JP2020112246A - Lubrication structure for hybrid vehicle driving device - Google Patents

Abstract

To provide a lubrication structure for a hybrid vehicle driving device, capable of reliably lubricating a speed reduction mechanism even when the speed reduction mechanism is installed above a transmission mechanism, thus improving the reliability of the speed reduction mechanism.SOLUTION: In a driving device 4, a speed reduction mechanism 33 is installed with an input shaft 34, a first intermediate shaft 35 and a second intermediate shaft 36 separating from one another in the vertical direction so as to protrude upward relative to a transmission mechanism 40. A transmission case 5 includes an oil pipe 48 for supplying lubricating oil to the upper part of the speed reduction mechanism 33, and a guide groove for supplying the lubricating oil supplied from the oil pipe 48 into an oil distribution space in a bearing holding part.SELECTED DRAWING: Figure 4

Description

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

2. Description of the Related Art As a transmission mounted on a vehicle, there is known a transmission case that includes an oil gutter in a transmission case that accommodates an input shaft and a counter shaft that form a transmission mechanism (see Patent Document 1).

Lubrication oil is stored at the bottom of the transmission case, and the oil gutter captures the oil scraped up by the final driven gear of the differential device, and the bearings and synchronizers provided at the ends of the input shaft and counter shaft. Guide the oil to the lubricated parts such as the mechanism.

JP, 2011-137493, A

In such a conventional transmission, the oil gutter can supply the lubricating oil to the bearings and the synchronizing mechanism provided at the ends of the input shaft and the counter shaft.

However, in a hybrid vehicle power transmission device having a driving force source such as a motor other than the engine, a power transmission mechanism such as a reduction mechanism having a plurality of rotation shafts for the motor is installed above the input shaft and the counter shaft. If so, this power transmission mechanism cannot be lubricated. That is, the conventional oil gutter cannot lubricate the power transmission mechanism installed at a higher place than the speed change mechanism.

The present invention has been made in view of the above circumstances. Even when the reduction gear mechanism is installed above the transmission mechanism, the reduction gear mechanism can be reliably lubricated, and the reliability of the reduction gear mechanism is improved. It is an object of the present invention to provide a lubrication structure for a drive device for a hybrid vehicle, which can improve the property.

The present invention relates to a speed change mechanism that changes the speed of power transmitted from an internal combustion engine, a plurality of rotating shafts, and a plurality of reduction gears that are provided on the plurality of rotating shafts and reduce the rotation of a motor and transmit the reduced speed to the speed change mechanism. And a reduction gear mechanism in which the plurality of rotation shafts are vertically separated from each other so as to project upward with respect to the transmission mechanism, and a transmission case that accommodates the transmission mechanism and the reduction mechanism. The transmission case has an oil circulation space in which lubricating oil circulates, has a plurality of bearing holders that rotatably support the plurality of rotation shafts via bearings, and The bearing holder includes an upper bearing holder that supports the uppermost rotary shaft of the plurality of rotary shafts, and a lower bearing holder that is lower than the upper bearing holder. In the lubrication structure for a drive device for a hybrid vehicle, the transmission case includes an oil passage portion for supplying a lubricant oil to an upper portion of the speed reduction mechanism, and a lubricant oil supplied from the oil passage portion for the upper bearing. And a guide groove for guiding to the oil circulation space of the holding portion.

As described above, according to the present invention, even when the reduction gear mechanism is installed above the transmission mechanism, the reduction gear mechanism can be reliably lubricated, and the reliability of the reduction gear mechanism can be improved.

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 rear view of the hybrid vehicle drive device according to the 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. FIG. 4 is a left side view of a hybrid vehicle drive device according to an embodiment of the present invention, showing a state in which a cover is removed. FIG. 5 is a sectional view taken along the line VV of FIG. FIG. 6 is a perspective view of a cover of a hybrid vehicle drive device according to an embodiment of the present invention. FIG. 7 is a perspective view of an upper portion of the left case of the hybrid vehicle drive device according to the embodiment of the present invention. 8 is a sectional view taken along line VIII-VIII in FIG. FIG. 9 is a cross-sectional view taken along the line IX-IX in FIG. 4 and is a cross-sectional view with the cover attached. FIG. 10 is a sectional view taken along line XX of FIG. FIG. 11 is a vertical cross-sectional view of the hybrid vehicle drive device according to the embodiment of the present invention, in which the cover is cut by an oil passage. FIG. 12 is a perspective view of an oil gutter of a hybrid vehicle drive device according to an embodiment of the present invention. FIG. 13 is a plan view of an oil gutter of a hybrid vehicle drive device according to an embodiment of the present invention.

A lubrication structure for a hybrid vehicle drive device according to an embodiment of the present invention includes a speed change mechanism that shifts the power transmitted from an internal combustion engine, a plurality of rotating shafts, and a plurality of rotating shafts. A reduction mechanism having a plurality of reduction gear sets for decelerating rotation and transmitting the rotation to the transmission mechanism, and a plurality of rotation shafts installed vertically apart from each other so as to project upward with respect to the transmission mechanism; And a transmission case accommodating the speed reduction mechanism. The transmission case has an oil circulation space in which lubricating oil flows, and a plurality of bearings that rotatably support a plurality of rotating shafts through bearings. And a plurality of bearing holding portions, the plurality of bearing holding portions includes an upper bearing holding portion that supports the uppermost rotation shaft among the plurality of rotation shafts, and a lower bearing holding portion that is located below the upper bearing holding portion. A lubrication structure for a drive device for a hybrid vehicle, comprising: an oil passage part for supplying a lubricating oil to an upper part of a reduction mechanism; And a guide groove that guides into the oil circulation space of the bearing holder.

As a result, the lubrication structure for the hybrid vehicle drive device according to the embodiment of the present invention can reliably lubricate the reduction gear mechanism even when the reduction gear mechanism is installed above the transmission mechanism, thereby reducing the deceleration speed. The reliability of the mechanism can be improved.

A lubrication structure for a hybrid vehicle drive device according to an embodiment of the present invention will be described below with reference to the drawings.
1 to 13 are diagrams showing a lubricating structure of a hybrid vehicle drive device according to an embodiment of the present invention.

1 to 13, 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 front and back direction is the left and right direction. The height direction 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 hybrid vehicle drive unit (hereinafter, simply referred to as drive unit) 4 is installed in the engine room 2A, and the drive unit 4 has 6 forward speeds and 1 reverse speed.

As shown in FIG. 2, the drive device 4 includes a transmission case 5, and the transmission case 5 has a right case 6, a left case 7, and a cover 27 in order from the right side.

An engine 8 is connected to the right end of 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 engine 8 of this embodiment is composed of an internal combustion engine.

The left case 7 is connected to the right case 6 on the side opposite to the engine 8. That is, the left case 7 is connected to the left side of the right case 6. As shown in FIG. 2, a flange portion 6F is formed on the outer peripheral edge on the left side of the light case 6.

As shown in FIG. 2, a flange portion 7F is formed on the right outer peripheral edge of the left case 7. The flange portion 6F of the right case 6 and the flange portion 7F of the left case 7 are joint portions of the right case 6 and the left case 7, and the end faces directed in the left and right direction of each are joint surfaces (matching surfaces) that are overlapped and joined. ).

The flange portion 7F is provided with a plurality of boss portions (not shown) into which the bolts 23A (see FIG. 1) are inserted, and the flange portion 6F is formed with a plurality of boss portions (not shown) that match the boss portions of the flange portion 7F. Has been done.

In the transmission case 5, the right case 6 and the left case 7 are fastened and integrated by tightening the bolts 23A into the boss portion of the flange portion 6F and the boss portion of the flange portion 7F. The cover 27 is fastened to the left end of the left case 7 with a bolt 23B.

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, 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.

As shown 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. 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, and an input gear 16E for the fifth speed. It has 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 provided on the input shaft 11 so as to be rotatable relative to each other.

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 the forward movement, and the output gears 17A to 17F mesh with the input gears 16A to 16F constituting the same gear.

The output gears 17A and 17B are provided on the forward output shaft 12 so as to be rotatable relative to each other. 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.

The first synchronizer 18 connects the output gear 17A of the first gear to the forward output shaft 12 when the gear is shifted to the first gear by the shift operation and shifts to the second gear when the gear is shifted to the second gear by the shift operation. The output gear 17B for the speed is connected to the forward output shaft 12. As a result, 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.

The second synchronizer 19 connects the input gear 16C to the input shaft 11 when shifted to the third speed stage by the shift operation, and connects the input gear 16D to the input shaft 11 when shifted to the fourth speed stage by the shift operation. Connect to. As a result, 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.

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

The third synchronizer 20 connects the input gear 16E to the input shaft 11 when the gear is shifted to the fifth speed by the shift operation, and connects the input gear 16F to the input shaft 11 when the gear is shifted to the sixth speed by the shift operation. Connect to. As a result, 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.

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 output shaft 13 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. The fourth synchronizer 21 connects the reverse gear 22A to the reverse output shaft 13 when it is shifted to the reverse stage by the shift operation. 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. The final driven gear 15A of this embodiment constitutes the gear member of the present invention.

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 the left and right drive wheels 40L and 40R, respectively. 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 40L and 40R.

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 40.

As shown in FIG. 2, a motor 32 is installed above the left case 7. The motor 32 has a motor case 32A and a motor shaft 32B (see FIG. 3) 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.

The motor 32 generates a rotating magnetic field that rotates in the circumferential direction by supplying three-phase alternating current to the coils of the stator. The stator interlocks the generated magnetic flux with the rotor to rotate the rotor that is integral with the motor shaft 32B.

The transmission case 5 has a speed reducer case portion 25 formed by the left case 7 and the cover 27. As shown in FIGS. 1, 3, and 4, the speed reducer case portion 25 includes a case portion 26 formed by extending the left end portion of the left case 7 so as to spread upward, and an upper portion of the cover 27. There is. A reduction mechanism 33 (see FIG. 4) is housed inside the reduction gear case portion 25.

That is, the left case 7 has a case portion 26 that bulges upward at the left end portion thereof, and the opening at the left end portion of the left case 7 is enlarged upward by the case portion 26. The case portion 26 is a case portion that houses the speed reduction mechanism 33, and the speed reduction mechanism 33 is arranged on the left side thereof.

As shown in FIGS. 1 and 2, the cover 27 is joined (fastened) to the left end portion of the left case 7 by a bolt 23B and closes the opening of the left end portion of the left case 7 including the case portion 26. ing. The upper portion of the cover 27 is arranged on the left side of the reduction gear mechanism 33, and together with the case portion 26 forms a reduction gear case portion 25 that forms a housing space for the reduction gear mechanism 33 from the left and right.

As shown in FIG. 3, the speed reduction mechanism 33 is provided on the input shaft 34 connected to the motor shaft 32B of the motor 32, the first intermediate shaft 35, the second intermediate shaft 36, and the forward output shaft 12. The output gear 17D for the fourth speed is provided.

As shown in FIG. 10, a fitting groove 34a having a spline formed on the inner peripheral surface is formed on the input shaft 34, and the tip end portion of the motor shaft 32B is spline fitted to the fitting groove 34a. ..

As shown in FIG. 3, the input shaft 34 is provided with a first drive gear 34A, and 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 34A, and meshes with the first drive gear 34A. The second drive gear 35B is arranged on the left side of the first driven gear 35A, has a diameter smaller 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 arranged on the right side of the second driven gear 36A with the first driven gear 35A interposed therebetween. The third drive gear 36B is formed to have a diameter substantially the same as the diameter of the second driven gear 36A and a diameter larger than that of the output gear 17D for the fourth speed stage. It meshes with 17D.

The speed reduction mechanism 33 decelerates the power of the motor 32 and transmits it to the forward output shaft 12 by setting the diameters of the drive gears 34A, 35B, 36B and the driven gears 35A, 36A to be arbitrary reduction ratios. ..

The first drive gear 34A and the first driven gear 35A of the present embodiment constitute a first reduction gear set 37, and the second drive gear 35B and the second driven gear 36A include a second reduction gear set 38. Make up. The third drive gear 36B and the output gear 17D form a third reduction gear set 39, and these reduction gear sets 37, 38, 39 form the reduction gear set of the present invention. Further, like the first driven gear 35A and the second drive gear 35B, coaxially arranged gears of different diameters also contribute to the deceleration.

A damper 81 is arranged coaxially with the second intermediate shaft 36 at the left end of the second intermediate shaft 36. As shown in FIG. 9, the damper 81 includes an outer cylinder 82 that fits with the second driven gear 36</b>A and integrally rotates, an inner cylinder 86 that is fitted and fixed to the second intermediate shaft 36, and an outer cylinder 82. The elastic member 85 is provided between the inner cylinder 86 and the inner cylinder 86.

The outer cylinder 82 is an inner peripheral portion on the side of the second driven gear 36A in the axial direction, and is spline-fitted to the outer peripheral portions of the second driven gear 36A and the inner cylinder 86.

In the spline fitting portion 88, the outer cylinder 82 and the second driven gear 36A are spline fitted without play. That is, in the spline fitting portion 88, the fitting between the spline of the outer cylinder 82 and the spline of the second driven gear 36A has no play in the rotational direction, and the outer cylinder 82 and the second driven gear 36A rotate together. The spline is fitted.

In the spline fitting portion 89, the outer cylinder 82 and the inner cylinder 86 are spline-fitted with a relatively large play in the rotational direction so as to allow a slight relative rotation. That is, the spline fitting portion 89 regulates the relative rotation between the outer cylinder 82 and the inner cylinder 86 within a predetermined range, and the splines whose relative rotation is regulated are in contact with each other. Power is transmitted from 82 to the inner cylinder 86 without passing through the elastic member 85.

A bearing (metal bush) is arranged between the second driven gear 36A and the second intermediate shaft 36, and the second driven gear 36A is a fitting portion that is rotatably supported by the second intermediate shaft 36 in a relatively rotatable manner. Has 87. However, this relative rotation is restricted to a predetermined range by the above-mentioned spline fitting portion 89, and the second driven gear 36A deforms the elastic member 85 with respect to the second intermediate shaft 36 while varying the rotation of the engine. Relative rotation is permitted to the extent that the rotation of the gear changes due to.

The damper 81 (elastic member 85) effectively absorbs rotational fluctuations and differential rotations of different power sources of the engine 8 and the motor 32, and gears of the input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36. Suppresses the rattling noise of each other.

As shown in FIGS. 2, 4, and 9, the case portion 26 that constitutes the reduction gear case portion 25 has a peripheral wall portion 28. The peripheral wall portion 28 protrudes leftward (in a direction away from the right case 6) from a peripheral edge of a wall portion 29 of the left case 7 which will be described later, and an upper end 28a (see FIG. 4) of the peripheral wall portion 28 is higher than that of the upper wall 7B of the left case 7. It extends upward. The upper wall 7B is a portion other than the case portion 26 and is a ceiling wall portion of the left case 7 where the speed reduction mechanism 33 is not provided and the transmission mechanism 40 is arranged.

As shown in FIG. 4, when viewed from the axial direction of the input shaft 11, the peripheral wall portion 28 is formed from the front side of the reduction gear mechanism 33 to the rear side via the upper side, and surrounds the periphery of the reduction gear mechanism 33 except the lower side. I'm out.

As shown in FIG. 6, the cover 27 has a side wall portion 27A and a peripheral wall portion 27B. As shown in FIG. 8, the side wall portion 27A is a vertical wall that constitutes the left surface of the transmission case 5 and is vertical to the left-right direction, and the peripheral wall portion 27B matches the peripheral wall portion 28 of the left case 7 with the side wall portion. It projects from 27 A toward the peripheral wall portion 28, and the tip end portion 27 a in the protruding direction is joined to the tip end portion 28 b in the protruding direction of the peripheral wall portion 28.

In the description of the peripheral wall portion 28 of the left case 7, the peripheral portion of the left case of the left case 7 is continuous with the peripheral wall portion 28. In the portion, a joint surface that is continuous with the joint surface between the tip portion 27a of the peripheral wall portion 27B of the cover 27 and the tip portion 28b of the peripheral wall portion 28 is formed. At this joint surface, the cover 27 is joined (fastened) to the left end portion of the left case 7 by the bolt 23B, and the cover 27 closes the opening of the left end portion of the left case 7 including the portion other than the case portion 26.

That is, the cover 27 is fastened to the peripheral wall portion 28 by the bolts 23B (see FIG. 1) in a state where the protruding end portion 27a overlaps with the protruding end portion 28b of the peripheral wall portion 28, so that the peripheral wall portion 28 is The open end is closed.

As shown in FIGS. 2, 4, and 8, the left case 7 has a wall portion 29. The wall portion 29 is a vertical wall that is perpendicular to the axial direction (left-right direction) and is formed integrally with the left case 7. As shown in FIG. 8, the wall portion 29 is provided between the reduction mechanism 33 and the motor 32 in the axial direction of the input shaft 34, and the reduction mechanism 33 covers the wall portion 29 and the cover in the axial direction of the input shaft 34. It is installed between 27.

As shown in FIGS. 2 and 8, the wall portion 29 extends vertically from the upper wall 7B of the left case 7 and serves as a right side wall of the speed reducer case portion 25. It has an internal partition wall of the left case 7 that extends downward from the upper wall 7B of the left case 7 continuously, and a partition wall portion 29B that connects the upper wall 7B and the lower portion 28c of the left case 7 (see FIG. 4).

The wall portion 29 of this embodiment has a vertical wall portion 29A and a partition wall portion 29B, and the vertical wall portion 29A and the partition wall portion 29B are formed integrally with the left case 7. The portion located above the upper wall 7B with the upper wall 7B of the left case 7 as a boundary constitutes the vertical wall portion 29A, and the portion located below the upper wall 7B constitutes the partition wall portion 29B.

As shown in FIG. 5, the partition wall portion 29B is formed inside the left case 7 from the vicinity of the center of the rear wall of the left case 7 in the left-right direction toward the front, and as shown in FIG. The partition wall portion 29B passes above the output shaft 12 for forward movement and reaches above the input shaft 11. Further, as shown in FIG. 9, the speed reduction mechanism housing chamber 30B is composed of a space between the cover 27 and the wall portion 29.

As shown in FIG. 4, the partition wall portion 29B is not formed in the lower front position inside the left case 7, but an opening portion 29h in which the input shaft 11 and the output shaft 12 for forward movement are arranged is formed. .. As shown in FIG. 5, the input shaft 11 and the forward output shaft 12 pass through the opening 29h and extend from the light case 6 side to the speed reduction mechanism housing chamber 30B side.

The input gears 16A, 16B, 16C and the output gears 17A, 17B, 17C are installed in the gear housing chamber 30A on the light case 6 side of the partition wall 29B, and the input gears 16D, 16E, 16F, the output gear 17D, 17E and 17F and the reduction mechanism 33 are installed in the reduction mechanism housing chamber 30B on the cover 27 side of the partition wall 29B.

As shown in FIGS. 2 and 4, a motor 32 that generates a driving force for traveling is attached to the right side of the case portion 26. In order to mount the motor 32, a motor mounting portion 29C is provided on the upper portion of the vertical wall portion 29A toward the right side. The motor mounting portion 29C is formed in a disk shape having 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 boss portions 29m are provided on the outer peripheral portion of the motor mounting portion 29C, and the boss portions 29m are provided along the outer peripheral portion of the motor mounting portion 29C. A bolt 23C (see FIG. 1) is inserted into the motor mounting portion 29C, and the bolt 32C is screwed into a screw hole (not shown) formed in the motor case 32A, whereby the motor 32 is fastened to the motor mounting portion 29C.

As shown in FIG. 1, a motor connector 32C is provided at the rear of the right end of the motor 32, and a power cable (not shown) for driving the motor 32 is connected to the motor connector 32C.

A cooling water introducing pipe portion 32a and a cooling water discharge pipe portion 32b are provided above the motor 32. The cooling water introduction pipe portion 32 a introduces cooling water into the motor 32, and the cooling water discharge pipe portion 32 b discharges the cooling water that has cooled the motor 32 from the motor 32.

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 front edge of the right end of the motor 32 and the light case 6, and supports the right end of the motor 32 on the light case 6.

The rear bracket 46B connects the rear edge of the right end of the motor 32 and the light case 6, and supports the motor 32 on the light case 6. Thus, the motor 32 is connected to the motor mounting portion 29C on the left side and the light case 6 on the right side.

As shown in FIGS. 8 and 9, the wall portion 29 of the left case 7 is provided with bearing holding portions 29D, 29E, 29F. The bearing holding portions 29D and 29E extend in a tubular shape from the vertical wall portion 29A toward the cover 27 side, and are configured to include the vertical wall portion 29A. The bearing holding portion 29F extends cylindrically from the partition wall portion 29B toward the cover 27, and is configured to include the partition wall portion 29B.

The side wall portion 27A of the cover 27 is provided with cylindrical bearing holding portions 27C, 27D and 27E. The bearing holding portions 27C, 27D, 27E extend in a tubular shape from the side wall portion 27A toward the vertical wall portion 29A, and are configured to include the side wall portion 27A.

As shown in FIG. 8, the bearing holding portion 29D rotatably supports the right end portion of the input shaft 34 of the reduction mechanism 33 via a ball bearing 51A, and the bearing holding portion 27C via a ball bearing 51B. The left end of the input shaft 34 of the reduction mechanism 33 is rotatably supported. The inner diameter of the ball bearing 51A is larger than that of the ball bearing 51B.

An oil seal 55 is provided at the opening end of the bearing holding portion 29D (opening end on the motor 32 side with respect to the ball bearing 51A), and the oil seal 55 has an inner peripheral portion at an outer peripheral portion of a right end portion of the input shaft 34. Are in contact. That is, the right end portion of the input shaft 34 projects from the speed reduction mechanism housing chamber 30B, and thereby the speed reduction mechanism housing chamber 30B is sealed by the oil seal 55, and the fitting groove formed in the shaft center of the right end portion of the input shaft 34. The motor shaft 32B can be spline-fitted to 34a. The oil seal 55 of this embodiment constitutes a part of the vertical wall portion 29A.

An oil circulation space 53A through which lubricating oil circulates is formed inside the bearing holder 29D. The oil circulation space 53A is composed of a space surrounded by the bearing holding portion 29D, the oil seal 55 (the vertical wall portion 29A of the bearing holding portion 29D), and the right end portion of the input shaft 34. It is installed in the distribution space 53A.

An oil circulation space 53B through which lubricating oil circulates is formed inside the bearing holding portion 27C. The oil circulation space 53B is composed of a space surrounded by the bearing holding portion 27C and the left end portion of the input shaft 34, and the ball bearing 51B is installed in the oil circulation space 53B.

As shown in FIGS. 8 and 9, the right end portion of the first intermediate shaft 35 is rotatably supported by the bearing holding portion 29E via a needle bearing 51C, and the bearing holding portion 27D is provided with a ball bearing 51D. The left end of the first intermediate shaft 35 is rotatably supported via the intermediate shaft 35.

An oil circulation space 53C through which lubricating oil circulates is formed inside the bearing holding portion 29E. The oil circulation space 53C is composed of a space surrounded by the bearing holding portion 29E and the right end portion of the first intermediate shaft 35, and the needle bearing 51C is installed in the oil circulation space 53C.

An oil circulation space 53D through which lubricating oil flows is formed inside the bearing holding portion 27D. The oil circulation space 53D is composed of a space surrounded by the bearing holding portion 27D and the left end portion of the first intermediate shaft 35, and the ball bearing 51D is installed in the oil circulation space 53D.

As shown in FIG. 9, an oil circulation space 53E through which lubricating oil circulates is formed inside the bearing holder 29F. The oil circulation space 53E is composed of a space surrounded by the bearing holding portion 29F and the right end portion of the second intermediate shaft 36, and the ball bearing 51E is installed in the oil circulation space 53E.

An oil circulation space 53F in which lubricating oil circulates is formed inside the bearing holding portion 27E. The oil circulation space 53F is composed of a space surrounded by the bearing holding portion 27E and the left end portion of the second intermediate shaft 36, and the ball bearing 51F is installed in the oil circulation space 53F.

In this way, the input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36 are rotatable with respect to the wall portion 29 and the cover 27 by the ball bearings 51A, 51B, 51D, 51E, 51F and the needle bearing 51C. It is supported.

The ball bearings 51A, 51B, 51D, 51E, 51F and the needle bearing 51C of the present embodiment constitute the bearing of the present invention.

As shown in FIGS. 7 and 8, a semicircular recess 29M is formed between the bearing holding portion 29D and the bearing holding portion 29E, and the bearing holding portion 29E is located at the lower end of the recess 29M. ..

As shown in FIG. 8, the bearing holding portion 29D and the bearing holding portion 29E are arranged side by side in the vertical direction orthogonal to the input shaft 34. That is, the bearing holding portion 29D and the bearing holding portion 29E are formed at the same position in the axial direction of the input shaft 34. As shown in FIG. 9, the bearing holding portion 27E is installed at a position farther from the vertical wall portion 29A than the bearing holding portion 27D in the axial direction of the input shaft 34.

The bearing holding portion 29F is installed at a position farther from the cover 27 than the bearing holding portion 29E in the axial direction of the second intermediate shaft 36. The third drive gear 36B is arranged at the same position as the bearing holding portion 29E in the axial direction of the second intermediate shaft 36, and the third drive gear 36B is installed so as to go under the bearing holding portion 29E. ing.

Specifically, below the bearing holding portion 29E in the partition wall portion 29B, and on the bearing holding portion 27E side with respect to the bearing holding portion 29F, the partition wall portion 29B is cylindrically recessed toward the light case 6 side. 29G is provided, and the third drive gear 36B is housed in the gear housing portion 29G.

Here, the reason why the right end portion of the first intermediate shaft 35 is supported by the bearing holding portion 29E by the needle bearing 51C will be described.

If the third drive gear 36B is installed below the bearing holding portion 29E, the axial length of the input shaft 34 and the first intermediate shaft 35 can be shortened, and the shaft length of the input shaft 34 and the first intermediate shaft 35 can be reduced. The transmission case 5 can be miniaturized in the direction.

That is, with respect to the input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36, the ball bearings 51A and 51E and the needle bearing 51C are arranged on the same wall portion 29, but the input shaft 34, the first intermediate shaft 35, and the needle bearing 51C are arranged. By disposing the ball bearings 51A and the needle bearings 51C of the intermediate shaft 35 on the cover 27 side with respect to the positions of the ball bearings 51E of the second intermediate shaft 36, the shafts of the input shaft 34 and the first intermediate shaft 35 are The length can be shortened, and the shaft can be made advantageous for strength and rigidity.

Further, the third drive gear 36B can be arranged closer to the light case 6 side than the first driven gear 35A, and the transmission case 5 can be downsized in the axial direction. Further, the third drive gear 36B can be meshed with the output gear 17D arranged near the axial center of the forward drive output shaft 12.

However, in the case where the third drive gear 36B is installed under the bearing holding portion 29E in consideration of downsizing in the axial direction, if a ball bearing is used in place of the needle bearing 51C, the bearing becomes large. The bearing holding portion 29E for holding becomes large in the vertical direction. Then, a problem occurs in which the enlarged bearing holding portion 29E and the third drive gear 36B interfere with each other.

Therefore, the bearing holding portion 29E and the bearing holding portion 29F are separated from each other in the vertical direction, and the first intermediate shaft 35 and the second intermediate shaft 36 are installed apart from each other in the vertical direction. As a result, the transmission case 5 may increase in size in the vertical direction.

On the other hand, according to the drive device 4 of the present embodiment, the right end portion of the first intermediate shaft 35 is rotatably supported by the bearing holding portion 29E via the needle bearing 51C, whereby the bearing holding portion 29E is rotatably supported. Can be reduced (the radial dimension from the axial center of the first intermediate shaft 35).

Therefore, the bearing holder 29E and the bearing holder 29F can be installed close to each other in the vertical direction, and the first intermediate shaft 35 and the second intermediate shaft 36 can be installed close to each other in the vertical direction. As a result, it is possible to prevent the transmission case 5 from increasing in size in the vertical direction.

As shown in FIG. 5, ball bearings 50A and 50B are provided at the left end of the input shaft 11 and the left end of the forward output shaft 12, respectively, and the left end of the input shaft 11 and the left end of the forward output shaft 12 are provided. The portion projects leftward from the left case 7 and is rotatably supported by the cover 27 via ball bearings 50A and 50B, respectively.

As shown in FIG. 9, an oil passage 36 a is formed in the shaft center of the second intermediate shaft 36. The oil passage 36a extends along the axial direction of the second intermediate shaft 36 and is open at both ends.

As shown in FIGS. 1 and 4, a pump housing portion 43 is provided in the left side wall 7A of the left case 7, and an oil pump 47 is housed in the pump housing portion 43. The oil pump 47 is provided at the end of the reverse drive output shaft 13 (see FIG. 3) and is driven by the reverse drive output shaft 13.

That is, the rotation of the final driven gear 15A of the differential device 15 is transmitted to the reverse drive output shaft 13 via the final drive gear 22B, and the oil pump 47 is driven by the reverse drive output shaft 13 when the vehicle is traveling.

As shown in FIG. 4, the pump housing portion 43 is provided with a cylindrical oil discharge passage portion 44, and the oil discharge passage portion 44 has an oil discharge passage 44 a that opens inside the left case 7 therein. Have. The base end of the oil pipe 48 is inserted and attached to the opening formed at the upper end of the oil discharge passage 44a.

As shown in FIG. 4, the oil pipe 48 is routed along the inner surface of the transmission case 5 and passes behind the second intermediate shaft 36, the first intermediate shaft 35, and the input shaft 34 of the reduction mechanism 33. And extends upward, passes above the input shaft 34, and extends to the rear side of the input shaft 34.

Lubricating oil O is stored at the bottom of the left case 7, an oil strainer (not shown) is attached to the pump housing 43, and the lubricating oil at the bottom of the left case 7 is introduced into the oil pump 47 from the oil strainer. .. The oil pump 47 supplies the lubricating oil introduced into the pump housing portion 43 to the oil pipe 48 through the oil discharge passage 44a.

The oil pipe 48 discharges the lubricating oil supplied from the oil pump 47 above the input shaft 34. That is, the oil pipe 48 supplies the lubricating oil supplied from the oil pump 47 to the upper portion of the speed reduction mechanism 33. The oil pipe 48 of the present embodiment constitutes the oil passage portion of the present invention.

As shown in FIGS. 4 and 6, the oil pipe 48 extends from the rear side of the bearing holding portion 27C to the front along the peripheral wall portion 27B of the cover 27 or the peripheral wall portion 28 of the left case 7 in a curved shape. The part opens downward.

That is, the opening at the top end of the oil pipe 48 is directed to the front side of the input shaft 34 and between the input shaft 34 and the peripheral wall portion 27B or the peripheral wall portion 28. A rib 27b is provided on the inner peripheral surface of the peripheral wall portion 27B of the cover 27. The rib 27b is formed along the axial direction of the input shaft 34 and projects from the peripheral wall portion 27B toward the bearing holding portion 27C.

As shown in FIG. 7, ribs 28 d are provided on the inner peripheral surface of the peripheral wall portion 28 of the left case 7. The rib 28d is formed along the axial direction of the input shaft 34 and projects from the peripheral wall portion 28 toward the input shaft 34. The position of the rib 28d is set so as to be continuous with the rib 27b when the cover 27 is attached to the left case 7. The ribs 28d and the ribs 27b are arranged in front of the input shaft 34 and at a position higher than the axial center of the input shaft 34.

The upper opening of the oil pipe 48 is open downward, specifically, toward the ribs 27b and 28d. The lubricating oil flowing out from the tip end portion (opening) of the oil pipe 48 collides with the ribs 27b and 28d. The lubricating oil that collides with the ribs 27b and 28d is scattered in a wide area within the reduction gear case portion 25 and flows down as the flow velocity decreases.

As shown in FIG. 6, among the input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36, the bearing holding portion 27C that supports the uppermost input shaft 34 has a notch-shaped guide groove 27g. Has been formed. The guide groove 27g is a front side portion of the bearing holding portion 27C, and is formed in the range from the axial center position of the input shaft 34 to the positions of the ribs 27b and 28d in the height direction.

As shown in FIG. 10, the guide groove 27g reaches the oil circulation space 53B, passes the side of the ball bearing 51B, and communicates the oil circulation space 53B with the space around the bearing holding portion 27C. The guide groove 27g guides the lubricating oil flowing out from the oil pipe 48 to the oil circulation space 53B.

As shown in FIG. 7, among the bearing holding portions 29D, 29E, and 29F of the wall portion 29 of the left case 7, the bearing holding portion 29D that supports the uppermost input shaft 34 has a notch-shaped guide groove 29g. Has been formed. The guide groove 29g is a front side portion of the bearing holding portion 29D, and is formed in the range from the axial center position of the input shaft 34 to the positions of the ribs 27b and 28d in the height direction.

As shown in FIG. 10, the guide groove 29g reaches the oil circulation space 53A, passes the side of the ball bearing 51A, and communicates the oil circulation space 53A with the space around the bearing holding portion 29D. The guide groove 29g guides the lubricating oil flowing out from the oil pipe 48 to the oil circulation space 53A.

The input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36 of the present embodiment constitute the rotary shaft of the present invention. The bearing holders 27C and 29D form the upper bearing holder of the present invention, and the bearing holders 27D, 27E, 29E and 29F form the lower bearing holder of the present invention.

The ball bearing 51A constitutes the bearing of the present invention and the first bearing, and the ball bearing 51B constitutes the bearing of the present invention and the second bearing. The bearing holding portion 29D constitutes an upper bearing holding portion and a first upper bearing holding portion of the present invention that rotatably supports the right end portion (one end portion) of the input shaft 34 in the axial direction via the ball bearing 51A. The bearing holding portion 27C includes an upper bearing holding portion and a second upper bearing holding portion of the present invention that rotatably support the left end portion (the other end portion) of the input shaft 34 in the axial direction via a ball bearing 51B. Constitute.

As shown in FIGS. 6 and 7, at the same height position as the bearing holding portions 27C and 29D (see FIG. 4), that is, at the same height position as the input shaft 34, the oil gutter 60 is provided on the cover 27 and the wall portion 29. It is provided. An oil gutter 60 is provided in front of the input shaft 34 in the speed reducer case portion 25.

The oil gutter 60 is installed below the ribs 27b and 28d. The oil gutter 60 captures the lubricating oil that collides with the ribs 27b and 28d and scatters or flows down, and guides the lubricating oil so as to supply the lubricating oil to a portion requiring lubrication.

As shown in FIGS. 9 and 10, the oil gutter 60 has a bottom wall, a front wall that is erected upward from the front end of the bottom wall, and a rear wall that is erected upward from the rear end of the bottom wall. It is a gutter-shaped component that opens upward and extends in the axial direction of the input shaft 34. The rear wall of the oil gutter 60 has an oil outlet 60A having a narrow opening and an oil outlet 60B having an opening wider than the oil outlet 60A.

As shown in FIG. 7, the oil discharge port 60A is formed at the end portion (right end portion) on the vertical wall portion 29A side by notching the rear wall without protruding rearward, and is formed in the guide groove of the bearing holding portion 29D. It is facing 29g. The oil gutter 60 receives the lubricating oil supplied from the oil pipe 48, causes the received lubricating oil to flow out from the oil discharge port 60A toward the guide groove 29g, and introduces the lubricating oil into the oil circulation space 53A through the guide groove 29g.

The reason why the oil discharge port 60A is not projected rearward is to avoid interference with the first drive gear 34A during assembly. That is, the rear wall of the oil gutter 60 is set at a position close to the first drive gear 34A arranged behind it.

As shown in FIG. 6, the oil discharge port 60B is formed in a trough shape that protrudes rearward from the rear wall of the end portion on the side wall portion 27A side, faces the guide groove 27g of the bearing holding portion 27D, and A part is arranged in the guide groove 27g. The oil gutter 60 receives the lubricating oil supplied from the oil pipe 48, and introduces the received lubricating oil from the oil discharge port 60B into the oil circulation space 53B through the guide groove 27g.

Since the oil discharge port 60B is disposed on the left side of the first drive gear 34A, interference with the first drive gear 34A does not occur during assembly, and the oil discharge port 60B should be closer to the guide groove 27g. It projects rearward from the rear wall.

The oil outlet 60A of the present embodiment constitutes the first oil outlet of the present invention, and the oil outlet 60B constitutes the second oil outlet of the present invention. The guide groove 29g constitutes the first guide groove of the present invention, and the guide groove 27g constitutes the second guide groove of the present invention.

As shown in FIG. 7, a fitting protrusion 60a is provided at the left end portion (end portion on the side wall portion 27A side) of the oil gutter 60. As shown in FIGS. 6 and 9, the side wall portion 27A of the cover 27 is provided with a cylindrical fitting hole portion 27f that opens toward the vertical wall portion 29A, and the fitting protrusion 60a has a fitting hole portion. The part 27f is inserted and fitted. That is, the oil gutter 60 is attached to the transmission while being attached to the cover 27.

As shown in FIGS. 7 and 9, the vertical wall portion 29A of the left case 7 is provided with a rib-shaped mounting portion 29H that is continuous with the lower portion of the guide groove 29g along the front-rear direction. 29H connects the bearing holding portion 29D and the peripheral wall portion 28.

The right end portion (the end portion on the vertical wall portion 29A side) of the oil gutter 60 is mounted on the mounting portion 29H and is supported by the mounting portion 29H. Further, the right end surface of the oil gutter 60 abuts on the abutting surface 29a of the vertical wall portion 29A located on the upper side of the mounting portion 29H, so that the oil gutter 60 is prevented from moving to the right side and the fitting protrusion 60a is fitted. The hole 27f is prevented from falling out (prevention of falling out).

That is, the left end of the oil gutter 60 is held by the fitting hole 27f, and the right end of the oil gutter 60 is brought into contact with the mounting portion 29H. It is supported so as to be sandwiched between the side wall portion 27A and the vertical wall portion 29A of the left case 7. The side wall portion 27A, the fitting hole portion 27f, the vertical wall portion 29A and the mounting portion 29H of the present embodiment constitute the oil gutter support portion of the present invention.

As shown in FIG. 9, an oil passage 35 a is formed in the axial center of the first intermediate shaft 35. The oil passage 35a extends along the axial direction of the first intermediate shaft 35 and is open at both ends.

A guide plate 61 is provided on the left end of the first intermediate shaft 35. The guide plate 61 has a disc-shaped plate portion 61A having a hole formed in the center, and a cylindrical pipe portion 61B joined to the center of the plate portion 61A.

The plate portion 61A is fixed to the side wall portion 27A of the cover 27, and by contacting the plurality of protrusions 27t (see FIG. 8) protruding from the side wall portion 27A toward the first intermediate shaft 35, the plate portion 61A is removed. A space is formed on the left side between the side wall portion 27A and the side wall portion 27A to form an oil circulation space.

The pipe portion 61B projects from the center of the plate portion 61A toward the right side and is perpendicular to the plate portion 61A and is inserted into the oil passage 35a. The pipe portion 61B uses the center hole of the disc-shaped plate portion 61A to communicate the oil circulation space 53D with the oil passage 35a.

As shown in FIG. 9, the outer race 51n of the ball bearing 51D is fixed to the bearing holding portion 27D by a circlip 63 and is positioned in the axial direction of the first intermediate shaft 35. The inner race 51m of the ball bearing 51D is fixed to the first intermediate shaft 35 by a circlip 64, and is positioned on the first intermediate shaft 35 in the axial direction of the first intermediate shaft 35.

As a result, the first intermediate shaft 35 is attached to the transmission case 5 while being axially positioned. That is, the first intermediate shaft 35 is positioned with respect to the cover 27 by the ball bearing 51D. This positioning is important because the other end (right end) of the first intermediate shaft 35 is rotatably supported by the wall 29 by the needle bearing 51C that cannot be positioned in the axial direction.

A cylindrical circlip working hole portion 27H is formed in the side wall portion 27A of the cover 27 near the bearing holding portion 27D in the front upper part of the ball bearing 51D. The circlip working hole 27H is closed by a lid 65. When the lid 65 is removed from the circlip working hole 27H, the speed reduction mechanism housing chamber 30B communicates with the outside, and the speed reduction mechanism housing chamber 30B can be accessed from the outside.

With the lid 65 removed from the circlip working hole 27H, a tool (not shown) is inserted into the speed reduction mechanism housing chamber 30B from the circlip working hole 27H to expand the diameter of the circlip 63 from the outside. This makes it possible to fix the ball bearing 51D attached to the first intermediate shaft 35 to the bearing holder 27D. That is, the first intermediate shaft 35 can be attached to the bearing holder 27D.

As shown in FIG. 11, an oil passage 27d is formed in the side wall portion 27A of the cover 27.
The oil passage 27d extends obliquely leftward and downward from the oil circulation space 53B of the bearing holding portion 27C, and the lower end in the extending direction communicates with the oil circulation space 53D.

The oil passage 27d is a hole formed by drilling so that the cutting tool (drill) used in the drilling does not interfere with the tubular portion (the portion where the ball bearing 51B fits) of the bearing holding portion 27C. , Is processed by inclining to the lower left.

In the left-right direction, the ball bearing 51D is arranged on the left side of the ball bearing 51B, the bearing holding portion 27D is arranged on the left side of the bearing holding portion 27C, and the oil distribution space 53D is arranged on the left side of the oil distribution space 53B. Since it is arranged in the above, it is possible to minimize the bulging portion of the oil circulation space 53D that bulges to the left for communicating with the oil passage 27d.

That is, the oil passage 27d communicates the oil circulation space 53B of the bearing holding portion 27C and the oil circulation space 53D of the bearing holding portion 27D. Then, the lubricating oil supplied from the oil circulation space 53B to the oil circulation space 53D through the oil passage 27d is introduced from the oil circulation space 53D through the pipe portion 61B into the oil passage 35a of the first intermediate shaft 35. The oil passage 27d of the present embodiment constitutes the communication passage of the present invention.

As shown in FIG. 4, the transmission case 5 is provided with an oil gutter 66. The oil gutter 66 is above the output shaft 12 for forward movement and has the same height as the second intermediate shaft 36 located at the lowest position among the input shaft 34, the first intermediate shaft 35, and the second intermediate shaft 36. It is installed in the position.

As shown in FIG. 5, the oil gutter 66 extends leftward from the edge of the left case 7 on the right case 6 side and reaches the cover 27.

The oil gutter 66 includes a first oil gutter portion 67, a second oil gutter portion 68, and a third oil gutter portion 69.

The first oil gutter portion 67 is installed in the gear accommodating chamber 30A and extends from the edge of the left case 7 on the right case 6 side to the partition wall portion 29B along the inner surface of the rear wall of the left case 7.

The second oil gutter section 68 is installed in the gear accommodating chamber 30A. The second oil gutter portion 68 extends along the partition wall portion 29B from the left end of the first oil gutter portion 67 to the upper side of the forward output shaft 12 so as to be bent with respect to the first oil gutter portion 67. The right side of 29B extends in the front-rear direction.

The third oil gutter portion 69 passes below the partition wall portion 29B and is installed in front of the second intermediate shaft 36 from the gear accommodating chamber 30A to the speed reduction mechanism accommodating chamber 30B. The third oil gutter portion 69 extends from the front end of the second oil gutter portion 68 along the forward output shaft 12 to the cover 27 side so as to bend with respect to the second oil gutter portion 68. It is extended.

In FIG. 12 and FIG. 13, the first oil gutter portion 67 has a bottom wall 67A and side walls 67B and 67C extending upward from the front and rear edges of the bottom wall 67A. A trough-shaped first oil passage 70 is formed.

The second oil gutter portion 68 has a bottom wall 68A continuous with the bottom wall 67A, and side walls 68B, 68C extending upward from the left and right edges of the bottom wall 68A and continuous with the side walls 67B, 67C. A second oil passage 71 is formed by the side walls 68B and 68C and has a gutter shape that opens upward and communicates with the first oil passage 70.

The third oil gutter portion 69 has a bottom wall 69A that is continuous with the bottom wall 68A, and side walls 69B and 69C that extend upward from the front and rear edges of the bottom wall 69A and that are continuous with the side walls 68B and 68C. Further, the side walls 69B and 69C form a third oil passage 72 which is gutter-shaped and opens to the upper side and communicates with the second oil passage 71.

The right end portion of the first oil gutter portion 67 is disposed above and in front of the final driven gear 15A, and the right end portion of the first oil gutter portion 67 is provided with an oil introduction portion 67D that opens rearward. Then, the lubricating oil scraped up by the final driven gear 15A is introduced into the oil introducing portion 67D (first oil gutter portion 67).

The lubricating oil introduced from the oil introducing portion 67D into the first oil gutter portion 67 flows through the inside of the first oil passage 70 toward the second oil passage 71. Lubricating oil that flows in the first oil passage 70 toward the second oil passage 71 is guided from the first oil passage 70 to the third oil passage 72 through the second oil passage 71.

A tubular pipe portion 68D is provided on a left side wall 68C of the second oil gutter portion 68. The pipe portion 68D projects leftward from the side wall 68C so that its axis extends in the left-right direction, and is configured to allow the lubricating oil in the second oil passage 71 to flow out through the internal hole of the pipe portion 68D.

As shown in FIG. 9, the pipe portion 68D penetrates the partition wall portion 29B and is inserted into the oil passage 36a of the second intermediate shaft 36. The second oil passage 71 communicates with the oil passage 36a through the pipe portion 68D, and the lubricating oil flowing through the second oil passage 71 is introduced into the oil passage 36a through the pipe portion 68D.

As described above, the oil gutter 66 includes the pipe portion 68D that supplies the lubricating oil to the oil passage 36a formed in the axial center of the second intermediate shaft 36 located at the lowest position.

In FIGS. 12 and 13, side walls 69B and 69C of the third oil gutter portion 69 are provided with oil receiving portions 69D and 69E, respectively. The oil receiving portions 69D and 69E have a shape for increasing the amount of lubricating oil in the third oil gutter portion 69, and take in the lubricating oil flowing down from the reduction mechanism housing chamber 30B into the oil gutter 66. The oil receiving portions 69D and 69E extend obliquely upward from the side walls 69B and 69C so as to spread in the front-rear direction and project upward, and are formed with a predetermined dimension in the axial direction of the input shaft 11 as shown in FIG. Has been done.

As shown in FIG. 4, the third oil gutter portion 69 is arranged below the front peripheral wall portion 28. The upper end of the oil receiving portion 69D is located below the upper wall 7B located in front of the peripheral wall portion 28, is installed so as to approach the inner surface (lower surface) of the upper wall 7B, and is scattered from the reduction mechanism 33. The lubricating oil flowing down along the peripheral wall portion 28 is received and guided to the third oil passage 72.

Further, as shown in FIG. 6, a cylindrical circlip working hole portion 27H is formed in the side wall portion 27A of the cover 27 so as to project into the reduction mechanism housing chamber 30B. Lubricating oil is collected on the peripheral wall 28 side on the circular upper surface of the portion 27H, and the lubricating oil can be collected efficiently.

The oil receiving portion 69E is installed on the second intermediate shaft 36 side with respect to the oil receiving portion 69D, bulges rearward from the side wall 69B toward the reduction mechanism 33, and has an outer diameter of the second driven gear 36A. It extends so as to incline upward along the.

Specifically, the oil receiving portion 69E is inclined from the side wall 69C toward the meshing portion of the second drive gear 35B and the second driven gear 36A, and is inclined from the second drive gear 35B and the second driven gear 36A. The scattered oil is received and guided to the third oil passage 72.

The oil receiving portion 69D of the present embodiment constitutes the first oil receiving portion of the present invention, and the oil receiving portion 69E constitutes the second oil receiving portion of the present invention.

As shown in FIGS. 12 and 13, oil supply portions 69F and 69G are provided at the left end portion of the third oil gutter portion 69.

As shown in FIG. 5, the oil supply unit 69F supplies the lubricating oil from the third oil passage 72 to the ball bearing 50A provided on the input shaft 11. The oil supply unit 69G supplies the lubricating oil from the third oil passage 72 to the ball bearing 50B provided on the advancing output shaft 12. Although not shown, the oil supply portions 69F and 69G are inserted into the lubrication grooves communicating with the bearing holding portions for the ball bearings 50A and 50B formed in the cover 27.

As shown in FIGS. 12 and 13, notches 69b and 69c are formed in the side walls 69B and 69C of the third oil gutter portion 69, and the notches 69b and 69c are different from the oil receiving portions 69D and 69E. It is located on the second oil gutter portion 68 side.

The lower ends of the notches 69b and 69c are located below the upper ends of the side walls 69B and 69C. As a result, a part of the lubricating oil flowing through the third oil passage 72 flows out from the cutouts 69b and 69c.

As shown in FIG. 5, the notches 69b and 69c are located between the second synchronizer 19 and the third synchronizer 20 in the axial direction of the input shaft 11, and are discharged from the notches 69b and 69c. The lubricating oil is used as the second synchronizing device 19, the third synchronizing device 20, the meshing portion of the third drive gear 36B and the output gear 17D, the meshing portion of the input gear 16D and the output gear 17D, and the input gear 16E and the output gear. It is supplied to the meshing portion or the like of 17E. That is, the notches 69b and 69c are formed above the portion requiring lubrication, and are arranged adjacent to the right sides of the oil receiving portions 69D and 69E.

As described above, the oil gutter 66 of the present embodiment captures both the oil scraped up by the final driven gear 15A and the oil scattered and flowing down from the reduction mechanism 33.

As shown in FIGS. 12 and 13, a fitting protrusion 68a is provided on the side wall 68C of the second oil gutter portion 68 in front of the pipe portion 68D so as to project leftward. The fitting protrusion 68a is fitted into a fitting hole formed in the partition wall 29B of the left case 7. Further, the oil gutter 66 is provided with an extension portion 68E extending rearward at a connecting portion between the first oil gutter portion 67 and the second oil gutter portion 68.

The extension portion 68E is provided with a fitting protrusion 68b having the same shape as the fitting protrusion 68a so as to project leftward, and the fitting protrusion 68b is fitted into a fitting hole formed in the partition wall portion 29B. Has been done. The oil gutter 66 is attached to the partition wall portion 29B of the left case 7 before and after the pipe portion 68D by the fitting protrusion 68a and the fitting protrusion 68b.

That is, the oil gutter 66 is attached to the transmission case 5 by inserting the oil supply portions 69F and 69G into the lubricating groove and the fitting protrusions 68a and 68b into the fitting holes, and projects forward from the side wall 67B. The parts come into contact with the transmission case 5 to prevent them from falling off (the movement of the oil gutter 66 to the right is suppressed).

Next, the operation will be described.
As shown by a dotted arrow in FIG. 4 which is a left side view, when the vehicle 1 travels forward, in the reduction mechanism 33, the input shaft 34 is counterclockwise, the first intermediate shaft 35 is clockwise, and the second intermediate shaft 35 is clockwise. The shaft 36 rotates counterclockwise. In the speed change mechanism 40, the input shaft 11 rotates counterclockwise and the forward output shaft 12 rotates clockwise. As a result, the final driven gear 15A rotates counterclockwise.

The lubricating oil supplied from the oil pump 47 to the oil pipe 48 through the oil discharge passage 44a is discharged from the tip end portion of the oil pipe 48 arranged in the upper portion of the reduction mechanism housing chamber 30B. This lubricating oil collides with the ribs 27b and 28d of the cover 27 and the like, the flow velocity is reduced and is scattered into the reduction mechanism housing chamber 30B, and then falls on each gear of the reduction mechanism 33 and is installed below the ribs 27b and 28d. The oil gutter 60 is captured.

As shown in FIG. 10, the lubricating oil captured by the oil gutter 60 flows through the oil gutter 60 and flows out from the oil discharge port 60A. The lubricating oil flowing out from the oil discharge port 60A is guided by the mounting portion 29H and the guide groove 29g and introduced into the oil circulation space 53A.

The lubricating oil O1 introduced into the oil distribution space 53A is supplied to the oil seal 55, passes through the ball bearing 51A to lubricate the ball bearing 51A, and then is discharged from the oil distribution space 53A.

As shown in FIG. 8, the lubricating oil O1 discharged from the oil circulation space 53A has a meshing portion between the first drive gear 34A and the first driven gear 35A arranged laterally below the oil circulation space 53A. As it lubricates and flows downward, as shown by the lubricating oil O2 in FIGS. 7 and 8, it is guided along the recess 29M into the oil circulation space 53C of the bearing holder 29E.

As shown in FIG. 8, the lubricating oil O2 introduced into the oil circulation space 53C is the needle bearing 51C, the outer peripheral surface of the first intermediate shaft 35 that is the rolling surface of the needle bearing 51C, and the inner diameter surface of the bearing holding portion 29E. Is lubricated and flows downward from the oil circulation space 53C.

As shown in FIG. 10, the lubricating oil captured by the oil gutter 60 is guided from the oil discharge port 60B to the guide groove 27g and introduced into the oil circulation space 53B, as indicated by the lubricating oil O3. The lubricating oil O3 introduced into the oil distribution space 53B partially passes through the ball bearing 51B to lubricate the ball bearing 51B, and then is discharged downward from the oil distribution space 53B.

As shown in FIG. 8, the lubricating oil O3 discharged downward from the oil circulation space 53B meshes with the first drive gear 34A and the first driven gear 35A arranged laterally below the oil circulation space 53B. Lubricate parts.

On the other hand, the lubricating oil introduced into the oil distribution space 53B is partially introduced into the oil distribution space 53D from the oil distribution space 53B through the oil passage 27d, as indicated by the lubricating oil O4 in FIG.

The lubricating oil O4 guided to the oil circulation space 53D is introduced into the oil passage 35a of the first intermediate shaft 35 from the oil circulation space 53D through the pipe portion 61B of the guide plate 61, as indicated by the lubricating oil O5 in FIG. To be done.

The lubricating oil O5 introduced into the oil passage 35a is introduced into the oil distribution space 53C of the bearing holder 29E, lubricates the needle bearing 51C installed in the bearing holder 29E, and is then discharged downward from the oil distribution space 53C. It

A part of the lubricating oil O5 introduced into the oil passage 35a is supplied to the ball bearing 51D from between the inner peripheral surface of the first intermediate shaft 35 and the pipe portion 61B (see the lubricating oil O6 in FIG. 9). As a result, the ball bearing 51D is lubricated.

As shown in FIG. 9, the lubricating oil O6 that lubricates the ball bearing 51D is discharged downward from the oil circulation space 53D. A meshing portion of the second driven gear 36A and the second drive gear 35B is located on the side of the lower portion of the bearing holding portion 27D.

As a result, the meshing portion between the second driven gear 36A and the second drive gear 35B is lubricated by the lubricating oil O6 discharged from the bearing holding portion 27D.

In the oil gutter 60 of this embodiment, the opening width of the oil discharge port 60B is wider than the opening width of the oil discharge port 60A, so that more lubricating oil can be supplied to the oil circulation space 53B of the bearing holding portion 27C. Then, a large amount of lubricating oil can be made to flow into the oil passage 27d, and a large amount of lubricating oil can be supplied to the oil circulation space 53D.

Therefore, a sufficient amount of oil can be supplied from the oil passage 27d to the ball bearing 51D that supports the left end portion of the first intermediate shaft 35. In addition to this, the oil passage 35a of the first intermediate shaft 35 is used to be installed separately on the opposite side of the first intermediate shaft 35, and the bearing holding portion 29E and the right end portion of the first intermediate shaft 35 are separated from each other. A sufficient amount of lubricating oil can be supplied also to the needle bearing 51C installed in a small gap between them.

On the other hand, the lubricating oil O stored in the bottom portion of the left case 7 is scraped up by the final driven gear 15A, and as shown by the lubricating oil O7 in FIG. 5, from the oil introduction portion 67D of the first oil gutter portion 67 to the first oil introduction portion 67D. Is introduced into the oil passage 70.

The lubricating oil O7 introduced into the first oil passage 70 is guided from the first oil passage 70 to the third oil passage 72 through the second oil passage 71.

As shown in FIG. 9, a cylindrical pipe portion 68D is provided on the side wall 68C of the second oil gutter portion 68 that constitutes the second oil passage 71, and the pipe portion 68D passes through the oil circulation space 53E. Then, it is inserted into the oil passage 36a of the second intermediate shaft 36.

As a result, as shown in FIG. 9, the lubricating oil O7 flowing through the second oil passage 71 is supplied to the oil passage 36a of the second intermediate shaft 36 through the pipe portion 68D, as indicated by the lubricating oil O8.

A part of the lubricating oil O8 supplied to the oil passage 36a is discharged from the oil passage 36a to the oil circulation space 53E as indicated by the lubricating oil O9, and after lubricating the ball bearing 51E installed in the bearing holding portion 29F. , Is discharged from the oil distribution space 53E.

The lubricating oil O9 discharged downward from the oil circulation space 53E flows along the gear accommodating portion 29G and lubricates the meshing portion between the third drive gear 36B and the output gear 17D for the fourth speed.

The lubricating oil O8 flowing through the oil passage 36a is introduced into the oil circulation space 53F as indicated by the lubricating oil O10. The lubricating oil O10 introduced into the oil circulation space 53F is discharged from the oil circulation space 53F after lubricating the ball bearing 51F.

On the other hand, the side walls 69B and 69C of the third oil gutter portion 69 of the oil gutter 66 are provided with oil receiving portions 69D and 69E extending upward from the side walls 69B and 69C, respectively.

As shown in FIG. 4, a peripheral wall portion 28 is arranged in front of the input shaft 34 and the first intermediate shaft 35, and receives the lubricating oil scattered as the gear rotates. The oil receiving portion 69D is installed below the peripheral wall portion 28, and the oil receiving portion 69D scatters from the first drive gear 34A, the first driven gear 35A, and the second drive gear 35B of the reduction mechanism 33. The lubricating oil O11 flowing down along the peripheral wall portion 28 is received and guided to the third oil passage 72.

The oil receiving portion 69E is installed on the second intermediate shaft 36 side with respect to the oil receiving portion 69D, and is inclined from the side wall 69C toward the reduction mechanism 33. Further, the second drive gear 35B and the second driven gear 36A are rotated in the direction in which their meshing position approaches the upper end of the oil receiving portion 69E.

As a result, the oil receiving portion 69E receives the lubricating oil O12 scattered from the meshing portion of the second drive gear 35B and the second driven gear 36A and guides it to the third oil passage 72.

The lubricating oil flowing through the third oil passage 72 is supplied to the ball bearing 50A provided on the input shaft 11 from the oil supply portion 69F provided at the left end portion of the third oil gutter portion 69. As a result, the ball bearing 50A is lubricated with the oil.

The lubricating oil flowing through the third oil passage 72 is supplied from the oil supply portion 69G provided at the left end portion of the third oil gutter portion 69 to the ball bearing 50B provided at the forward output shaft 12.

As a result, the ball bearing 50B is lubricated with oil. Notches 69b and 69c are formed in the third oil passage 72, and the lubricating oil flowing out from the notches 69b and 69c is supplied to a synchronizing device, a gear, a gear meshing portion, and the like arranged therebelow. ..

The lubricating oil discharged from the oil gutters 60 and 66 finally returns to the bottom of the left case 7, and joins with the lubricating oil O stored in the bottom of the left case 7.

As described above, according to the drive device 4 of the present embodiment, the transmission case 5 has the oil circulation space 53A formed therein from the oil circulation space 53A through which the lubricating oil circulates, and the input shaft 34, the first intermediate shaft 35, and The second intermediate shaft 36 has cylindrical bearing holding portions 27C, 27D, 27E, 29D, 29E, 29F that rotatably support the second intermediate shaft 36 via ball bearings 51A, 51B, 51D, 51E, 51F and a needle bearing 51C.

The speed reduction mechanism 33 has an input shaft 34, a first intermediate shaft 35, and a second intermediate shaft 36 that are vertically separated from each other so as to project upward with respect to the transmission mechanism 40.

The transmission case 5 includes an oil pipe 48 that supplies lubricating oil to the upper portion of the reduction mechanism 33, and a guide groove 29g that supplies oil supplied from the oil pipe 48 to the oil distribution space 53A inside the bearing holding portion 29D. It has a guide groove 27g for supplying the lubricating oil supplied from the oil pipe 48 to the oil circulation space 53B inside the bearing holding portion 27C.

Accordingly, even when the reduction gear mechanism 33 is installed above the transmission mechanism 40, the ball bearings 51A and 51B that support the input shaft 34 of the reduction gear mechanism 33 can be reliably lubricated. As a result, the durability of the ball bearings 51A and 51B can be improved, and the reliability of the speed reduction mechanism 33 can be improved.

Further, according to the drive device 4 of the present embodiment, the transmission case 5 communicates the oil distribution space 53B of the bearing holding portion 27C and the oil distribution space 53D of the bearing holding portion 27D so that the oil distribution space 53B allows oil distribution. It has an oil passage 27d for supplying lubricating oil to the space 53D.

As a result, the lubricating oil can be reliably supplied from the oil circulation space 53B of the bearing holder 27C to the oil circulation space 53D of the bearing holder 27D, and the ball bearing 51D installed in the bearing holder 27D can be reliably lubricated.

Further, according to the drive device 4 of the present embodiment, the transmission case 5 is provided with the oil gutter 60, and the oil gutter 60 receives the lubricating oil supplied from the oil pipe 48 and guides it to the guide grooves 27g, 29g.

As a result, the lubricating oil discharged from the oil pipe 48 can be captured by the oil gutter 60, and a larger amount of lubricating oil can be supplied to the necessary portion by the oil gutter 60. Therefore, more oil can be supplied from the oil gutter 60 through the guide grooves 27g and 29g to the oil distribution space 53A of the bearing holder 29D and the oil distribution space 53B of the bearing holder 27C.

Therefore, the ball bearings 51A and 51B can be lubricated more reliably. As a result, the durability of the ball bearings 51A and 51B can be further improved, and the reliability of the speed reduction mechanism 33 can be further improved.

Further, according to the drive device 4 of the present embodiment, the oil gutter 60 has the oil discharge port 60A and the oil discharge port 60B. In addition to this, the guide groove 29g guides the lubricating oil discharged from the oil discharge port 60A to the oil circulation space 53A of the bearing holding portion 29D, and the guide groove 27g guides the lubricating oil discharged from the oil discharge port 60B. The bearing holder 27C is guided to the oil circulation space 53B.

Accordingly, a large amount of lubricating oil can be simultaneously supplied to the ball bearings 51A and 51B provided at both ends of the input shaft 34 by one oil gutter 60, and the ball bearings 51A and 51B can be lubricated more effectively.

As described above, in the drive device 4 of the present embodiment, since only one oil gutter 60 that supplies oil to the ball bearings 51A and 51B needs to be provided, the number of parts of the oil gutter can be reduced and the ball bearings 51A and 51B can be reduced. Lubrication performance can be improved.

Further, according to the drive device 4 of the present embodiment, the transmission case 5 is supported by the side wall portion 27A of the cover 27 and the vertical wall portion 29A of the left case 7 so as to sandwich the oil gutter 60.

That is, the oil gutter 60 is prevented from coming off by contacting the mounting surface 29a of the vertical wall portion 29A with the left end portion held by the fitting hole portion 27f and the right end portion supported by the mounting portion 29H. The cover 27 is attached so as to be sandwiched between the side wall portion 27A of the cover 27 and the vertical wall portion 29A of the left case 7.

As a result, by utilizing the shape of the transmission case 5, the oil gutter 60 can be supported and the oil gutter 60 can be easily prevented from falling off.

In addition to this, by adopting a configuration in which the oil gutter 60 is sandwiched between the side wall portion 27A of the cover 27 and the vertical wall portion 29A of the left case 7, the oil gutter 60 can be easily assembled to the transmission case 5, and the oil gutter 60 can be easily assembled. Can be easily assembled in a short time. As a result, the productivity of the drive device 4 can be improved.

Although the lubricating oil is supplied to the upper portion of the speed reduction mechanism 33 by the oil pipe 48 in the drive device 4 of the present embodiment, the present invention is not limited to this. As an example, an oil passage may be formed in the cover 27 or the left case 7, and the lubricating oil discharged from the oil pump 47 may be supplied to the upper part of the reduction mechanism 33 through the oil passage.

Further, in the drive unit 4 of the present embodiment, the bearing is composed of a ball bearing or a needle bearing, but the bearing is not limited to the ball bearing.

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 covered by the following claims.

1... Vehicle, 4... Drive device (drive device for hybrid vehicle), 5... Transmission case, 8... Engine (internal combustion engine), 11... Input shaft (transmission mechanism), 12 ... output shaft for forward movement (transmission mechanism), 16A, 16B, 16C, 16D, 16E, 16F... input gear (transmission mechanism), 17A, 17B, 17C, 17D, 17E, 17F... output gear ( Transmission mechanism), 27A... Side wall portion (oil gutter support portion), 27C... Bearing holding portion (upper bearing holding portion, second upper bearing holding portion), 27D, 27E... Bearing holding portion (lower side) Bearing holding portion), 27d... Oil passage (communication passage), 27f... Fitting hole portion (oil gutter support portion), 27g... Guide groove (second guide groove), 28... Peripheral wall portion , 29A... Vertical wall portion (oil gutter support portion), 29D... Bearing holding portion (upper bearing holding portion, first upper bearing holding portion), 29E, 29F... Bearing holding portion (lower bearing holding portion) Part), 29H... mounting part (oil gutter support part), 29g... guide groove (first guide groove), 32... motor, 33... reduction mechanism, 34... input shaft ( Rotating shaft), 35... first intermediate shaft (rotating shaft), 36... second intermediate shaft (rotating shaft), 37... first reduction gear set (reduction gear set), 38. .. Second reduction gear set (reduction gear set), 39... Third reduction gear set (reduction gear set), 40... Transmission mechanism, 48... Oil pipe (oil passage portion), 51A ... ball bearing (bearing, first bearing), 51B... ball bearing (bearing, second bearing), 51C... needle bearing (bearing), 51D, 51E, 51F... ball bearing ( Bearings), 53A, 53B, 53C, 53D, 53E, 53F... Oil distribution space, 60... Oil gutter, 60A... Oil discharge port (first oil discharge port), 60B... Oil discharge port (Second oil outlet)

Claims (5)

A speed change mechanism for changing the power transmitted from the internal combustion engine,
A plurality of rotation shafts, and a plurality of reduction gear sets provided on the plurality of rotation shafts for decelerating the rotation of the motor and transmitting the rotations to the speed change mechanism, and to project upward with respect to the speed change mechanism. A reduction mechanism in which the plurality of rotating shafts are installed separately in the vertical direction,
A transmission case housing the transmission mechanism and the reduction mechanism,
The transmission case has an oil flow space through which lubricating oil flows, and has a plurality of bearing holders that rotatably support the plurality of rotary shafts via bearings.
Among the plurality of rotation shafts, the plurality of bearing holding portions include an upper bearing holding portion that supports the uppermost rotation shaft and a lower bearing holding portion that is located below the upper bearing holding portion. A lubrication structure of a hybrid vehicle drive device including:
The transmission case has an oil passage portion that supplies lubricating oil to the upper portion of the reduction mechanism, and a guide groove that guides the lubricating oil supplied from the oil passage portion to the oil circulation space of the upper bearing holding portion. A lubrication structure for a drive device for a hybrid vehicle, comprising: The transmission case communicates with the oil flow space of the upper bearing holding part and the oil flow space of the lower bearing holding part, and extends from the oil flow space of the upper bearing holding part to the oil of the lower bearing holding part. The lubrication structure for a drive device for a hybrid vehicle according to claim 1, further comprising a communication passage for supplying lubricating oil to the distribution space. An oil gutter is provided in the transmission case,
The lubricating structure for a hybrid vehicle drive device according to claim 1 or 2, wherein the oil gutter receives the lubricating oil supplied from the oil passage portion and guides the lubricating oil to the guide groove. The bearing has a first bearing and a second bearing,
The upper bearing holding portion includes a first upper bearing holding portion that rotatably supports one end portion of the rotating shaft in the axial direction via the first bearing, and another end portion of the rotating shaft in the axial direction. A second upper bearing holding portion that rotatably supports the second bearing,
The oil gutter has a first oil outlet and a second oil outlet,
The guide groove includes a first guide groove for guiding the lubricating oil discharged from the first oil discharge port to the oil circulation space of the first upper bearing holder, and a second oil discharge port. The lubrication structure for a hybrid vehicle drive device according to claim 3, further comprising a second guide groove that guides the discharged lubricating oil to the oil circulation space of the second upper bearing holding portion. The lubrication structure for a hybrid vehicle drive device according to claim 3 or 4, wherein the transmission case includes an oil gutter support portion that supports the oil gutter so as to sandwich the oil gutter.

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