JP2020100273A - Driving device for hybrid vehicle - Google Patents

Abstract

To provide a driving device for a hybrid vehicle which can inhibit vibration of a motor attachment part of a transmission case caused by load torque from a motor.SOLUTION: A motor 32 is disposed on a transmission mechanism 61, and a transmission case 5 has a right case 6, a left case 7, and a cover member 27 in this order from the side close to an engine 8. A transmission mechanism housing part 62 which houses a transmission mechanism 61 is formed by the right case 6, the left case 7, and the cover member 27. The left case 7 has a left case body part 7G and an expansion part 7H. An area in front of the expansion part 7H on an upper surface of the left case body part 7G is formed with a mount attachment part 31 having multiple mount attachment bosses to which a mount device 70 is attached. At least one of the multiple mount attachment bosses 31A to 31E is connected to a front wall part 29D which is a wall surface, ranging from the mount attachment boss 31A to 31E side, on a front surface of the expansion part 7H.SELECTED DRAWING: Figure 8

Description

The present invention relates to a drive device for a hybrid vehicle.

As a conventional power transmission device for a hybrid vehicle, the one described in Patent Document 1 is known. The power transmission device for a hybrid vehicle described in Patent Document 1 includes a transmission case having a transmission housing portion and a differential housing portion that houses the differential device, and the motor is located in front of the differential housing portion. Is attached to the outer periphery of the transmission case.

Further, in the power transmission device for a hybrid vehicle described in Patent Document 1, the side wall of the transmission case is formed with an opening through which the output shaft of the reduction gear is inserted, and the reduction gear case is formed on the side wall of the transmission case. Installed.

As a result, the power transmission device for a hybrid vehicle described in Patent Document 1 enables the rotary electric machine to be mounted in the transmission case without significantly modifying the existing drive device, and the drive device is applied to the hybrid vehicle. In both cases, when applied to a non-hybrid vehicle, vehicle mountability can be improved.

JP, 2005-145188, A

However, in the conventional power transmission device for a hybrid vehicle, a large load torque from the motor may act on the reduction gear case, and the reduction gear case may vibrate. Since the load torque from the motor is easily concentrated on the motor mounting portion of the transmission case, there was room for further study on the structure of the motor mounting portion.

The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a hybrid vehicle drive device capable of suppressing the vibration of the motor mounting portion of the transmission case due to the load torque from the motor. It is intended.

The present invention includes a speed change mechanism that changes the speed of rotation transmitted from an engine, a transmission case that accommodates the speed change mechanism, and a motor that transmits a driving force to the speed change mechanism. A drive device for a hybrid vehicle mounted on a vehicle body via a motor, wherein the motor is arranged above the transmission mechanism, and the transmission case is arranged from a side close to the engine in a right case, a left case and a cover. A left gear case, which has a member, is formed of the right case, the left case, and the cover member, and the left case forms a part of the left gear case. The main body and a motor mounting portion to which one end side of the motor in the axial direction is mounted are formed, and the motor has a bulging portion that bulges upward from the left case main body. A mount mounting portion having a plurality of mount mounting bosses to which the mounting device is mounted is formed in front of the protruding portion, and at least one of the plurality of mount mounting bosses is located on the mount mounting boss side on the front surface of the bulging portion. It is characterized in that it is connected to a front wall portion which is a wall surface.

As described above, according to the present invention, it is possible to suppress the vibration of the motor mounting portion of the transmission case due to the load torque from the motor.

FIG. 1 is a left side view of a hybrid vehicle drive device according to an embodiment of the present invention. FIG. 2 is a plan view of a hybrid vehicle drive device according to an embodiment of the present invention. FIG. 3 is a skeleton diagram of a hybrid vehicle drive device according to an embodiment of the present invention. 4 is a sectional view taken along the line IV-IV in FIG. FIG. 5 is a left side view of a hybrid vehicle drive device according to an embodiment of the present invention with a mount member mounted. FIG. 6 is a plan view of a hybrid vehicle drive device according to an embodiment of the present invention in which a mount member is mounted. FIG. 7 is a left side view of the hybrid vehicle drive system according to the embodiment of the present invention with the shift unit removed. FIG. 8 is a plan view of the hybrid vehicle drive system according to the embodiment of the present invention with the shift unit removed. FIG. 9 is a right side view of the left case of the hybrid vehicle drive device according to the embodiment of the present invention.

A hybrid vehicle drive device according to an embodiment of the present invention includes a transmission mechanism that shifts the rotation transmitted from an engine, a transmission case that houses the transmission mechanism, and a motor that transmits driving force to the transmission mechanism. Is a drive device for a hybrid vehicle in which a transmission case is attached to a vehicle body via a mounting device, the motor is arranged above the transmission mechanism, and the transmission case is a light case arranged from a side close to the engine. A left case main body that has a left case and a cover member, and forms a transmission mechanism accommodating portion that accommodates a transmission mechanism with a right case, a left case, and a cover member, and the left case forms a part of the transmission mechanism accommodating portion. And a bulging portion that bulges upward from the left case main body portion, the motor mounting portion to which one end side of the motor in the axial direction is attached is formed, and the motor mounting portion is provided on the upper surface of the left case main body in front of the bulging portion. A mount mounting portion having a plurality of mount mounting bosses to which the mounting device is mounted is formed, and at least one of the plurality of mount mounting bosses is connected to a front wall portion that is a wall surface on the mount mounting boss side on the front surface of the bulging portion. It is characterized by Accordingly, the hybrid vehicle drive device according to the embodiment of the present invention can suppress the vibration of the motor mounting portion of the transmission case due to the load torque from the motor.

Hereinafter, a hybrid vehicle drive device according to an embodiment of the present invention will be described with reference to the drawings.

1 to 9 are views showing a hybrid vehicle drive device according to an embodiment of the present invention.

1 to 9, the up, down, front, back, left, and right directions are the up, down, front, back, left, and right directions of the hybrid vehicle drive device installed in the vehicle, and the direction orthogonal to the vehicle front-rear direction is the left-right direction The height direction of the device is the vertical direction.

First, the configuration will be described. In FIG. 1, a hybrid vehicle (hereinafter, simply referred to as a vehicle) 1 includes a vehicle body 2, and a vehicle body 2 is partitioned by a dash panel 3 into a front engine room 2A and a rear vehicle room 2B. A drive device 4 is installed in the engine room 2A, and the drive device 4 has 6 forward speeds and 1 reverse speed. The drive unit 4 constitutes the hybrid vehicle drive unit of the present invention.

In FIG. 2, an engine 8 is connected to the drive device 4. The drive device 4 includes a transmission case 5, and the transmission case 5 includes a right case 6, a left case 7, and a cover member 27 in order from the engine 8 side.

An engine 8 is connected to the light case 6. The engine 8 has a crankshaft 9 (see FIG. 3), and the crankshaft 9 is installed so as to extend in the width direction of the vehicle 1. That is, the engine 8 of the present embodiment is composed of a horizontal engine, and the vehicle 1 of the present embodiment is a front engine/front drive (FF) vehicle.

The left case 7 is connected to the side opposite to the engine 8, that is, the left side of the right case 6. A flange portion 6F (see FIG. 2) is formed on the outer peripheral edge on the left side of the light case 6. 1 and 2, a flange portion 7F is formed on the outer peripheral edge on the right side of the left case 7.

As shown in FIG. 1, the flange portion 7F is provided with a boss portion 7f into which the bolt 23A is inserted, and a plurality of boss portions 7f are provided along the flange portion 7F.

The flange portion 6F has a plurality of boss portions (not shown) that match the boss portion 7f, and by fastening the boss portion of the flange portion 6F and the boss portion 7f of the flange portion 7F by bolts 23A (see FIG. 1). The right case 6 and the left case 7 are fastened and integrated.

A clutch 10 (see FIG. 3) is housed in the light case 6. The left case 7 accommodates the input shaft 11, the forward output shaft 12, the reverse output shaft 13, the final reduction mechanism 14 and the differential device 15 shown in FIG.

The input shaft 11, the forward output shaft 12, and the reverse output shaft 13 are installed in parallel along the left-right direction of the vehicle. The forward output shaft 12 of this embodiment constitutes the output shaft of the present invention. The speed change mechanism 61 is arranged in order of the input shaft 11, the forward output shaft 12, and the differential device 15 from the front of the vehicle.

In FIG. 3, the input shaft 11 is connected to the engine 8 via the clutch 10, and the power of the engine 8 is transmitted via the clutch 10. In FIG. 3, the input shaft 11 includes an input gear 16A for the first speed, an input gear 16B for the second speed, an input gear 16C for the third speed, an input gear 16D for the fourth speed, a input gear 16D for the fifth speed. It has an input gear 16E and an input gear 16F for the sixth speed.

The input gears 16A and 16B are fixed to the input shaft 11 and rotate integrally with the input shaft 11. The input gears 16C to 16F are rotatably provided on the input shaft 11 via needle bearings (not shown).

The forward output shaft 12 is an output gear 17A for the first speed, an output gear 17B for the second speed, an output gear 17C for the third speed, an output gear 17D for the fourth speed, an output gear 17D for the fifth speed. 17E, an output gear 17F for the sixth speed and a final drive gear 17G for forward movement.

The output gears 17A to 17F mesh with the input gears 16A to 16F that form the same gear. For example, the output gear 17D for the fourth gear meshes with the input gear 16D for the fourth gear.

The output gears 17A and 17B are relatively rotatably provided on the forward output shaft 12 via a needle bearing (not shown). The output gear 17C to the output gear 17F and the final drive gear 17G are fixed to the forward drive output shaft 12 and rotate integrally with the forward drive output shaft 12.

In the first speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16A and the output gear 17A. In the second speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16B and the output gear 17B.

A first synchronizer 18 is provided on the forward output shaft 12 between the output gears 17A and 17B.

When the shift operation shifts to the first gear, the first synchronizer 18 connects the output gear 17A of the first gear to the forward output shaft 12. When shifting to the second gear by the shift operation, the first synchronizer 18 connects the output gear 17B for the second gear to the output shaft 12 for forward movement. As described above, when the shift operation shifts to the first speed or the second speed, the output gear 17A or the output gear 17B rotates integrally with the forward output shaft 12.

A second synchronizer 19 is provided on the input shaft 11 between the input gears 16C and 16D.

When the shift operation shifts to the third speed, the second synchronizer 19 connects the input gear 16C to the input shaft 11. When shifting to the fourth speed by the shift operation, the second synchronizer 19 connects the input gear 16D to the input shaft 11. In this way, when the shift operation shifts to the third speed or the fourth speed, the input gear 16C or the input gear 16D rotates integrally with the input shaft 11.

In the third speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16C and the output gear 17C. In the fourth speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16D and the output gear 17D.

In this way, the second synchronizer 19 provided on the input shaft 11 includes one shift gear set including the input gear 16C and the output gear 17C, and one shift gear set including the input gear 16D and the output gear 17D. One transmission gear set is selected from the above, and power is transmitted to the forward output shaft 12 via the transmission gear set selected from the input shaft 11.

A third synchronizer 20 is provided on the input shaft 11 between the input gears 16E and 16F.

When shifted to the fifth speed by the shift operation, the third synchronizer 20 connects the input gear 16E to the input shaft 11. When the sixth gear is shifted by the shift operation, the third synchronizer 20 connects the input gear 16F to the input shaft 11. In this way, when the shift operation shifts to the fifth speed or the sixth speed, the input gear 16E or the input gear 16F rotates integrally with the input shaft 11.

In the fifth speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16E and the output gear 17E. In the sixth speed, the power of the engine 8 is transmitted from the input shaft 11 to the forward output shaft 12 via the input gear 16F and the output gear 17F.

As described above, the third synchronizer 20 provided on the input shaft 11 includes one shift gear set including the input gear 16E and the output gear 17E, and one shift gear set including the input gear 16F and the output gear 17F. One transmission gear set is selected from the above, and power is transmitted to the forward output shaft 12 via the transmission gear set selected from the input shaft 11.

The speed change gear set including the input gear 16D and the output gear 17D and the speed change gear set including the input gear 16E and the output gear 17E include a second synchronizer 19 and a third synchronizer 20 in the axial direction of the input shaft 11. Are installed adjacent to each other.

The reverse output shaft 13 is provided with a reverse gear 22A and a reverse final drive gear 22B. The reverse gear 22A is rotatably provided on the reverse drive output shaft 13 via a needle bearing (not shown), and meshes with the output gear 17A. The final drive gear 22B is fixed to the reverse output shaft 13 and rotates integrally with the reverse output shaft 13.

A fourth synchronizer 21 is provided on the reverse output shaft 13. When shifted to the reverse gear by the shift operation, the fourth synchronizer 21 connects the reverse gear 22A to the reverse output shaft 13. As a result, the reverse gear 22A rotates integrally with the reverse output shaft 13.

In the reverse gear, the power of the engine 8 is transmitted from the input shaft 11 to the reverse output shaft 13 via the input gear 16A, the output gear 17A that rotates relative to the forward output shaft 12, and the reverse gear 22A.

The forward drive final drive gear 17G and the reverse drive final drive gear 22B mesh with the final driven gear 15A of the differential device 15. As a result, the power of the output shaft 12 for forward drive and the power of the output shaft 13 for reverse drive are transmitted to the differential device 15 via the final drive gear 17G for forward drive or the final drive gear 22B for reverse drive.

The differential device 15 has a final driven gear 15A, a differential case 15B having the final driven gear 15A attached to the outer peripheral portion, and a differential mechanism 15C built in the differential case 15B.

A tubular portion 15c (see FIG. 4) is provided at the left end of the differential case 15B, and a tubular portion (not shown) similar to the tubular portion 15c is provided at the right end of the differential case 15B. As shown in FIG. 3, one end of each of the right drive shaft 24R and the left drive shaft 24L is inserted into the tubular portion 15c and the tubular portion (not shown).

One ends of the left and right drive shafts 24L and 24R are connected to the differential mechanism 15C, and the other ends of the left and right drive shafts 24L and 24R are connected to left and right drive wheels (not shown). The differential device 15 distributes the power of the engine 8 to the left and right drive shafts 24L and 24R by the differential mechanism 15C and transmits the power to the drive wheels. The final driven gear 15A rotates around the rotation axis 15a.

The input shaft 11, the forward output shaft 12, the input gear 16A to the input gear 16F, and the output gear 17A to the output gear 17F of the present embodiment constitute a speed change mechanism 61.

The final reduction mechanism 14 is composed of a final drive gear 17G for forward movement and a final driven gear 15A.

1 and 2, the motor 32 has a motor case 32A and a motor shaft 32B rotatably supported by the motor case 32A. A rotor (not shown) and a stator around which a coil is wound are housed inside the motor case 32A, and the motor shaft 32B is provided integrally with the rotor.

In the motor 32, a three-phase alternating current is supplied to the coil to generate a rotating magnetic field that rotates in the circumferential direction. The stator interlocks the generated magnetic flux with the rotor to rotate the rotor that is integral with the motor shaft 32B.

1 and 4, the transmission case 5 is provided with a speed reduction mechanism housing portion 25, and the speed reduction mechanism housing portion 25 is formed from a bulging portion 7H of the left case 7 described later and a cover member 27. It A speed reduction mechanism 33 (see FIG. 4) is housed inside the speed reduction mechanism housing portion 25.

3 and 4, the reduction mechanism 33 includes a first drive gear 34 provided on a motor shaft 32B of a motor 32, a first intermediate shaft 35, a second intermediate shaft 36, and a forward output shaft. 12 and an output gear 17D for the fourth speed.

The first intermediate shaft 35 is provided with a first driven gear 35A and a second drive gear 35B. The second intermediate shaft 36 is provided with a second driven gear 36A and a third drive gear 36B.

The first driven gear 35A is formed to have a diameter larger than the diameter of the first drive gear 34, and meshes with the first drive gear 34.

The second drive gear 35B is formed to have a smaller diameter than the diameters of the first driven gear 35A and the second driven gear 36A, and meshes with the second driven gear 36A.

The third drive gear 36B is formed to have the same diameter as the diameter of the second driven gear 36A and larger than the diameter of the output gear 17D for the fourth speed stage. Meshes with. In the gear pair that meshes with each other, the large-diameter gear has more teeth than the small-diameter gear.

The first drive gear 34 and the first driven gear 35A form a first reduction gear pair 37 that connects the motor shaft 32B and the first intermediate shaft 35. The second drive gear 35B and the second driven gear 36A connect the first intermediate shaft 35 and the second intermediate shaft 36, and form a second reduction gear pair 38. The third drive gear 36B and the output gear 17D connect the second intermediate shaft 36 and the output shaft 12 for forward movement, and form a third reduction gear pair 39.

As described above, the speed reduction mechanism 33 has the first intermediate shaft 35 and the second intermediate shaft 36 on the power transmission path that transmits power from the motor 32 to the forward output shaft 12. The reduction gear mechanism 33 decelerates the power of the motor 32 by setting the diameters and the number of teeth of the drive gears 34, 35B, 36B and the driven gears 35A, 36A to be arbitrary reduction ratios, and outputs the power for forward movement. It is transmitted to the shaft 12.

The left case 7 has a bulging portion 7H that bulges upward at the left end thereof. The opening at the left end of the left case 7 is enlarged upward by the bulging portion 7H. The bulging portion 7H is a case portion that constitutes the reduction mechanism housing portion 25, and the reduction mechanism 33 is arranged on the left side thereof.

1 and 2, the cover member 27 is joined (fastened) to the flange portion 7K at the left end portion of the left case 7 by a bolt 23B (see FIG. 1), and the left case 7 including the bulging portion 7H is also included. The opening at the left end of is closed. That is, the bulging portion 7H and the cover member 27 arranged on the left side of the bulging portion 7H form a reduction mechanism housing portion 25 that is a storage space for the reduction mechanism 33 from the left and right.

1 and 2, a motor mounting portion 29C is provided on the engine 8 side (right side) of the upper end of the bulging portion 7H. The motor mounting portion 29C is formed in a circular flange shape and has an outer diameter equivalent to the outer diameter of the motor 32, that is, the outer diameter of the motor case 32A.

A plurality of fastening portions 29m are provided on the outer peripheral portion of the motor mounting portion 29C, and the fastening portions 29m are arranged along the outer peripheral portion of the motor mounting portion 29C. The fastening portion 29m is formed as a boss portion into which the fastening bolt 23C is inserted. A bolt 23C is inserted into the fastening portion 29m, and the motor 32 is fastened to the motor attachment portion 29C by fastening the bolt 23C to a screw hole (not shown) formed in the motor case 32A.

The motor mounting portion 29C has a motor mounting surface facing rightward, and the motor 32 mounted on the motor mounting portion 29C is arranged so that the motor shaft 32B extends in the left-right direction of the vehicle. The motor 32 is arranged so as to extend rightward from the bulging portion 7H formed on the left side portion of the left case 7 while being exposed above the outside of the transmission case 5.

Further, as shown in FIG. 4, the center of the motor shaft 32B of the motor 32 is arranged between the input shaft 11 and the rotary shaft center 15a of the final driven gear in the front-rear direction of the vehicle. More specifically, the center of the motor shaft 32B of the motor 32 is disposed in the front-rear direction of the vehicle between the forward drive output shaft 12 and the rotary shaft center 15a of the final driven gear.

1 and 2, a shift unit 41 is installed above the left case 7 on the front side of the motor 32 in the front-rear direction of the vehicle. In a plan view of the vehicle 1, the motor 32 and the shift unit 41 are arranged close to the mount mounting portion 31 so as to approach the mount mounting portion 31 described later.

That is, the motor 32 and the shift unit 41 are installed before and after the mount attachment portion 31. In detail, the mount mounting portion 31 and the bulging portion 7H are formed side by side at the left end portion of the left case 7 side by side, and the shift unit 41 extends from the right side of the mount mounting portion 31 to the front side. It is arranged so as to extend forward.

The shift unit 41 is driven so as to perform a shift operation and a clutch operation of the drive device 4. Here, the shift operation refers to an operation of switching the shift speed of the drive device 4, and the clutch operation refers to an operation of engaging (connecting) or releasing (disconnecting) the clutch 10 of the drive device 4.

The shift unit 41 is a hydraulic device, and includes an oil pump, a motor for driving the oil pump, a valve unit 44, a pressure accumulator, a reservoir tank for hydraulic oil, and the like. The device has a large number of parts and is relatively heavy.

In particular, the valve unit 44 is a heavy component because a large number of solenoid valves are attached and a complex hydraulic passage and a hydraulic operating mechanism such as a cylinder are provided inside the valve unit 44. Also, the base plate 43 is a relatively thick metal plate to which a large number of constituent parts of the shift unit 41 are attached and which is attached to the left case 7, and is a heavy part.

In FIG. 4, the left case 7 houses a shift and select shaft 42. The shift and select shaft 42 is movable and rotatable in the axial direction with respect to the left case 7, and is operated by the shift unit 41 arranged above it.

That is, the shift and select shaft 42 is operated by a hydraulic operating mechanism such as a cylinder built in the valve unit 44, and the valve unit 44 is arranged above the shift and select shaft 42 in the axial direction.

The shift unit 41 is a shift map in which, for example, a throttle lever and a vehicle speed are set as parameters in advance when a shift lever (not shown) operated by a driver is shifted to the drive range or the reverse range. The shift and select shaft 42 is operated based on the.

The shift and select shaft 42 extends in the vertical direction and is arranged on the front side of the input shaft 11. All of them are provided with a shift operation mechanism including a shift yoke, a shifter shaft, a shift fork, etc., which are not shown. The first synchronizer 18 to the fourth synchronizer 21 are operated to control the shift speed. The shift unit 41 operates the shift and select shaft 42 by a hydraulic mechanism, a motor mechanism, or the like, but the drive system is not limited to these hydraulic mechanism, motor mechanism, and the like.

As shown in FIGS. 1 and 2, the transmission case 5 is provided with a front bracket 46A and a rear bracket 46B. The front bracket 46A connects the motor 32 and the light case 6, and supports the motor 32 on the light case 6.

The rear bracket 46B connects the motor 32 and the light case 6, and supports the motor 32 on the light case 6. In this way, the motor 32 is arranged outside the transmission case 5, one end portion (left end portion) in the axial direction is attached to the motor attachment portion 29C, and the other side in the axial direction (the other end portion, the right end portion). ) Is connected to the light case 6.

A connector 32C is provided behind the motor 32, and a power cable (not shown) that supplies electric power for driving the motor 32 is connected to the connector 32C.

As shown in FIG. 1 and FIG. 2, in the present embodiment, the motor 32 has a power receiving portion 32D that projects radially outward from the other end side (right end portion) of the motor 32 and receives power used by the motor 32. The left side surface of the portion 32D (the surface that is the one end side of the motor 32) has a connector 32C provided facing the one end side of the motor 32.

Since the connector 32C is provided facing the one end side of the motor 32, the attachment/detachment direction is along the motor shaft 32B, and the power cable can be routed along the motor 32.

A mount attachment portion 31 is provided on the upper portion of the left case 7. The mount mounting portion 31 is formed above the input shaft 11 at the left end portion of the left case 7, and has a plurality of mount mounting bosses 31A to 31E which are provided upright. The mount device 70 fixed to the vehicle body 2 is fastened to the mount attachment bosses 31A to 31E. As a result, the drive device 4 is elastically supported by the vehicle body 2 via the mount device 70.

The motor 32 is set above the left case 7 on the rear side of the mount attachment portion 31 in the front-rear direction of the vehicle. The engine 8 is elastically supported by the vehicle body 2 via a mounting device (not shown) for the engine.

As shown in FIG. 4, in the present embodiment, the motor 32 is arranged above the speed change mechanism 61. Further, as shown in FIG. 2, the transmission case 5 has a right case 6, a left case 7 and a cover member 27 which are arranged from the side closer to the engine 8. Further, a transmission mechanism housing portion 62 (see FIG. 4) for housing the transmission mechanism 61 is formed by the right case 6, the left case 7 and the cover member 27.

As shown in FIGS. 1, 2 and 4, the left case 7 includes a left case body portion 7G forming a part of the transmission mechanism housing portion 62, and one end of the motor 32 bulging upward from the left case body portion 7G. And a bulge 7H to which the side is attached. Further, in the left case 7, a mount mounting portion 31 having a plurality of mount mounting bosses 31A to 31E to which the mounting device 70 is mounted is formed in front of the bulging portion 7H on the upper surface of the left case main body portion 7G.

In the present embodiment, as shown in FIG. 5, the mount device 70 includes a drive device side bracket 71, an elastic member 73, and a vehicle body side bracket 72 that is a vehicle body 2 side bracket. The bracket 72 is connected via an elastic member 73.

The drive device side bracket 71 has a fixing portion that is attached to the mount attaching portion 31 of the left case 7, extends upward from the fixing portion, and is attached inside the elastic member 73. The vehicle body side bracket 72 is a bracket that surrounds the periphery of the elastic member 73 and attaches the elastic member 73 to the vehicle body 2.

Further, as shown in FIG. 5, the shaft center of the output shaft (motor shaft 32B) of the motor 32 is arranged between the mount attachment portion 31 and the elastic member 73 in the vertical direction when viewed from the left side. More specifically, the shaft center of the output shaft of the motor 32 (motor shaft 32B) is lower than the connecting portion between the drive device side bracket 71 and the elastic member 73 on the upper side of the mount mounting portion 31 when viewed in the axial direction. It is located in a position.

In the present embodiment, a shift unit 41 that automatically shifts the transmission mechanism 61 is provided, and the shift unit 41 is disposed on the opposite side of the mount attachment portion 31 from the motor 32 in the vehicle front-rear direction.

In this embodiment, as shown in FIGS. 5 and 6, the shift unit 41 has a base plate 43 to which at least a valve unit 44 for operating the shift and select shaft 42 by a hydraulic operating mechanism is attached.

The left case 7 has a base plate mounting portion 30 to which the base plate 43 is mounted. The base plate mounting portion 30 is an upper part of the left end portion of the left case 7, and is located on the front side of the mount mounting portion 31 and the mount mounting portion 31. It is located on the left side. The mounting surface of the base plate mounting portion 30 to which the base plate 43 is mounted is arranged below the mounting surface of the mount mounting portion 31 (the mounting surface on which the drive device side bracket 71 is mounted) in the vertical direction.

Further, as shown in FIG. 5, most of the valve unit 44 is disposed between the mount attachment portion 31 and the elastic member 73 in the left side view. Specifically, most of the valve unit 44 is disposed above the mount attachment portion 31 and lower than the connection point between the drive device side bracket 71 and the elastic member 73 when viewed in the axial direction.

Further, as shown in FIG. 6, the valve unit 44 is arranged on the rear side of the entire shift unit 41 in the front-rear direction of the vehicle, and is arranged at the same position as the motor 32 in the left-right direction of the vehicle.

7 and 8, a mount attachment portion 31 is formed in front of the bulging portion 7H on the upper surface of the left case body portion 7G, and the mount attachment portion 31 includes a plurality of mounts to which the mount device 70 is attached. It has mounting bosses 31A to 31E. Therefore, the mount device 70 is attached to the mount attachment portion 31.

Then, at least one of the plurality of mount mounting bosses 31A to 31E is connected to a front wall portion 29D that is a wall surface on the front surface of the bulging portion 7H on the side of the mount mounting bosses 31A to 31E.

The mount mounting boss 31A connected to the front wall portion 29D is connected to the front surface of the motor mounting portion 29C in the bulging portion 7H. That is, the front surface of the motor mounting portion 29C is the front wall portion 29D.

The mount mounting portion 31 also has a plurality of ribs 51 to 56 that connect the plurality of mount mounting bosses 31A to 31E to each other. The plurality of ribs 51 to 56 include the rib 51 as one specific rib that rises at the flange portion 7K of the left case 7 in the left side view of FIG. 7. Further, in the top view of FIG. 8, the rib 51 extends from the front wall portion 29D to the mount mounting bosses 31D and 31E in a direction orthogonal to the axis of the motor 32.

The drive device 4 also includes a shift unit 41 having a shift and select shaft 42 and a shift cover 45. In FIG. 8, an opening 7J through which the shift and select shaft 42 penetrates is formed in front of the mount mounting portion 31 on the upper surface of the transmission case 5, and the opening 7J is closed by the shift cover 45. The ribs 51 connect the mount attachment bosses 31D and 31E to the edge of the opening 7J.

7 and 8, the shift unit 41 has a base plate 43 fixed to the upper wall 7L of the transmission case 5. The base plate 43 is fastened to the upper surface wall 7L and the shift cover 45, and extends from the shift cover 45 to the vicinity of the front wall portion 29D of the bulging portion 7H across the sides of the mount mounting bosses 31A to 31E. .. The drive device 4 includes a support bracket 48 that connects the front end of the base plate 43 and the front side wall 5A of the transmission case 5.

In FIG. 9, the motor mounting portion 29C has a fastening portion 29m to which one end side of the motor 32 in the axial direction is fastened at the frontmost position. Then, when the vertical virtual line VL passing through the fastening portion 29m is set, the mount mounting boss 31A connected to the front surface of the motor mounting portion 29C in the bulging portion 7H has the outer periphery of the virtual line VL and the motor mounting portion 29C. And a position on the front side above the intersection P on the lower side of.

7 and 8, the base plate 43 has a protrusion 43A that protrudes forward of the transmission case 5, and an accumulator attachment portion 43B that extends downward from the protrusion 43A and that has an accumulator 47 attached to the front side. ing. The support bracket 48 connects the front surface of the accumulator mounting portion 43B and the side wall 5A of the transmission case 5.

Next, the operation will be described. When the vehicle is moving forward when the vehicle is moving forward, the power of the engine 8 is transmitted from the input shaft 11 to any of the output gear 17A to the output gear 17F via any of the input gear 16A to the input gear 16F that establishes a predetermined shift speed. Is transmitted to.

As a result, the power is transmitted from the final drive gear 17G of the output shaft 12 for forward drive to the final driven gear 15A, and the power of the engine 8 is distributed to the left and right drive shafts 24L and 24R by the differential mechanism 15C of the differential device 15 to drive the drive wheels. The vehicle 1 travels forward.

On the other hand, when the driving force of the motor 32 is applied when the vehicle 1 moves forward, the power of the motor 32 is transmitted from the motor shaft 32B to the first driven gear 35A via the first drive gear 34.

Next, the power of the motor 32 is transmitted to the output gear 17D for the fourth speed via the second drive gear 35B, the second driven gear 36A and the third drive gear 36B.

In the reduction mechanism 33, the drive gears 34, 35B, 36B and the driven gears 35A, 36A are set such that the diameters and the numbers of teeth of the reduction gears 33 have an arbitrary reduction ratio. Be transmitted to.

As a result, power is transmitted from the final drive gear 17G of the output shaft 12 for forward drive to the final driven gear 15A, and the vehicle 1 travels forward.

According to the drive device 4 of the present embodiment, the motor 32 is arranged above the speed change mechanism 61, and the transmission case 5 includes the right case 6, the left case 7, and the cover member 27 arranged from the side close to the engine 8. The transmission mechanism housing portion 62 that has the transmission mechanism 61 is formed by the right case 6, the left case 7, and the cover member 27.

Further, the left case 7 has a left case main body portion 7G forming a part of the speed change mechanism housing portion 62, and a bulging portion 7H to which one end side of the swelling motor 32 is attached upward from the left case main body portion 7G. ing. A mount mounting portion 31 having a plurality of mount mounting bosses to which the mounting device 70 is mounted is formed in front of the bulging portion 7H on the upper surface of the left case body portion 7G.

Then, at least one of the plurality of mount mounting bosses 31A to 31E is connected to a front wall portion 29D that is a wall surface on the front surface of the bulging portion 7H on the side of the mount mounting bosses 31A to 31E.

In this way, the mount mounting boss 31A is connected to the front wall portion 29D of the bulging portion 7H having high rigidity for mounting the motor 32 which is a heavy object. Further, the rigidity of the periphery of the mount mounting bosses 31A to 31E can be increased by fastening the mount device 70 to the mount mounting bosses 31A to 31E. Further, the load torque from the motor 32 can be dispersed and applied to the transmission case 5 via the mount mounting bosses 31A to 31E.

As a result, vibration of the motor mounting portion 29C of the transmission case 5 due to the load torque from the motor 32 can be suppressed.

According to the drive device 4 of this embodiment, the mount mounting boss 31A connected to the front wall portion 29D is connected to the front surface of the motor mounting portion 29C in the bulging portion 7H.

As a result, the front surface of the motor mounting portion 29C functions as the front wall portion 29D, and the torque load of the motor 32 acting on the motor mounting portion 29C can be directly received by the mount mounting boss 31A. Vibration can be suppressed.

According to the drive device 4 of the present embodiment, the mount attachment portion 31 has the plurality of ribs 51 to 56 that connect the plurality of mount attachment bosses 31A to 31E to each other.

Thus, when the torque load of the motor 32 acts on the mount mounting boss 31A via the motor mounting portion 29C, the load torque is input from the mount mounting boss 31A to the other mount mounting bosses 31B to 31E via the ribs 51 to 56. It For this reason, the load torque from the motor 32 can be dispersed and carried by the plurality of mount mounting bosses 31A to 31E, local concentration of torque load can be suppressed, and vibration of the mount mounting portion 31 can be suppressed.

According to the drive device 4 of the present embodiment, the plurality of ribs 51 to 56 include the rib 51 as one specific rib that rises at the flange portion 7K of the left case 7 in the left side view. Further, in a top view, the rib 51 extends from the front wall portion 29D to the mount mounting bosses 31D and 31E in a direction orthogonal to the axis of the motor 32.

In this way, the rib 51 is formed integrally with the flange of the transmission case 5 having high rigidity, and the mount mounting portion 31 boss is connected by the rib 51, so that the mount mounting bosses 31A to 31E are affected by the external force. Vibration can be suppressed.

Further, since the ribs 51 are arranged in a direction orthogonal to the axis of the motor 32, that is, in parallel with the direction of the torque load of the motor 32, the mount mounting bosses 31A to 31E with respect to the torque load of the motor 32 acting in the vertical direction. The rigidity can be improved.

According to the drive device 4 of the present embodiment, the drive device 4 includes the shift and select shaft 42, the shift cover 45, and the shift unit 41 that automatically shifts the speed change mechanism 61. Further, an opening 7J through which the shift and select shaft 42 penetrates is formed in front of the mount mounting portion 31 on the upper surface of the transmission case 5, and the shift cover 45 closes the opening 7J. The ribs 51 connect the mount mounting bosses 31A to 31E to the edge of the opening 7J.

Accordingly, the load torque dispersed in the plurality of mount mounting bosses 31A to 31E can be further taken up by the shift cover 45, and the load torque can be reduced to suppress the vibration of the mount mounting bosses 31A to 31E.

According to the drive device 4 of the present embodiment, the shift unit 41 has the base plate 43 fixed to the upper wall 7L of the transmission case 5. Further, the base plate 43 is fastened to the upper surface wall 7L and the shift cover 45, and extends from the shift cover 45 to the vicinity of the front wall portion 29D of the bulging portion 7H across the sides of the mount mounting bosses 31A to 31E. ing.

As a result, the base plate 43 of the shift unit 41 is attached to the upper surface of the shift case including the shift cover 45. Further, since the mount mounting bosses 31A to 31E are mounted from the front end to the rear end, the mount mounting bosses 31A to 31E can function as a reinforcing member that reinforces the periphery of the mount mounting portion 31. Therefore, the rigidity around the mount mounting bosses 31A to 31E can be improved, and the vibration of the motor mounting portion 29C can be further suppressed.

The drive device 4 according to the present embodiment includes the support bracket 48 that connects the front end portion of the base plate 43 and the front side wall of the transmission case 5.

Therefore, the base plate 43 provided on the upper surface of the transmission case 5 and the side wall 5A on the front side of the transmission case 5 are connected by the support bracket 48, so that the periphery of the mount mounting portion 31 is reinforced more firmly. Therefore, the vibration of the motor mounting portion 29C can be suppressed.

According to the drive device 4 of the present embodiment, the motor attachment portion 29C has the fastening portion 29m to which the one end side in the axial direction of the motor 32 is fastened at the frontmost position.

Then, when the vertical virtual line VL passing through the fastening portion 29m is set, the mount mounting boss 31A connected to the front surface of the motor mounting portion 29C in the bulging portion 7H is located between the virtual line and the outer peripheral edge of the motor mounting portion 29C. It projects above and below the lower intersection point P.

In this way, the torque load in the rotation direction R acts on the motor mounting portion 29C, and the tall mount mounting boss 31A on the front side and the upper side of the imaginary line VL is connected to the front wall portion 29D. When a torque load acts in the rotation direction R, vibration of the motor mounting portion 29C can be suppressed.

According to the drive device 4 of the present embodiment, the base plate 43 includes the projecting portion 43A projecting forward of the transmission case 5, and the accumulator mounting portion 43B extending downward from the projecting portion 43A and having the accumulator 47 mounted on the front surface side. , And the support bracket 48 connects the front surface of the accumulator mounting portion 43B and the side wall 5A of the transmission case 5.

Accordingly, the vibration of the base plate 43 due to the load torque can be suppressed by the support bracket 48.

According to the drive device 4 of the present embodiment, the support bracket 48 passes below the accumulator mounting portion 43B and connects the front surface of the accumulator mounting portion 43B and the side wall 5A of the transmission case 5. The support bracket 48 has a bent portion 48A that bends with a large curvature below the accumulator mounting portion 43B.

Here, the above-mentioned "large curvature" means that the radius of curvature is small and the curve is tight. In other words, the support bracket 48 is bent at the bent portion 48A in a narrow range without forming a curved surface. The bending angle of the bending portion 48A is approximately 90 degrees.

In this way, by bending the support bracket 48 with a large curvature in the bent portion 48A, the rigidity of the support bracket 48 can be improved and the vibration of the base plate 43 due to the load torque from the motor 32 can be suppressed.

According to the drive device 4 of the present embodiment, since the base plate 43 is provided, the support bracket 48 is not provided on the upper surface of the transmission case 5 to which load torque acts, and the influence of vibration due to load torque is small. Since the base plate 43 is attached to the side wall 5A of the transmission case 5, which is a part having a different behavior, the vibration of the base plate 43 can be suppressed.

Moreover, since the curvature of the support bracket 48 can be increased, the vertical length L of the support bracket 48 can be shortened. Therefore, the load moment acting on the transmission case 5 from the support bracket 48 can be reduced.

Specifically, when the direction of the load torque from the motor 32 is F1, the load moment in the direction indicated by F2 acts on the transmission case 5 from the support bracket 48 as a reaction force. Here, the length L of the support bracket 48 in the vertical direction corresponds to the arm length of the load moment. Therefore, in this embodiment, by shortening the length L, the load moment acting on the transmission case 5 can be reduced.

While an embodiment of this invention has been disclosed, it will be apparent to those skilled in the art that changes may be made without departing from the scope of this invention. All such modifications and equivalents are intended to be included in the following claims.

1...hybrid vehicle, 4...drive device (drive device for hybrid vehicle), 5...transmission case, 6...right case, 7...left case, 7G...left case body Parts, 7H... bulging part, 7K... flange part, 8... engine, 27... cover member, 30... base plate mounting part, 31... mount mounting part, 31A to 31E. .. Mount mounting boss, 32... Motor, 32B... Motor shaft, 41... Shift unit, 42... Shift and select shaft, 43... Base plate, 43B... Accumulator mounting portion, 45 ... shift cover, 48... support bracket, 48A... bent portions, 51-56... ribs, 61... transmission mechanism, 62... transmission mechanism accommodating portion, 70... mounting device

Claims (10)

A speed change mechanism that changes the speed of rotation transmitted from the engine,
A transmission case that houses the transmission mechanism;
A motor for transmitting driving force to the speed change mechanism,
A drive device for a hybrid vehicle, wherein the transmission case is attached to a vehicle body via a mount device,
The motor is arranged above the speed change mechanism,
The transmission case has a right case, a left case and a cover member arranged from a side close to the engine,
A transmission mechanism accommodating portion that accommodates the transmission mechanism is formed of the right case, the left case, and the cover member,
The left case is
A left case body that forms a part of the transmission mechanism housing,
A motor mounting portion to which one end side in the axial direction of the motor is mounted is formed, and has a bulging portion bulging upward from the left case body portion,
A mount mounting portion having a plurality of mount mounting bosses to which the mounting device is mounted is formed in front of the bulging portion on the upper surface of the left case body.
At least one of the plurality of mount attachment bosses is connected to a front wall portion that is a wall surface on the mount attachment boss side on the front surface of the bulging portion, and a hybrid vehicle drive device. The hybrid vehicle drive device according to claim 1, wherein the mount attachment boss connected to the front wall portion is connected to a front surface of the motor attachment portion in the bulge portion. The drive device for a hybrid vehicle according to claim 1 or 2, wherein the mount attachment portion has a plurality of ribs that connect the plurality of mount attachment bosses to each other. In a left side view, the plurality of ribs include one specific rib that rises at a flange portion of the left case,
The drive device for a hybrid vehicle according to claim 3, wherein the specific rib extends from the front wall portion to the mount mounting boss in a direction orthogonal to an axis of the motor in a top view. A shift-and-select shaft, a shift cover, and a shift unit that automatically shifts the shift mechanism,
An opening through which the shift and select shaft penetrates is formed in front of the mount attachment portion on the upper surface of the transmission case,
The opening is closed by the shift cover,
The drive device for a hybrid vehicle according to claim 4, wherein the mount mounting boss and the edge of the opening are connected by the specific rib. The shift unit has a base plate fixed to an upper wall of the transmission case,
The base plate is fastened to the upper surface wall and the shift cover, and extends from the shift cover to the vicinity of the front wall portion of the bulging portion across the side of the mount mounting boss. The drive device for a hybrid vehicle according to claim 5, wherein the drive device is a hybrid vehicle. The hybrid vehicle drive device according to claim 6, further comprising a support bracket that connects a front end portion of the base plate and a front side wall of the transmission case. The motor mounting portion has a fastening portion to which one end side in the axial direction of the motor is fastened at the most front,
When a vertical virtual line passing through the fastening portion is set, the mount mounting boss connected to the front surface of the motor mounting portion in the bulging portion is below the virtual line and the outer peripheral edge of the motor mounting portion. The drive device for a hybrid vehicle according to claim 2, wherein the drive device protrudes to a position on the front side and above the intersection point on the side. The base plate has a protrusion that protrudes forward of the transmission case, and an accumulator attachment portion that extends downward from the protrusion and that has an accumulator attached to the front side.
The drive device for a hybrid vehicle according to claim 7, wherein the support bracket connects the front surface of the accumulator mounting portion and the side wall of the transmission case. The support bracket passes below the accumulator mounting portion and connects the front surface of the accumulator mounting portion and the side wall of the transmission case,
The drive device for a hybrid vehicle according to claim 9, wherein the support bracket has a bent portion that bends with a large curvature below the accumulator mounting portion.

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