center hub 28.

  The clutch spring 21 constantly urges the pressure plate 22 toward the left. Therefore, when the force for pulling the pull rod 70 to the right is lost, the pressure plate 22 moves to the left and presses the friction plate 24 and the clutch plate 25 together. The first clutch 74 is a so-called normally closed type clutch, and is a type of clutch that is in a connected state if no force is applied from the outside. For example, when the energization of the first actuator 77 is stopped, the first clutch 74 is connected. The second clutch 75 is also a normally closed type clutch.

<Back torque limiter>
The first clutch 74 transmits torque from the clutch housing 23 to the clutch boss 26. This torque is a torque for driving the rear wheel 12. Hereinafter, this torque is referred to as forward torque. On the other hand, when both the first transmission path and the second transmission path are in a state of transmitting torque, the first clutch 74 may be subjected to torque in the direction opposite to the forward direction. The reverse torque is a torque transmitted from the clutch boss 26 to the clutch housing 23. The first clutch 74 includes a back torque limiting device 37 that limits the torque in the reverse direction. The second clutch 75 is also provided with a similar back torque limiting device.

  The back torque limiting device 37 is mainly constituted by a plate 27, a center hub 28, and a leaf spring 29. 12A is a view of the boss portion 28a of the center hub 28 as viewed from the right side, and FIG. 12B is a partial cross-sectional view taken along line RR in FIG. 12A. As shown in FIGS. 12A and 12B, the first cam 32 of the center hub 28 has a vertical surface 32a positioned on the front side in the forward direction and an inclined surface 32b positioned on the rear side in the forward direction. doing. Fig.13 (a) is the figure which looked at the plate 27 from the right side, FIG.13 (b) is the SS sectional view taken on the line of FIG.13 (a). As shown in FIGS. 13A and 13B, the second cam 34 of the plate 27 has a vertical surface 34a located on the front side in the forward direction and an inclined surface 34b located on the rear side in the forward direction.

  As shown in FIG. 14A, when a forward torque is applied to the first clutch 74, the torque is transmitted from the boss portion 28 a of the center hub 28 to the plate 27. In this case, the first cam 32 of the boss portion 28a is the driving side, and the second cam 34 of the plate 27 is the driven side. The first cam 32 enters the second cam 34, the vertical surface 32 a of the first cam 32 and the vertical surface 34 a of the second cam 34 come into contact with each other, and force is transmitted from the first cam 32 to the second cam 34. Is done. Therefore, the center hub 28 and the plate 27 rotate together.

  As shown in FIG. 14B, when reverse torque is applied to the first clutch 74, torque is transmitted from the plate 27 to the boss portion 28 a of the center hub 28. In this case, the second cam 34 of the plate 27 is the driving side, and the first cam 32 of the boss portion 28a is the driven side. Since the inclined surface 32b of the first cam 32 and the inclined surface 34b of the second cam 34 are in contact with each other, a reverse force acts on the first cam 32 via both inclined surfaces 32b and 34b. On the other hand, since the boss portion 28a receives a force in the direction toward the plate 27 (downward in FIG. 14B) by the leaf spring 29, the first cam 32 also receives a forward force. Therefore, when the reverse force acting on the first cam 32 is smaller than the forward force, the first cam 32 does not move relative to the second cam 34.

  On the other hand, when the reverse force acting on the first cam 32 is larger than the forward force, the first cam 32 follows the inclined surface 34b of the second cam 34 as shown in FIG. To move in the opposite direction. Thereby, the boss 28a of the center hub 28 moves in a direction away from the plate 27 (upward in FIG. 14C), in other words, to the right. As a result, the cylindrical portion 28b of the center hub 28 comes into contact with the pressure plate 22, and the cylindrical portion 28b pushes the pressure plate 22 to the right (see FIG. 11). Then, the force with which the pressure plate 22 presses the friction plate 24 and the clutch plate 25 against each other is weakened or disappears. Thereby, the torque transmitted from the clutch plate 25 to the friction plate 24 decreases or disappears, and transmission of torque in the reverse direction is limited. It should be noted that the upper limit value of the reverse torque can be appropriately set by adjusting the inclination angle of both the inclined surfaces 32b and 34b or the spring constant of the leaf spring 29.

<Speed change operation>
Next, the shift operation will be described by taking a shift from the second speed to the third speed as an example. FIG. 15 is a time chart of the speed change operation, and FIGS. 16, 17, 18, and 19 are conceptual diagrams showing the state of the transmission 7 and torque transmission at times t1, t2, t3, and t4.

  In the following description, the state of the clutch that transmits a part of the input torque is referred to as “half-clutch state”. A state in which the friction plate 24 transmits torque while sliding with respect to the clutch plate 25 is a half-clutch state. A state in which no torque is transmitted is referred to as a “cut-off state”, and a state in which all of the input torque is transmitted is referred to as a “connected state”.

  At t0, the transmission 7 is in the second speed state as shown in FIG. As shown in FIG. 5, when the gear position of the odd-numbered transmission gear mechanism 51 is neutral and the gear position of the even-numbered transmission gear mechanism 52 is second gear, the gear position of the transmission 7 is second gear. . When the occupant presses the upshift button at t0, the speed change operation is started, and the first clutch 74 is driven to the disengagement side. At t1, the first clutch 74 is in the disconnected state, and the gear position of the transmission gear mechanism 51 is switched from neutral to the third speed (see FIG. 16). As shown in FIG. 16, at t1, the gear position of the transmission gear mechanism 51 is the third speed, the gear position of the transmission gear mechanism 52 is the second speed, and both the transmission gear mechanism 51 and the transmission gear mechanism 52 are engaged. It becomes a state.

  Next, the first clutch 74 is driven to the connection side, and the second clutch 75 is driven to the disconnection side. At t2, the first clutch 74 and the second clutch 75 are in a half-clutch state (see FIG. 17).

  Thereafter, the first clutch 74 is further driven to the connection side, and the second clutch 75 is further driven to the disconnection side, and is eventually disconnected. At t3, the first clutch 74 is in a half-clutch state, but the second clutch 75 is in a disconnected state (see FIG. 18).

  After the second clutch 75 is disengaged, at t4, the gear position of the transmission gear mechanism 52 is switched from the second speed to the neutral (see FIG. 19). Thereafter, the second clutch 75 is connected. At t5, the transmission 7 is in the third speed state as shown in FIG. As shown in FIG. 6, when the gear position of the odd-numbered transmission gear mechanism 51 is 3rd speed and the gear position of the even-numbered transmission gear mechanism 52 is neutral, the gear position of the transmission 7 is 3rd speed.

  The above operation is a basic speed change operation of the transmission 7. The speed change operation of the transmission 7 is not limited to the above operation, and for example, a speed change operation as shown in FIG. 20 is also possible. In this speed change operation, driving of the second clutch 75 to the disengagement side is started before the gear position of the odd-numbered speed change gear mechanism 51 is changed from the neutral to the third speed (see t10). When the engine speed starts to decrease after the first clutch 74 is driven to the connection side, the first clutch 74 is considered to be in a state of transmitting torque, and the gear position of the even-numbered transmission gear mechanism 52 is changed. The speed is changed from the second speed to neutral, and the driving of the second clutch 75 to the connection side is started (see t12). By performing such a shifting operation, the time required for shifting can be shortened.

  In addition, although the said operation | movement is a speed change operation | movement from 2nd speed to 3rd speed, the speed change operation | movement of another gear position can be performed similarly.

  According to the speed change operation, the second clutch 75 is controlled to maintain the connected state until the first clutch 74 is disengaged and the gear position of the odd-numbered speed change gear mechanism 51 is set to the third speed (FIG. 20). T11). The second clutch 75 is maintained in the connected state until both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are engaged. When the first clutch 74 is driven to the connection side and the second clutch 75 is driven to the disconnection side, both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are maintained in the engaged state. The Therefore, even if an abnormality occurs in one of the clutches in this state, the torque of the crankshaft 60 can be transmitted to the drive shaft 73 by connecting the other clutch. Therefore, an idle running state can be prevented.

  Further, according to the speed change operation, after the first clutch 74 is in a state of transmitting torque, the gear position of the even-numbered speed change gear mechanism 52 is changed to neutral (see t12 in FIG. 20). Until the first clutch 74 is at least in the half-clutch state, both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are maintained in the engaged state. Therefore, even if an abnormality occurs in one of the clutches in this state, it is possible to transmit the torque of the crankshaft 60 to the drive shaft 73 by connecting the other clutch, thereby preventing the idling state. Can do.

<Abnormality detection device>
As shown in FIG. 3, the transmission 7 detects a first abnormality detection device 91 that detects an abnormality in the first actuator 77 or an abnormality in the first transmission path, and an abnormality in the second actuator 78 or an abnormality in the second transmission path. And a second abnormality detection device 92 for detecting. Here, the abnormality of the actuator means that the actuator does not operate normally. The abnormality of the actuator includes not only abnormality of the actuator itself but also disconnection of an electric wire that supplies a signal to the actuator. The abnormality of the transmission path means that the transmission path does not normally transmit torque. The transmission path abnormality includes a clutch abnormality, an input gear abnormality, an output gear abnormality, and the like. For example, when the rotation speed or transmission torque of the first main shaft 71, the second main shaft 72, or the drive shaft 73 is not a predetermined rotation speed or transmission torque according to the gear position, it can be considered that an abnormality has occurred.

<Fail-safe device>
The transmission 7 has a fail safe device 93. Here, the fail-safe device 93 is configured by the ECU 10, but the fail-safe device 93 may be separate from the ECU 10. When the first abnormality detection device 91 detects an abnormality, the fail safe device 93 causes the second actuator 78 and the third actuator 79 to transmit the torque of the crankshaft 60 to the drive shaft 73 via the second transmission path. Control. Further, when the second abnormality detection device 92 detects an abnormality, the fail safe device 93 includes a first actuator 77 and a third actuator so as to transmit the torque of the crankshaft 60 to the drive shaft 73 via the first transmission path. 79 is controlled.

  FIG. 21 shows a flow of processing performed by the fail safe device 93. The fail safe device 93 determines whether an abnormality is detected by the first abnormality detection device 91 or the second abnormality detection device 92 in step S1. If an abnormality is detected, the process proceeds to step S2, and if no abnormality is detected, the process ends. In step S2, the fail safe device 93 determines an abnormal part. In step S3, the fail safe device 93 determines the shift phase. That is, the fail-safe device 93 determines whether or not the gear shift operation is being performed, and determines to which stage the operation has proceeded when the gear shift operation is being performed. The fail-safe device 93 stores a plurality of abnormality handling processes determined in advance according to the shift phase. In step S4, the fail safe device 93 selects the abnormality handling process according to the shift phase. The fail safe device 93 selects a process of prohibiting the subsequent shift operation when the shift operation is not being performed. When the gear shifting operation is being performed, the fail safe device 93 selects a predetermined fail safe operation according to the stage of the gear shifting operation. In step S5, the fail safe device 93 executes the process selected in step S4. That is, the fail safe device 93 performs a predetermined fail safe operation.

<Example of first fail-safe operation>
Next, an operation example of the fail safe device 93 will be described. FIG. 22 is a diagram illustrating a case where an abnormality has occurred in the second clutch 75 and the second clutch 75 has been disengaged during a shift from the second speed to the third speed. As shown in FIG. 22, in this example, at the time t11, the second clutch 75 is supposed to be in a half-clutch state (see FIG. 20), and is in a disconnected state. In this case, the gear position of the odd-numbered transmission gear mechanism 51 is still neutral. However, the torque of the crankshaft 60 can be transmitted to the drive shaft 73 via the first transmission path by changing the gear position of the odd-numbered transmission gear mechanism 51 from neutral to the third speed. Therefore, when the second abnormality detection device 92 detects the abnormality of the second clutch 75 at time t10, the fail safe device 93 disengages the first clutch 74, and shifts the gear position of the odd speed transmission gear mechanism 51 from the neutral to the third speed. To. Thereafter, the fail safe device 93 connects the first clutch 74. Thereby, the crankshaft 60 and the drive shaft 73 are connected via the first transmission path. The idling of the drive shaft 73 is prevented and the idling state is avoided.

  When the fail safe device 93 performs the fail safe operation, the ECU 10 may change the torque of the crankshaft 60 so as to match the fail safe operation. In the fail-safe operation, after the abnormality occurs in the second clutch 75, both the first clutch 74 and the second clutch 75 may be disconnected (see, for example, t11). When the torque of the crankshaft 60 is large, in other words, when the rotational speed of the crankshaft 60 is high, the engine 6 may blow up. Further, when the first clutch 74 is subsequently connected, a large connection shock may occur. Therefore, the ECU 10 may reduce the torque of the crankshaft 60 when both the first clutch 74 and the second clutch 75 are in the disconnected state. Further, when the first clutch 74 is connected, the ECU 10 may cause the torque of the crankshaft 60 to have a magnitude corresponding to the connection. For example, as shown in FIG. 23, the ECU 10 appropriately changes the torque of the crankshaft 60 by appropriately changing the opening degree of the throttle valve 96 of the engine 6, the ignition timing of the ignition device 97, the injection amount of the fuel injection valve 98, or the like. May be changed. In this case, the throttle valve 96, the ignition device 97, the fuel injection valve 98, and the like function as a torque changing device that changes the torque of the crankshaft 60, and the ECU 10 functions as a torque control device that controls the torque changing device.

<Second fail-safe operation>
FIG. 24 is a diagram illustrating a case where an abnormality occurs in the first clutch 74 at time t13 during the shift from the second speed to the third speed, and the first clutch 74 stops moving in a half-clutch state. In this case, since the gear position of the even-numbered transmission gear mechanism 52 is neutral, even if the second clutch 75 is connected as it is, torque cannot be transmitted via the second transmission path. Therefore, when the first abnormality detection device 91 detects the abnormality of the first clutch 74 at time t13, the fail safe device 93 maintains the second clutch 75 in the disengaged state and the gear position of the even-numbered transmission gear mechanism 52. Return from neutral to 2nd. Thereafter, the fail safe device 93 connects the second clutch 75. Thereby, the crankshaft 60 and the drive shaft 73 are connected via the second transmission path. The idling of the drive shaft 73 is prevented and the idling state is avoided.

  Also in this fail-safe operation, the torque of the crankshaft 60 may be changed so that the ECU 10 controls the throttle valve 96 and the like to match the fail-safe operation.

  The above example is an example of fail-safe operation when shifting from 2nd gear to 3rd gear, but the same fail-safe operation is also possible when changing from another even gear position to another odd gear position. The action can be performed. The fail-safe operation in the above example can be performed not only when shifting up, but also when shifting down. The same fail-safe operation can be performed not only when changing from an even gear position to an odd gear position but also when changing from an odd gear position to an even gear position. .

  In the above-described operation example, when an abnormality occurs in the first transmission path, the state of the first clutch 74 is maintained at the state when the abnormality occurs, and when an abnormality occurs in the second transmission path, the second The state of the clutch 75 is maintained at the time when the abnormality occurs. That is, the clutch of the transmission path on which the abnormality has occurred is not driven to the connection side or the disconnection side. However, since the first clutch 74 and the second clutch 75 are normally closed clutches, the first clutch 74 and the second clutch 75 are automatically turned off by stopping the energization of the first actuator 77 and the second actuator 78, respectively. Can be connected. The fail-safe device 93 stops energization of the first actuator 77 when an abnormality occurs in the first transmission path when both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are engaged. Alternatively, energization of the second actuator 78 may be stopped when an abnormality occurs in the second transmission path. In this case, both the first clutch 74 and the second clutch 75 are in a connected state, and torque can be transmitted to the drive shaft via at least one of the first transmission path and the second transmission path. In addition, even when the first actuator 77 or the second actuator 78 is disconnected, both the first clutch 74 and the second clutch 75 are in a connected state, and are connected via at least one of the first transmission path and the second transmission path. Thus, torque can be transmitted to the drive shaft. Therefore, idling of the drive shaft 73 is prevented, and an idling state can be avoided.

  When both the first transmission path and the second transmission path transmit torque, a torque in the reverse direction is generated in the clutch of the transmission path with the smaller transmission torque. However, the first clutch 74 and the second clutch 75 are provided with a back torque limiting device 37. Therefore, the reverse torque is suppressed to a predetermined upper limit value or less. Therefore, even if both transmission paths are in a state of transmitting torque, normal operation of the drive unit 20 is not hindered.

  As described above, when an abnormality occurs in the first actuator 77 or the first transmission path, the fail-safe device 93 places the even-numbered transmission gear mechanism 52 in the engaged state and places the second clutch 75 in the connected state. . Thereby, the torque of the crankshaft 60 can be transmitted to the drive shaft 73 through at least the second transmission path. Further, when an abnormality occurs in the second actuator 78 or the second transmission path, the fail safe device 93 puts the odd-numbered transmission gear mechanism 51 into an engaged state and puts the first clutch 74 into a connected state. Thereby, the torque of the crankshaft 60 can be transmitted to the drive shaft 73 via at least the first transmission path. According to the fail-safe device 93, it is possible to maintain a state in which torque is transmitted to the drive shaft 73 using the normal transmission path in the event of an abnormality. Therefore, the idle running state of the motorcycle 100 can be prevented. According to the transmission device 7 of the present embodiment, compared to the case where both the first clutch 74 and the second clutch 75 are brought into the connected state by stopping the energization of the first actuator 77 and the second actuator 78 at the time of abnormality. Fail operation according to the location and content of the abnormality is possible.

  Like the second fail-safe operation, the fail-safe device 93 may maintain the state of the first clutch 74 at the state of the first clutch 74 when the abnormality is detected when the first abnormality detection device 91 detects the abnormality. it can. That is, when the first abnormality detection device 91 detects an abnormality, the fail-safe device 93 can immediately stop the first clutch 74 and prevent further operation. Further, as in the first fail-safe operation, the fail-safe device 93 maintains the state of the second clutch 75 in the state of the second clutch 75 at the time of detecting the abnormality when the second abnormality detecting device 92 detects the abnormality. be able to. In other words, the fail safe device 93 can stop the second clutch 75 when the second abnormality detection device 92 detects an abnormality, and can prevent further operation. As a result, since the clutch of the transmission path on which the abnormality has occurred is held as it is, it is possible to avoid a sudden behavior change that may occur when the clutch is operated. For example, it is possible to avoid a connection shock or the like that may occur when the clutch in which an abnormality has occurred is connected.

  When changing from an odd gear position to an even gear position, the ECU 10 first disengages the second clutch 75, and then shifts the even gear transmission mechanism 52 from the disengaged state to the engaged state. To do. Next, the ECU 10 connects the second clutch 75 and disconnects the first clutch 74 so that at least part of the torque of the crankshaft 60 is transmitted to the second main shaft 72. Next, the ECU 10 changes the odd-numbered transmission gear mechanism 51 from the engaged state to the disengaged state, and then connects the first clutch 74. According to such a shift operation, when the second clutch 75 is connected and the first clutch 74 is disconnected, both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are in the engaged state. Become. Therefore, when an abnormality occurs at this time, it is possible to prevent the idling state only by connecting the clutch of the transmission path on which the abnormality has not occurred.

  The same applies when changing from an even gear position to an odd gear position. That is, when changing from the even gear position to the odd gear position, the ECU 10 first disengages the first clutch 74 and then engages the odd speed transmission gear mechanism 51 from the non-engaged state. State. Next, the ECU 10 connects the first clutch 74 and disconnects the second clutch 75 so that at least a part of the torque of the crankshaft 60 is transmitted to the first main shaft 71. Next, the ECU 10 changes the even-speed transmission gear mechanism 52 from the engaged state to the disengaged state, and then connects the second clutch 75. As a result, when the first clutch 74 is connected and the second clutch 75 is disconnected, both the odd-numbered transmission gear mechanism 51 and the even-numbered transmission gear mechanism 52 are engaged. Therefore, when an abnormality occurs at this time, it is possible to prevent the idling state only by connecting the clutch of the transmission path on which the abnormality has not occurred.

  The ECU 10 can appropriately change the torque of the crankshaft 60 when the fail safe device 93 performs the fail safe operation. Therefore, it is possible to prevent the engine 6 from being blown up and to smoothly connect the clutches 74 and 75.

10 ECU (control device, torque control device)
51 odd-numbered transmission gear mechanism 52 even-numbered transmission gear mechanism 60 crankshaft 71 first main shaft (first input shaft)
72 Second main shaft (second input shaft)
73 Drive shaft (output shaft)
74 1st clutch 75 2nd clutch 77 1st actuator 78 2nd actuator 79 3rd actuator 81a, 83a, 85a Input gear 81b, 83b, 85b Output gear 82a of odd-numbered transmission gear mechanism 84a, 86a Even-speed transmission gear mechanism input gears 82b, 84b, 86b Even-speed transmission gear mechanism output gear 91 First abnormality detection device 92 Second abnormality detection device 93 Fail-safe device 100 Motorcycle (vehicle)

Claims (13)

A first clutch and a second clutch to which the torque of the crankshaft is respectively transmitted;
A first actuator and a second actuator that respectively connect and disconnect the first clutch and the second clutch;
A first input shaft to which torque of the crankshaft is transmitted via the first clutch and the second clutch, respectively, and a second input shaft;
An output shaft for outputting torque;
An odd-stage transmission gear mechanism having an input gear provided on the first input shaft and an output gear provided on the output shaft and engageable with the input gear;
An even-numbered transmission gear mechanism having an input gear provided on the second input shaft and an output gear provided on the output shaft and engageable with the input gear;
A third actuator for changing a gear position of the odd-numbered and even-numbered transmission gear mechanisms;
Abnormality of the first actuator or abnormality of the first transmission path for transmitting the torque of the crankshaft to the output shaft via the first clutch, the first input shaft, and the odd-numbered transmission gear mechanism A first abnormality detection device for detecting
Abnormality of the second actuator or abnormality of the second transmission path for transmitting the torque of the crankshaft to the output shaft via the second clutch, the second input shaft, and the even-numbered transmission gear mechanism A second abnormality detection device for detecting
When the first abnormality detection device detects an abnormality during shifting, the first clutch and the second transmission path are used to pass the at least one of the first transmission path and the second transmission path during a period until the second clutch is engaged. The second actuator transmits the crankshaft torque to the output shaft and transmits the crankshaft torque to the output shaft via the second transmission path when the second clutch is engaged. When the second abnormality detecting device detects an abnormality while controlling the third actuator and shifting, the first transmission path and the second transmission are in a period until the first clutch is engaged. Torque of the crankshaft is transmitted to the output shaft via at least one of the paths, and the clutch is transmitted via the first transmission path when the first clutch is engaged. Transmission torque of the click-axis equipped with a fail-safe device for controlling the first actuator and the third actuator to transmit to the output shaft.   When the first abnormality detection device detects an abnormality in the first transmission path, the fail-safe device maintains the state of the first clutch at the state of the first clutch at the time of abnormality detection, and detects the second abnormality. The transmission according to claim 1, wherein when the device detects an abnormality in the second transmission path, the state of the second clutch is maintained at the state of the second clutch at the time of detecting the abnormality. The apparatus further comprises a control device that controls the first actuator, the second actuator, and the third actuator,
When changing from an odd-numbered gear position to an even-numbered gear position, the second clutch is disengaged, the even-numbered transmission gear mechanism is changed from the disengaged state to the engaged state, and at least the torque of the crankshaft is The second clutch is connected and the first clutch is disconnected so that a part of the transmission is transmitted to the second input shaft, and the odd-numbered transmission gear mechanism is changed from the engaged state to the disengaged state. The transmission according to claim 1 or 2, wherein one clutch is connected.   In the fail-safe device, when changing from an odd-numbered gear position to an even-numbered gear position, the first transmission path does not transmit torque when the even-numbered transmission gear mechanism is disengaged. The transmission according to claim 3, wherein when the first abnormality detection device is detected, the even-numbered transmission gear mechanism is changed from the disengaged state to the engaged state, and the second clutch is connected.   When the fail-safe device changes from an odd-numbered gear position to an even-numbered gear position, the even-numbered transmission gear mechanism changes from a non-engaged state to an engaged state, and the odd-numbered gear transmission gear mechanism After the engagement state is changed to the non-engagement state, an abnormality that the second clutch does not move in a state where a part of the torque of the crankshaft is transmitted to the second input shaft is caused by the second abnormality detection device. 4. The transmission according to claim 3, wherein when detected, the odd-numbered transmission gear mechanism is changed from a non-engaged state to an engaged state, and the first clutch is connected. 5.   The apparatus further comprises a reverse torque limiting device that is disposed in the first transmission path and the second transmission path and limits transmission of the torque when torque in a direction opposite to the rotation direction of the crankshaft is applied. 5. The transmission according to 5. The apparatus further comprises a control device that controls the first actuator, the second actuator, and the third actuator,
When changing from an even-numbered gear position to an odd-numbered gear position, the first clutch is disengaged, the odd-numbered transmission gear mechanism is changed from a non-engaged state to an engaged state, and at least the torque of the crankshaft is The first clutch is connected and the second clutch is disconnected so that a part is transmitted to the first input shaft, and the even-speed transmission gear mechanism is changed from the engaged state to the disengaged state. The transmission according to claim 1 or 2, wherein two clutches are connected.   In the fail-safe device, when changing from an even-numbered gear position to an odd-numbered gear position, the second transmission path does not transmit torque when the odd-numbered transmission gear mechanism is disengaged. The transmission according to claim 7, wherein when the second abnormality detection device is detected, the odd-numbered transmission gear mechanism is changed from the disengaged state to the engaged state, and the first clutch is connected.   In the fail-safe device, when changing from an even-numbered gear position to an odd-numbered gear position, the odd-numbered transmission gear mechanism is changed from a non-engaged state to an engaged state, and the even-numbered gear mechanism is After the engagement state is changed to the non-engagement state, the first abnormality detection device causes an abnormality that the first clutch does not move while transmitting a part of the torque of the crankshaft to the first input shaft. The transmission according to claim 7, wherein when detected, the transmission gear mechanism of the even-numbered stage is changed from a non-engaged state to an engaged state, and the second clutch is connected.   The apparatus further comprises a reverse torque limiting device that is disposed in the first transmission path and the second transmission path and limits transmission of the torque when torque in a direction opposite to the rotation direction of the crankshaft is applied. The transmission according to claim 9. A torque changing device for changing the torque of the crankshaft;
A torque control device that controls the torque changing device so that the torque of the crankshaft is changed when the failsafe device performs the control;
The transmission according to claim 1, further comprising:   A vehicle comprising the transmission according to any one of claims 1 to 11.   A motorcycle comprising the transmission according to any one of claims 1 to 11.

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