JP2020128800A - Power transmission device - Google Patents

Abstract

To downsize a power transmission device, which adopts a clutch for a transmission mechanism, in a rotating axis direction.SOLUTION: The power transmission device comprises a transmission mechanism 3 which has: a planetary gear group 4 provided with first to third rotating elements; an engagement element; and a cylindrical section. The engagement element is a clutch 47 provided with a drive plate 471 and a driven plate 472. The cylindrical section is an outer wall section 481 of a clutch drum 48. The clutch drum 48 is rotated integrally with a sun gear 41 (the first rotating element). The clutch drum 48 is also connected to a ring gear 42 (the second rotating element) through the clutch 47. The drive plate 471 and the driven plate 472 of the clutch 47 are arranged between the planetary gear group 4 and the outer wall section 481 of the clutch drum 48 in a radial direction.SELECTED DRAWING: Figure 3

Description

The present invention relates to a power transmission device.

Patent Document 1 discloses a stepped speed change mechanism that switches between a low speed stage and a high speed stage by a meshing engagement device.

JP, 2018-118616, A

It is conceivable to use a multi-plate friction clutch instead of the meshing engagement device.
At this time, it is required to downsize the stepped speed change mechanism having a multi-plate friction clutch.

The present invention has a speed change mechanism having a planetary gear set having first to third rotating elements, an engagement element, and a tubular portion,
The tubular portion rotates integrally with the first rotating element,
The tubular portion is connected to the second rotating element via the engaging element,
The drive plate and the driven plate of the engagement element are a power transmission device configured to be sandwiched in the radial direction between the planetary gear set and the tubular portion.

According to the present invention, it is possible to reduce the size of a stepped speed change mechanism having a multi-plate friction clutch.

It is a figure explaining the power transmission device concerning 1st Embodiment. It is an enlarged view of the range from the motor of a power transmission device to a counter gear. It is a figure explaining the speed change mechanism of a power transmission device. It is an enlarged view of a differential gear of a power transmission device. It is a figure explaining the power transmission device concerning 2nd Embodiment. It is a figure explaining the speed change mechanism of the power transmission device concerning a 2nd embodiment. FIG. 3 is a skeleton diagram schematically showing the structure of a speed change mechanism. It is a skeleton figure explaining the modification of a speed change mechanism. It is a skeleton figure explaining the modification of a speed change mechanism. It is a skeleton figure explaining the modification of a speed change mechanism. It is a skeleton figure explaining the modification of a speed change mechanism.

[First Embodiment]
Hereinafter, the first embodiment of the present invention will be described.
FIG. 1 is a diagram illustrating a power transmission device 1 according to the first embodiment.
FIG. 2 is an enlarged view around the counter gear 5 of the power transmission device 1.

As shown in FIG. 1, the power transmission device 1 includes a motor 2, a speed change mechanism 3, a counter gear 5 for transmitting output rotation of the speed change mechanism 3 to a differential device 6, and a drive shaft 8 (8A) for transmitting the transmitted rotation. , 8B).

In the power transmission device 1, a transmission mechanism 3, a counter gear 5, a differential device 6, and a drive shaft 8 (8A, 8B) are provided along the transmission path of the output rotation of the motor 2.
The output rotation of the motor 2 is speed-changed by the speed change mechanism 3, then decelerated by the counter gear 5, and transmitted to the differential device 6. In the differential device 6, the transmitted rotation is transmitted to the left and right drive wheels (not shown) of the vehicle in which the power transmission device 1 is mounted via the drive shaft 8 (8A, 8B). In FIG. 1, the drive shaft 8A is connected to the left wheel of the vehicle equipped with the power transmission device 1 so as to be able to rotate, and the drive shaft 8B is connected to the right wheel to be able to rotate.

Here, the speed change mechanism 3 is connected downstream of the motor 2, the counter gear 5 is connected downstream of the speed change mechanism 3, and the differential device 6 is connected downstream of the counter gear 5. The drive shafts 8 (8A, 8B) are connected downstream of the differential device 6.

In the present embodiment, the motor housing 10, the outer cover 11, the inner cover 12, the outer case 13, and the inner case 14 form a main body case 9 of the power transmission device 1.
The motor housing 10, the outer cover 11, and the inner cover 12 form a case (first case member) of the motor 2.
The outer case 13 and the inner case 14 form a case (second case member) that houses the counter gear 5 and the differential device 6.

Here, on the inner diameter side of the motor housing 10, the space Sa formed between the outer cover 11 and the inner cover 12 is a motor chamber that houses the motor 2.

As shown in FIG. 2, the space formed between the outer case 13 and the inner case 14 is divided by the partition wall 142 provided in the inner case 14 into a space Sb for accommodating the counter gear 5 and the differential device 6, and a gear shift. It is partitioned into a space Sc that houses the mechanism 3.
Therefore, the space Sb is a first gear chamber that houses the counter gear 5 and the differential device 6, and the space Sc is a second gear chamber that houses the speed change mechanism 3.

As shown in FIG. 1, the motor 2 has a cylindrical motor shaft 20, a cylindrical rotor core 21 externally fitted to the motor shaft 20, and a stator core 25 that surrounds the outer periphery of the rotor core 21 at predetermined intervals. ing.

The motor shaft 20 is a tubular member having an insertion hole 200 for the drive shaft 8B, and the motor shaft 20 is externally inserted on the drive shaft 8B.
In the insertion hole 200 of the motor shaft 20, the coupling portion 201 on the one end 20a side in the longitudinal direction and the supported portion 202 on the other end 20b side are intermediate between the coupling portion 201 and the supported portion 202 in the rotation axis X direction. The inner diameter is larger than the area 203.

The inner circumference of the connecting portion 201 and the inner circumference of the supported portion 202 are supported by needle bearings NB and NB externally inserted on the drive shaft 8B.
In this state, the motor shaft 20 is provided so as to be rotatable relative to the drive shaft 8B.

As shown in FIG. 2, in the motor shaft 20, a bearing B1 is externally attached and fixed to the outer periphery of a position away from the one end 20a to the other end 20b side (left side in the drawing).
The bearing B1 is restricted from moving to the rotor core 21 side (left side in the drawing) by a step portion 205 provided on the outer periphery of the motor shaft 20.

The outer periphery of the bearing B1 is supported by the motor support portion 121 located on the inner diameter side of the inner cover 12. In this state, the bearing B1 is restricted from moving to the side opposite to the rotor core 21 (right side in the figure) by the step portion 121a provided on the inner circumference of the motor support portion 121.
Therefore, in the motor shaft 20, the outer periphery of the motor shaft 20 at a position away from the rotor core 21 toward the one end 20a side is rotatably supported by the cylindrical motor support portion 121 of the inner cover 12 via the bearing B1.

As shown in FIG. 1, in the motor shaft 20, a bearing B1 is externally attached and fixed to the outer periphery of the supported portion 202 on the side of the other end 20b.
The other end 20b side of the motor shaft 20 is rotatably supported by a cylindrical motor support portion 111 of the outer cover 11 via a bearing B1.

In the motor housing 10 that surrounds the outer periphery of the rotor core 21 at a predetermined interval, seal rings SL, SL are provided at one end 10a and the other end 10b in the rotation axis X direction. One end 10a of the motor housing 10 is joined to the annular joint portion 120 of the inner cover 12 without a gap by a seal ring SL provided on the one end 10a.
The other end 10b of the motor housing 10 is joined to the annular joint portion 110 of the outer cover 11 without a gap by a seal ring SL provided on the other end 10b.

In this state, the motor support portion 121 on the inner cover 12 side is arranged on the inner diameter side of the coil end 253a, which will be described later, facing the one end portion 21a of the rotor core 21 with a gap in the rotation axis X direction.
The motor support portion 111 on the outer cover 11 side is arranged on the inner diameter side of a coil end 253b, which will be described later, and faces the other end portion 21b of the rotor core 21 with a gap in the rotation axis X direction.

Inside the motor housing 10, the rotor core 21 is arranged between the motor support portion 111 on the outer cover 11 side and the motor support portion 121 on the inner cover 12 side.

The rotor core 21 is formed by laminating a plurality of silicon steel plates, and each of the silicon steel plates is externally attached to the motor shaft 20 in a state in which the relative rotation with the motor shaft 20 is restricted.
The silicon steel plate has a ring shape when viewed from the rotation axis X direction of the motor shaft 20, and on the outer peripheral side of the silicon steel plate, N and S pole magnets (not shown) alternate in the circumferential direction around the rotation axis X. It is provided in.

One end 21 a of the rotor core 21 in the direction of the rotation axis X is positioned by the large diameter portion 204 of the motor shaft 20. The other end 21b of the rotor core 21 is positioned by a stopper 23 press-fitted into the motor shaft 20.

The stator core 25 is formed by laminating a plurality of electromagnetic steel plates, and each of the electromagnetic steel plates is a ring-shaped yoke portion 251 fixed to the inner periphery of the motor housing 10, and the rotor core from the inner periphery of the yoke portion 251. The tooth portion 252 protruding toward the 21st side is provided.
In the present embodiment, the stator core 25 having a configuration in which the winding wire 253 is distributed and wound over a plurality of teeth portions 252 is adopted. The stator core 25 includes coil ends 253a and 253b protruding in the rotation axis X direction. The length in the direction of the rotation axis X is longer than that of the rotor core 21.

A stator core may be adopted in which windings are concentratedly wound on each of the plurality of teeth 252 protruding toward the rotor core 21 side.

As shown in FIG. 2, one end 20a of the motor shaft 20 penetrates the motor support portion 121 of the inner cover 12 toward the transmission mechanism 3 (right side in the drawing) and is located in the space Sc.

A lip seal RS is installed on the inner circumference of the motor support 121.
The lip seal RS seals the gap between the inner circumference of the motor support portion 121 and the outer circumference of the motor shaft 20.
The lip seal RS partitions the space Sa on the inner diameter side of the motor housing 10 from the space Sc on the inner diameter side of the inner case 14, and is provided to prevent the oil OL from entering the space Sa from the space Sc side. Has been.

FIG. 3 is a diagram illustrating the transmission mechanism 3.
The transmission mechanism 3 is arranged in the space Sc.
The speed change mechanism 3 includes a planetary gear set 4, a clutch 47, and a band brake 49.
The planetary gear set 4 includes a sun gear 41, a ring gear 42, a pinion gear 43, a pinion shaft 44, and a carrier 45.
The components of the planetary gear set 4 (sun gear 41, ring gear 42, pinion gear 43, pinion shaft 44, carrier 45) are provided on the inner diameter side of the outer wall portion 481 of the clutch drum 48.
The clutch 47 includes a drive plate 471 (inner diameter side friction plate) spline-fitted to the outer circumference of the ring gear 42 and a driven plate 472 (outer diameter side friction plate) spline-fitted to the inner circumference of the outer wall portion 481 of the clutch drum 48. And a piston 475 movably provided in the rotation axis direction.

The clutch drum 48 has an outer wall portion 481, a disc portion 480, an inner wall portion 482, and a connecting portion 483.
The outer wall portion 481 has a cylindrical shape that surrounds the rotation axis X at predetermined intervals. The disc portion 480 extends from the end portion of the outer wall portion 481 on the differential device 6 side (right side in the drawing) toward the inner diameter side. A region on the inner diameter side of the disk portion 480 is a recess 480a that is recessed in a direction away from the planetary gear set 4.

The inner wall portion 482 is formed in a cylindrical shape that surrounds the rotation axis X at a predetermined interval. The inner wall portion 482 extends from the inner diameter side end of the disc portion 480 to the planetary gear set 4 side (left side in the drawing), and the tip of the inner wall portion 482 is located at the meshing portion between the sun gear 41 and the pinion gear 43. , Are opposed to each other with a gap in the rotation axis X direction.

The connecting portion 483 has a cylindrical shape that surrounds the rotation axis X at predetermined intervals. A longitudinal end portion 483a of the connecting portion 483 is connected to the inner periphery of the inner wall portion 482 on the distal end side.
The connecting portion 483 linearly extends on the extension of the connecting portion 201 of the motor shaft 20 in the direction approaching the motor 2 (left direction in the drawing). The tip 483b of the connecting portion 483 is located closer to the motor 2 than the outer wall portion 481.

The clutch drum 48 including the outer wall portion 481, the disc portion 480, the inner wall portion 482, and the connecting portion 483 is provided with the opening facing the motor 2 side, and is located on the inner diameter side. The sun gear 41 of the planetary gear set 4 is spline-fitted to the outer periphery of the 483.

In the planetary gear set 4, the ring gear 42 is located on the outer diameter side of the sun gear 41. The ring gear 42 includes a peripheral wall portion 421 that surrounds the outer periphery of the sun gear 41 at a predetermined interval, a disc portion 422 that extends from the end portion of the peripheral wall portion 421 on the motor 2 side to the inner diameter side, and an end portion of the disc portion 422 on the inner diameter side. And a connecting portion 423 extending from the side to the motor 2 side.
The connecting portion 423 has a ring shape surrounding the rotation axis X at a predetermined interval, and the connecting portion 201 on the one end 20 a side of the motor shaft 20 is spline-fitted to the inner circumference of the connecting portion 423.

In the peripheral wall portion 421 located on the outer diameter side of the connecting portion 423, the outer circumference of the pinion gear 43 meshes with the inner circumference of the region located on the outer diameter side of the sun gear 41.
The pinion gear 43 meshes with the inner circumference of the peripheral wall portion 421 on the ring gear 42 side and the outer circumference of the sun gear 41.

The pinion shaft 44 that supports the pinion gear 43 is provided in a direction along an axis line X3 that is parallel to the rotation axis X. One end and the other end of the pinion shaft 44 are supported by a pair of side plate portions 451 and 452 that form the carrier 45.
The side plate portions 451 and 452 are provided in parallel with each other with an interval in the direction of the axis X3.

One side plate portion 452 located on the motor 2 side extends to the rotation axis X side with respect to the other side plate portion 451. A tubular connecting portion 453 that surrounds the rotation axis X at a predetermined interval is integrally formed at an end portion 452a on the inner diameter side of the side plate portion 452.
The connecting portion 453 extends along the rotating shaft X (inner diameter side) with respect to the connecting portion 201 of the motor shaft 20 in a direction away from the motor 2 along the rotating shaft X.

The connecting portion 453 is provided across the inner diameter side of the sun gear 41 from the motor 2 side to the differential device 6 side, and the connecting portion 453 is the inner diameter side of the inner wall portion 482 of the clutch drum 48 and connects the hollow shaft 50. The inner circumference of the portion 501 is spline-fitted.

The driven plate 472 of the clutch 47 is spline-fitted to the inner circumference of the outer wall portion 481 of the clutch drum 48. The drive plate 471 of the clutch 47 is spline-fitted to the outer periphery of the peripheral wall portion 421 of the ring gear 42.
A drive plate 471 and a driven plate 472 are alternately provided between the peripheral wall portion 421 of the ring gear 42 and the outer wall portion 481 of the clutch drum 48.

The retaining plate 473 positioned by the snap ring 474 is located on the motor 2 side in the region where the drive plate 471 and the driven plate 472 are alternately provided, and the piston 475 of the piston 475 is disposed on the differential device 6 side. The pressing portion 475a is located.

The base portion 475b on the inner diameter side of the piston 475 is provided at a position farther from the planetary gear set 4 than the pressing portion 475a on the outer diameter side. The base portion 475b on the inner diameter side of the piston 475 is inserted into the recess portion 480a on the inner diameter side of the disc portions 480 that are adjacent in the rotation axis X direction.

A spring Sp supported by a spring retainer 476 is in pressure contact with the surface of the base portion 475b on the motor 2 side (left side in the drawing) from the rotation axis X direction.
The piston 475 is biased toward the differential device 6 side by the biasing force applied from the spring Sp.

In the clutch drum 48, a protrusion 484 that protrudes toward the differential device 6 side is provided at the boundary between the recess 480a and the inner wall 482. The protruding portion 484 is inserted into the inner circumference of the first support portion 141 of the bearing B3. An oil OL supply path 141a is opened in the inner periphery of the first support portion 141.
An oil passage 484a for guiding the oil OL supplied from the first support portion 141 side into the recess 480a of the clutch drum 48 is provided inside the protruding portion 484.

The oil OL supplied via the oil passage 484a is supplied to the oil chamber between the base portion 475b of the piston 475 and the recess 480a to displace the piston 475 to the motor 2 side.
When the piston 475 is displaced toward the motor 2 side, the drive plate 471 and the driven plate 472 of the clutch 47 are gripped between the pressing portion 475a of the piston 475 and the retaining plate 473.
As a result, the relative rotation between the ring gear 42 in which the drive plate 471 is spline-fitted and the clutch drum 48 in which the driven plate 472 is spline-fitted is regulated in accordance with the pressure of the supplied oil OL, and finally. Relative rotation is restricted.

Furthermore, a band brake 49 is wound around the outer wall 481 of the clutch drum 48. When the winding radius of the band brake 49 is narrowed by an actuator (not shown), the rotation of the clutch drum 48 about the rotation axis X is restricted.

In the speed change mechanism 3, the planetary gear set 4 and the clutch 47 are located on the inner diameter side of the band brake 49. The band brake 49, the planetary gear set 4, and the clutch 47 overlap in the radial direction of the rotation axis X, and when viewed from the radial outside of the rotation axis X, the band brake 49, the planetary gear set 4, and The clutch 47 is provided in an overlapping positional relationship.

In the speed change mechanism 3 of the present embodiment, the ring gear 42 of the planetary gear set 4 serves as the output rotation input portion of the motor 2, and the carrier 45 serves as the input rotation output portion.

The speed change mechanism 3 is designed to switch between a low speed stage and a high speed stage by changing the combination of engagement/release of the clutch 47 and operation of the band brake 49.
The speed change mechanism 3 can switch between a low speed stage and a high speed stage.

In the speed change mechanism 3, the low speed stage is realized under the following condition (a), and the high speed stage is realized under the condition (b).
(A) Band brake 49: actuated, clutch 47: released (b) Band brake 49: non-actuated, clutch 47: engaged Here, the speed change mechanism 3 is a two-speed speed change mechanism, and the low speed stage and the high speed stage have the same rotation. Direction (forward or reverse). It is possible to switch between forward and reverse by rotating the motor 2 forward and backward.

The output rotation of the motor 2 is output to the hollow shaft 50 to which the connecting portion 453 of the carrier 45 is connected, after being changed in speed by the speed change mechanism 3.

As shown in FIG. 2, in the hollow shaft 50 to which the rotation changed in speed by the speed change mechanism 3 is input, one end 50a in the longitudinal direction is provided in a bearing B5 supporting the support portion 601 of the differential case 60, and a gap in the rotation axis X direction. It is provided with a space. The other end 50b of the hollow shaft 50 serves as a connecting portion 501 with the planetary gear set 4.
The outer periphery of the coupling portion 501 is supported by a needle bearing NB that is interposed between the outer periphery of the coupling portion 501 and the inner wall portion 482 of the clutch drum 48.

A gear portion 502 is integrally formed on the outer periphery of the hollow shaft 50 on the one end 50a side. Bearings B3 and B3 are externally inserted on both sides of the gear portion 502.
The bearing B3 on the one end 50a side is supported by the supporting portion 151 on the inner case 14 side, and the bearing B3 on the other end 50b side is supported by the first supporting portion 141 on the inner case 14.

The large-diameter gear 52 of the counter gear 5 meshes with the outer periphery of the gear portion 502 so that rotation can be transmitted. In the counter gear 5, the large diameter gear 52 is spline-fitted to the outer circumference of the hollow cylindrical shaft portion 51.

A bearing B4 is externally fitted to one end 51a and the other end 51b of the hollow shaft 51 in the longitudinal direction. The bearing B4 externally inserted into the one end portion 51a of the hollow shaft portion 51 is inserted into the cylindrical second support portion 135 of the outer case 13. One end 51a of the hollow shaft portion 51 is rotatably supported by the second support portion 135 of the outer case 13 via the bearing B4.

The bearing B4 externally inserted into the other end portion 51b of the hollow shaft portion 51 is inserted into the cylindrical second support portion 145 of the inner case 14. The other end portion 51b of the hollow shaft portion 51 is rotatably supported by the second support portion 145 of the inner case 14 via the bearing B4.

In this state, the hollow shaft portion 51 of the counter gear 5 is provided along the axis line X1 parallel to the rotation axis X.
In the hollow shaft portion 51, a park gear 53 is provided adjacent to the one end portion 51a side (left side in the drawing) when viewed from the large diameter gear 52.

In the hollow shaft portion 51, a small-diameter gear portion 511 is provided at a position away from the park gear 53 on the one end portion 51a side (right side in the drawing). The small-diameter gear portion 511 is formed integrally with the hollow shaft portion 51 and has an outer diameter R2 smaller than the outer diameter R1 of the large-diameter gear 52 (see FIG. 4: R1>R2).

The small-diameter gear portion 511 meshes with a final gear FG fixed to the differential case 60 of the differential gear 6 so as to be capable of transmitting rotation.
FIG. 4 is an enlarged view around the differential device 6 of the power transmission device 1.

In the power transmission device 1, the output rotation of the motor 2 is input to the hollow shaft 50 via the speed change mechanism 3. The rotation input to the hollow shaft 50 is input to the counter gear 5 via the large diameter gear 52 meshed with the gear portion 502.

In the counter gear 5, the large diameter gear 52 and the park gear 53 are spline-fitted to the outer circumference of the hollow shaft portion 51, and the small diameter gear portion 511 is formed integrally with the hollow shaft portion 51.
Therefore, when the output rotation of the motor 2 is input to the counter gear 5, the park gear 53 and the small diameter gear portion 511 rotate together with the large diameter gear 52 around the axis line X1.

Then, since the final gear FG with which the small-diameter gear portion 511 meshes so that rotation can be transmitted is fixed to the differential case 60, the differential case 60 rotates about the rotation axis X in conjunction with the rotation of the counter gear 5 about the axis X1. To do.

Here, in the counter gear 5, the outer diameter R2 of the small-diameter gear portion 511 is smaller than the outer diameter R1 of the large-diameter gear 52 (see FIG. 4).
Then, in the counter gear 5, the large-diameter gear 52 serves as an input portion for the rotation transmitted from the motor 2 side, and the small-diameter gear portion 511 serves as an output portion for the transmitted rotation.
Then, the rotation input to the counter gear 5 is greatly reduced and then output to the differential case 60.

As shown in FIG. 4, the differential case 60 is formed in a hollow shape in which the shaft 61, the bevel gears 62A and 62B, and the side gears 63A and 63B are housed.
In the differential case 60, tubular support parts 601 and 602 are provided on both sides in the direction of the rotation axis X (left and right direction in the figure). The support portions 601 and 602 extend along the rotation axis X in the direction away from the shaft 61.

A bearing B5 is externally inserted in the support portion 602 of the differential case 60. The bearing B5 externally inserted in the support portion 602 is held by the ring-shaped first support portion 131 of the outer case 13.

The drive shaft 8A penetrating the opening 130 of the outer case 13 is inserted into the support portion 602 from the direction of the rotation axis X, and the drive shaft 8A is rotatably supported by the support portion 602.
A lip seal RS is fixed to the inner circumference of the opening 130, and a lip portion (not shown) of the lip seal RS elastically contacts the outer circumference of the drive shaft 8A to open the outer circumference of the drive shaft 8A. The gap with the inner circumference of the portion 130 is sealed.

A bearing B5 is externally inserted in the support portion 601 of the differential case 60.
The support portion 601 of the differential case 60 is rotatably supported by the support portion 151 of the support member 15 fixed to the inner case 14 via the bearing B5.
The bearing B<b>5 externally inserted in the support portion 601 is held by the ring-shaped support portion 151 of the support member 15.

As shown in FIG. 1, the support member 15 has a tubular portion 152 extending from the outer periphery of the support portion 151 to the motor 2 side (right side in the figure) and an opening on the distal end side of the tubular portion 152 over the entire circumference. And a flange portion 153 surrounding it. The flange portion 153 of the support member 15 is fixed to the first support portion 141 of the inner case 14 by a bolt B penetrating the flange portion 153.

The support portion 601 of the differential case 60 is rotatably supported by the support member 15 via the bearing B2. In this embodiment, the support member 15 is fixed to the inner case 14. Therefore, the support portion 601 of the differential case 60 is supported by the inner case 14 that is the fixed-side member via the bearing B2 and the support member 15.

As shown in FIG. 1, the drive shaft 8B penetrating the opening 114 of the outer cover 11 is inserted into the support portion 601 of the differential case 60 from the direction of the rotation axis X.
The drive shaft 8B is provided across the inner diameter side of the motor shaft 20 of the motor 2, the planetary gear set 4, and the hollow shaft 50 in the rotation axis X direction, and the tip end side of the drive shaft 8B is the support portion 601. It is rotatably supported.

A lip seal RS is fixed to the inner periphery of the opening 114 of the outer cover 11, and a lip portion (not shown) of the lip seal RS elastically contacts the outer periphery of the drive shaft 8B, whereby the drive shaft 8B. The gap between the outer periphery of the opening and the inner periphery of the opening 114 is sealed.

As shown in FIG. 4, inside the differential case 60, the side gears 63A and 63B are spline-fitted to the outer periphery of the tip end portion of the drive shaft 8 (8A, 8B), and the side gears 63A and 63B and the drive shaft 8 (8A , 8B) are connected integrally with each other about the rotation axis X.

The differential case 60 is provided with shaft holes 60a and 60b penetrating in a direction orthogonal to the rotation axis X at positions symmetrical with respect to the rotation axis X.
The shaft holes 60a and 60b are located on the axis line Y orthogonal to the rotation axis X, and the shaft 61 is inserted into the shaft holes 60a and 60b.

The shaft 61 is fixed to the differential case 60 by a pin P, and the shaft 61 is prohibited from rotating about the axis Y.

The shaft 61 is located between the side gears 63A and 63B in the differential case 60, and is arranged along the axis Y.

Bevel gears 62A and 62B are externally inserted and rotatably supported on a shaft 61 in the differential case 60.
Two bevel gears 62A and 62B are provided at intervals in the longitudinal direction of the shaft 61 (axial direction of the axis Y), and the bevel gears 62A and 62B are arranged with their teeth facing each other. ing.
In the shaft 61, the bevel gears 62A and 62B are provided such that the shaft centers of the bevel gears 62A and 62B coincide with the shaft center of the shaft 61.
In the differential case 60, side gears 63A and 63B are located on both sides of the bevel gears 62A and 62B in the axial direction of the rotation axis X.
The side gears 63A and 63B are provided at two intervals in the axial direction of the rotation axis X with their teeth facing each other, and the bevel gears 62A and 62B and the side gears 63A and 63B are mutually provided. It is assembled with the teeth engaged.

The operation of the power transmission device 1 having such a configuration will be described.
As shown in FIG. 1, in the power transmission device 1, the transmission mechanism 3, the counter gear 5, the differential device 6, and the drive shaft 8 (8A, 8B) are provided along the transmission path of the output rotation of the motor 2. , Are provided.

As shown in FIG. 2, when the rotor core 21 rotates about the rotation axis X by driving the motor 2, the rotation is input to the transmission mechanism 3 via the motor shaft 20 that rotates integrally with the rotor core 21.
In the speed change mechanism 3, the ring gear 42 of the planetary gear set 4 serves as a rotation input unit and a rotation output unit to which the carrier 45 is input.

In the speed change mechanism 3, the state in which the rotation of the clutch drum 48 is restricted by the operation of the band brake 49 is smaller than the state in which the ring gear 42 and the clutch drum 48 rotate together by the operation of the clutch 47. The gear ratio is set to be high.
That is, in the speed change mechanism 3, the low speed stage is realized while the band brake 49 is operating, and the high speed stage is realized while the clutch 47 is operating.

Therefore, the rotation input to the speed change mechanism 3 is output to the hollow shaft 50 from the connecting portion 453 of the carrier 45 after the speed is changed. The rotation input to the hollow shaft 50 is input to the counter gear 5 via the large diameter gear 52 meshed with the gear portion 502 of the hollow shaft 50.

In the counter gear 5, the large diameter gear 52 meshing with the gear portion 502 of the hollow shaft 50 serves as an input portion of the output rotation of the motor 2, and the small diameter gear portion 511 meshing with the final gear FG of the differential case 60 receives the input. It is the output part of the rotated rotation.

Here, in the counter gear 5, the outer diameter R2 of the small-diameter gear portion 511 is smaller than the outer diameter R1 of the large-diameter gear 52 (see FIG. 4).
Therefore, the rotation input to the counter gear 5 is greatly decelerated and then output to the differential case 60 (differential device 6) via the final gear FG with which the small diameter gear portion 511 meshes.

Then, the drive shaft 8 (8A, 8B) is rotated about the rotation axis X by rotating the differential case 60 about the rotation axis X by the input rotation. As a result, the output rotation of the motor 2 is transmitted to the left and right drive wheels (not shown) of the vehicle in which the power transmission device 1 is mounted.

Here, in the power transmission device 1, the speed change mechanism 3 including the planetary gear set 4, the clutch 47, and the band brake 49 is adopted, the output rotation of the motor 2 is changed by the speed change mechanism 3, and the counter gear 5 is used. Have been communicated to.

Here, in the case of the meshing type engagement device, the shift speed is switched using the transmission switching member. Therefore, if the spline phase of the shift speed before the change and the spline phase of the shift speed after the change do not match, the shift speed cannot be switched. This is because the transmission switching member cannot engage with the spline of the change-destination shift speed.

On the other hand, the speed change mechanism 3 of the present embodiment is designed to switch between the low speed stage and the high speed stage by changing the combination of engagement/release of the clutch 47 and operation of the band brake 49. .. Therefore, unlike the meshing type engagement device, it is possible to prevent a situation in which the shift speed cannot be switched.

Further, in the speed change mechanism 3, the band brake 49 overlaps with the clutch 47 and the planetary gear set 4 in the radial direction of the rotation axis X. , The clutch 47 and the planetary gear set 4 are provided so as to overlap with each other. Therefore, in the power transmission device 1, the length of the portion of the speed change mechanism 3 in the rotation axis X direction can be shortened.

In the power transmission device 1, the motor shaft 20 of the rotor core 21, the counter gear 5, and the drive shaft 8 (8A, 8B) are arranged in series on the transmission path of the output rotation of the motor 2.
The drive shaft 8B is provided so as to penetrate the inner diameter side of the motor shaft 20 in the rotation axis X direction, and the drive shaft 8B and the motor shaft 20 are provided so as to be relatively rotatable on the common rotation axis X. ing.
Therefore, as compared with a power transmission device in which a motor shaft, a counter gear, and a drive shaft are provided on different rotary shafts that are parallel to each other, that is, a so-called three-axis type power transmission device, the radial direction of the rotary shaft is larger. The size can be reduced.

In the present embodiment, of the three rotating elements (sun gear 41, ring gear 42, carrier 45) included in the planetary gear set 4, the sun gear 41 is the first rotating element and the ring gear 42 is the second rotating element. Was illustrated.
The present invention is not limited to this aspect.
The first rotating element may be any one of the sun gear 41, the carrier 45, and the ring gear 42, and the second rotating element and the third rotating element may be any of the remaining two.

As described above, the power transmission device 1 according to this embodiment has the following configuration.
(1) The power transmission device 1 is
The transmission mechanism 3 includes a planetary gear set 4 having first to third rotating elements, an engaging element, and a tubular portion.
The engagement element is a clutch 47 (multi-plate friction clutch) having a drive plate 471 and a driven plate 472.
The tubular portion is the outer wall portion 481 of the clutch drum 48, and the clutch drum 48 rotates integrally with the sun gear 41 (first rotating element).
The clutch drum 48 is connected to the ring gear 42 (second rotating element) via the clutch 47.
The drive plate 471 and the driven plate 472 of the clutch 47 are radially sandwiched between the planetary gear set 4 and the outer wall portion 481 of the clutch drum 48.

According to this structure, the planetary gear set 4, the drive plate 471 and the driven plate 472, and the outer wall portion 481 of the clutch drum 48 are arranged to overlap each other in the radial direction of the rotation axis X of the power transmission device 1. .. When viewed from the radial direction of the rotation axis X, the planetary gear set 4, the drive plate 471 and the driven plate 472, and the outer wall portion 481 are arranged so as to overlap each other.
As a result, the speed change mechanism 3 can be shortened in the rotation axis X direction, and the power transmission device 1 in which the multi-plate friction clutch is adopted in the speed change mechanism 3 can be provided without increasing the size in the rotation axis X direction.

Here, the first rotating element may be any one of the sun gear 41, the carrier 45, and the ring gear 42, and the second rotating element and the third rotating element may each be the remaining two. ..
An outer wall portion 481 (cylindrical portion) pulled out to the outer peripheral side of the planetary gear set 4 is provided on the clutch drum 48 that rotates integrally with the first rotating element, and the outer wall portion 481, the planetary gear set 4, and the clutch 47 are provided. And are arranged so as to overlap each other in the radial direction of the rotation axis X. As a result, the speed change mechanism 3 can be shortened in the direction of the rotation axis X.

The power transmission device 1 has the following configuration.
(2) The clutch drum 48 is
An outer wall portion 481 arranged on the outer diameter side of the planetary gear set 4,
An inner wall portion 482 arranged on the inner diameter side of the planetary gear set 4,
It has a disc portion 480 which is arranged laterally of the planetary gear set 4 in the direction of the rotation axis X and which connects the outer wall portion 481 and the inner wall portion 482.
The outer wall portion 481, the inner wall portion 482, and the planetary gear set 4 are provided so as to overlap each other when viewed in the radial direction of the rotation axis X.

With this configuration, the transmission mechanism 3 can be shortened in the rotation axis X direction.

(3) The clutch drum 48 has a disc portion 480 (wall portion) that connects the outer wall portion 481 and the first rotating element.
The disk portion 480 is arranged laterally of the planetary gear set 4 in the rotation axis X direction.
The piston 475 of the clutch 47 is disposed between the planetary gear set 4 and the disc portion 480 so as to be sandwiched in the axial direction.
The disc portion 480 constitutes a part of a piston hydraulic chamber that supplies hydraulic pressure to the piston 475.

By using the disc portion 480 (wall portion) of the clutch drum 48 as the wall of the hydraulic chamber of the piston 475, it is not necessary to separately prepare a member for forming the hydraulic chamber between the piston 475 and the piston 475.
As a result, it is possible to further reduce the size of the transmission mechanism 3 in the rotation axis X direction.

(4) The first rotating element is the sun gear 41.
The outer wall portion 481 of the clutch drum 48 is arranged on the outer periphery of the ring gear 42.

With this configuration, the disk portion 480 of the clutch drum 48 when viewed from the direction of the rotation axis X has the sun gear 41 located closest to the inner diameter side in the radial direction of the rotation axis X and the ring gear located closest to the outer diameter side. It is provided in a range straddling 42.
This maximizes the range of the disk portion 480 in the radial direction of the rotation axis X. Therefore, when the hydraulic chamber of the piston 475 is formed using the disk portion 480, the size of the hydraulic chamber in the radial direction of the rotation axis X is increased. Can be maximized.

Thereby, when the volume of the hydraulic chamber of the piston 475 is set to a predetermined volume, it is possible to shorten the rotation axis X direction.

(5) The outer wall portion 481 of the clutch drum 48 is connected to the fixed element (inner case 14) provided on the outer peripheral side of the planetary gear set 4 via the band brake 49 (brake element).

The body case 9 (case member) of the power transmission device 1 is often used as a fixing element to which the band brake 49 is fixed.
Here, when fixing is performed on the inner peripheral side of the planetary gear set 4, it is necessary to extend the fixing element to the inner peripheral side.
By setting the clutch drum 48 so as to rotate integrally with the sun gear 41, the outer wall portion 481 of the clutch drum 48 can be placed on the outer peripheral side where the main body case 9 is located.
As a result, the inner case 14 (case member) of the main body case 9 and the outer wall portion 481 of the clutch drum 48 can be arranged close to each other in the radial direction of the rotation axis X.
As a result, the band brake 49 wound around the outer wall portion 481 can be fixed to the inner case 14 located near the outer wall portion 481 and can function as a brake element. Therefore, the brake element can be compactly arranged.
In addition, in this embodiment, the band brake 49 is illustrated as an example of the position of the brake element. The braking element is not limited to this aspect only. For example, in addition to the band brake, it is possible to use a multi-plate friction fastening element, a meshing engagement element, or the like.

(6) The first rotating element is the ring gear 42.
The inner wall portion 482 of the clutch drum 48 is arranged on the inner circumference of the sun gear 41.

According to this structure, the disc portion 480 of the clutch drum 48 is pulled in the radial direction of the rotary shaft X from the sun gear 41 located at the innermost circumference in the radial direction of the rotary shaft X to the ring gear 42 located at the outermost circumference. It is rotated and placed.
Accordingly, when the hydraulic chamber of the piston 475 is formed by using the disc portion 480, the size of the hydraulic chamber in the radial direction of the rotation axis X can be maximized.
Therefore, when the volume of the hydraulic chamber of the piston 475 is set to the predetermined volume, the rotation axis X direction can be shortened.

The power transmission device 1 according to the present embodiment has the following configuration.
(6) The power transmission device 1 has a motor 2.
The speed change mechanism 3 is connected downstream of the motor 2.

Since the output torque of the motor 2 tends to decrease as the rotation speed increases, the configuration that can reduce friction at the high speed stage is particularly suitable for a power transmission device using a motor as a drive source.

[Second Embodiment]
Next, a second embodiment of the present invention will be described.
In the following description, the same parts as those in the first embodiment will be designated by the same reference numerals, and the description thereof will be omitted as much as possible.

FIG. 5 is a diagram illustrating a power transmission device 1A according to the second embodiment.
FIG. 6 is an enlarged view around the transmission mechanism 3A of the power transmission device 1A.

As shown in FIG. 5, the power transmission device 1A includes a motor 2, a transmission mechanism 3A, a counter gear 5 that transmits the output rotation of the transmission mechanism 3A to a differential device 6, and a transmitted rotation of the drive shaft 8 (8A). , 8B).

In the power transmission device 1A, a speed change mechanism 3A, a counter gear 5, a differential device 6, and a drive shaft 8 (8A, 8B) are provided along the transmission path of the output rotation of the motor 2.
The output rotation of the motor 2 is speed-changed by the speed change mechanism 3A, then decelerated by the counter gear 5, and transmitted to the differential device 6. In the differential device 6, the transmitted rotation is transmitted to the left and right drive wheels (not shown) of the vehicle in which the power transmission device 1A is mounted via the drive shaft 8 (8A, 8B).

Here, the speed change mechanism 3A is connected downstream of the motor 2, the counter gear 5 is connected downstream of the speed change mechanism 3A, and the differential device 6 is connected downstream of the counter gear 5. The drive shafts 8 (8A, 8B) are connected downstream of the differential device 6.

In the power transmission device 1A, the motor 2 and the speed change mechanism 3A are coaxially arranged on the common rotation axis Xa. On the outer side of the rotation axis Xa in the radial direction, the rotation axis Xb of the counter gear 5 and the rotation axis Xc of the differential device 6 and the drive shafts 8 (8A, 8B) are provided parallel to the rotation axis Xa.
The power transmission device 1A is a so-called three-axis type power transmission device in which rotating shafts Xa, Xb, and Xc involved in transmission of rotation are arranged in parallel with each other.

Also in the power transmission device 1A according to the second embodiment, the motor housing 10, the outer cover 11, the inner cover 12, the outer case 13, and the inner case 14 constitute the main body case 9 of the power transmission device 1A. There is.
The motor housing 10, the outer cover 11, and the inner cover 12 form a case (first case member) of the motor 2.
The outer case 13 and the inner case 14 form a case (second case member) that houses the transmission mechanism 3A, the counter gear 5, and the differential device 6.

As shown in FIG. 5, the motor 2 has a cylindrical motor shaft 20, a cylindrical rotor core 21 externally fitted to the motor shaft 20, and a stator core 25 surrounding the outer periphery of the rotor core 21 at a predetermined interval. ing.

In the motor shaft 20, bearings B1 and B1 are externally inserted on both sides of the rotor core 21. The motor shaft 20 is rotatably supported by the motor support portion 111 of the outer cover 11 and the support portion 112 of the inner cover 12 via bearings B1 and B1.

As shown in FIG. 6, a connecting portion 201 having a smaller outer diameter than the large diameter portion 208 on the other end 20b side is provided on the one end 20a side of the motor shaft 20.
The connecting portion 201 of the motor shaft 20 is spline-fitted inside the ring-shaped third supporting portion 147 of the inner case 14 to the inner periphery of the connecting portion 423 on the transmission mechanism 3A side.

The speed change mechanism 3A includes a planetary gear set 4, a clutch 47, and a band brake 49.
The planetary gear set 4 includes a sun gear 41, a ring gear 42, a pinion gear 43, a pinion shaft 44, and a carrier 45.
The components of the planetary gear set 4 (sun gear 41, ring gear 42, pinion gear 43, pinion shaft 44, carrier 45) are provided on the inner diameter side of the outer wall portion 481 of the clutch drum 48.
The clutch 47 includes a drive plate 471 (inner diameter side friction plate) spline-fitted to the outer circumference of the ring gear 42 and a driven plate 472 (outer diameter side friction plate) spline-fitted to the inner circumference of the outer wall portion 481 of the clutch drum 48. And a piston 475 provided so as to be movable in the direction of the rotation axis Xa.

The clutch drum 48 has an outer wall portion 481, a disc portion 480, an inner wall portion 482, and a connecting portion 483.
The outer wall portion 481 has a cylindrical shape that surrounds the rotation axis Xa at predetermined intervals. The disc portion 480 extends from the end portion of the outer wall portion 481 on the opposite side (left side in the drawing) of the motor 2 to the inner diameter side. An inner wall portion 482 is provided at the inner diameter side end of the disc portion 480.

The inner wall portion 482 is formed in a cylindrical shape that surrounds the rotation axis Xa at predetermined intervals. The inner wall portion 482 extends from the inner diameter side end of the disc portion 480 to the planetary gear set 4 side (right side in the drawing), and the tip of the inner wall portion 482 is located on the inner diameter side of the band brake 49. ..

The connecting portion 483 has a cylindrical shape that surrounds the rotation axis Xa at predetermined intervals. A longitudinal end portion 483a of the connecting portion 483 is connected to the inner periphery of the inner wall portion 482 on the distal end side.
The connecting portion 483 linearly extends in a direction approaching the motor 2 (rightward in the drawing).

The clutch drum 48 including an outer wall portion 481, a disc portion 480, an inner wall portion 482, and a connecting portion 483 is provided with its opening facing the motor 2.

The inner circumference of the inner wall portion 482 is supported by the outer circumference of the support shaft 30 via the needle bearing NB.
As shown in FIG. 5, the support shaft 30 is a shaft-shaped member in which a small diameter portion 301 and a large diameter portion 302 are integrally formed side by side in the rotation axis Xa direction, and are arranged in a direction along the rotation axis Xa. ing.

The support shaft 30 is arranged coaxially with the motor shaft 20. As shown in FIG. 6, in the large-diameter portion 302 located on the motor 2 side (right side in the drawing) of the support shaft 30, a housing hole 302a capable of receiving the motor shaft 20 is opened at a portion facing the motor shaft 20. doing.

A shaft portion 424 provided at the tip of the motor shaft 20 is inserted into the accommodation hole 302a. The needle bearing NB externally inserted in the shaft portion 424 is in contact with the inner periphery of the housing hole 302a, and the support shaft 30 and the motor shaft 20 are relatively rotatably engaged with each other in the housing hole 302a.

A disc-shaped flange portion 303 is integrally formed at the end of the large diameter portion 302 on the motor 2 side. The flange portion 303 is provided in a direction orthogonal to the rotation axis Xa, and the outer periphery of the flange portion 303 extends to the side of the connecting portion 483 of the clutch drum 48.

The sun gear 41 of the planetary gear set 4 is spline-fitted to the outer periphery of the connecting portion 483.
In the planetary gear set 4, the ring gear 42 is located on the outer diameter side of the sun gear 41. The ring gear 42 includes a peripheral wall portion 421 that surrounds the outer periphery of the sun gear 41 at predetermined intervals, a disk portion 422 that extends from the end of the peripheral wall portion 421 on the motor 2 side to the inner diameter side, and the motor 2 from the inner diameter side of the disk portion 422. It has a connecting portion 423 extending to the side, and a shaft portion 424 extending from the inner diameter side end of the disc portion 422 to the side opposite to the motor 2.

In the peripheral wall portion 421 located on the outer diameter side of the shaft portion 424, the outer circumference of the pinion gear 43 meshes with the inner circumference of the region located on the outer diameter side of the sun gear 41.
The pinion gear 43 meshes with the inner circumference of the peripheral wall portion 421 on the ring gear 42 side and the outer circumference of the sun gear 41.

The pinion shaft 44 that supports the pinion gear 43 is provided in a direction along an axis line X3 that is parallel to the rotation axis Xa of the motor 2. One end and the other end of the pinion shaft 44 are supported by a pair of side plate portions 451 and 452 that form the carrier 45.
The side plate portions 451 and 452 are provided in parallel with each other with an interval in the direction of the axis X3.

One side plate portion 452 located on the motor 2 side extends to the rotation axis Xa side with respect to the other side plate portion 451. An end portion 452a on the inner diameter side of the side plate portion 452 is connected to the outer circumference of the flange portion 303 on the support shaft 30 side.

The peripheral wall portion 421 of the ring gear 42 has a ring shape surrounding the rotation axis Xa at predetermined intervals, and the drive plate 471 of the clutch 47 is spline-fitted to the outer periphery of the peripheral wall portion 421. The driven plate 472 of the clutch 47 is spline-fitted to the inner circumference of the outer wall portion 481 of the clutch drum 48.
A drive plate 471 and a driven plate 472 are alternately provided between the peripheral wall portion 421 of the ring gear 42 and the outer wall portion 481 of the clutch drum 48.

The retaining plate 473 positioned by the snap ring 474 is located on the motor 2 side in the region where the drive plate 471 and the driven plate 472 are alternately provided, and the piston 475 is disposed on the side opposite to the motor 2. The pressing portion 475a of is located.

The piston 475 has a base portion 475b provided in a direction orthogonal to the rotation axis Xa. A cylindrical wall portion 475c extending toward the planetary gear set 4 side (right side in the drawing) is provided at a substantially central portion of the base portion 475b in the radial direction of the rotation axis Xa.

In the base portion 475b of the piston 475, a slit 475d that is recessed in a direction away from the disc portion 480 of the clutch drum 48 (right direction in the drawing) is provided in a region where the cylindrical wall portion 475c is provided.
A guide piece 480b extending from the disc portion 480 of the clutch drum 48 to the motor 2 side is inserted into the slit 475d.

In the region of the base portion 475b on the inner diameter side of the cylindrical wall portion 475c, the spring Sp supported by the spring retainer 476 is in pressure contact with the surface of the base portion 475b on the motor 2 side in the rotation axis X direction.
The piston 475 is biased toward the disc portion 480 side (left side in the drawing) of the clutch drum 48 by the biasing force applied from the spring Sp.

In the clutch drum 48, a protrusion 484 that protrudes to the side opposite to the motor 2 is provided at the boundary between the disc portion 480 and the inner wall portion 482. The protrusion 484 is inserted into the inner circumference of the support 151 of the bearing B2. An oil OL supply path 151a is opened in the inner periphery of the support portion 151.
An oil passage 484a for guiding the oil OL supplied from the support portion 151 side to the oil chamber between the disc portion 480 of the clutch drum 48 and the base portion 475b of the piston 475 is provided inside the projecting portion 484. ing.

The oil OL supplied to the oil chamber via the oil passage 484a displaces the piston 475 to the motor 2 side (right side in the drawing). At this time, the displacement of the piston 475 in the rotation axis X direction is guided by the guide piece 480b provided on the disc portion 480 and the slit 475d on the piston 475 side into which the guide piece 480b is inserted.

When the piston 475 is displaced toward the motor 2 side, the drive plate 471 and the driven plate 472 of the clutch 47 are gripped between the pressing portion 475a of the piston 475 and the retaining plate 473.
As a result, the relative rotation between the ring gear 42 in which the drive plate 471 is spline-fitted and the clutch drum 48 in which the driven plate 472 is spline-fitted is regulated in accordance with the pressure of the supplied oil OL, and finally. Relative rotation is restricted.

Furthermore, a band brake 49 is wound around the outer wall 481 of the clutch drum 48. When the winding radius of the band brake 49 is narrowed by an actuator (not shown), the rotation of the clutch drum 48 about the rotation axis X is restricted.

In the speed change mechanism 3A, the planetary gear set 4 and the clutch 47 are located on the inner diameter side of the band brake 49. The band brake 49, the planetary gear set 4, and the clutch 47 overlap in the radial direction of the rotation axis X, and when viewed from the radial outside of the rotation axis X, the band brake 49, the planetary gear set 4, and The clutch 47 is provided in an overlapping positional relationship.

In the speed change mechanism 3A of the present embodiment, the ring gear 42 of the planetary gear set 4 serves as the output rotation input portion of the motor 2, and the carrier 45 serves as the input rotation output portion.

In the speed change mechanism 3, the low speed stage is realized under the following condition (a), and the high speed stage is realized under the condition (b).
(A) Band brake 49: actuated, clutch 47: released (b) Band brake 49: non-actuated, clutch 47: engaged Here, the speed change mechanism 3 is a two-speed speed change mechanism, and the low speed stage and the high speed stage have the same rotation. Direction (forward or reverse). It is possible to switch between forward and reverse by rotating the motor 2 forward and backward.

That is, in the transmission mechanism 3A, when the rotation of the clutch drum 48 is restricted by the operation of the band brake 49, the low speed stage is realized. When the clutch 47 is engaged and the ring gear 42 and the clutch drum 48 are connected so that they cannot rotate relative to each other, a high speed stage is realized.

The output rotation of the motor 2 is output to the support shaft 30 from the side plate portion 452 of the carrier 45 after the speed is changed by the speed change mechanism 3A.

As shown in FIG. 5, the support shaft 30 extends in a direction away from the motor 2 along the rotation axis Xa. In the support shaft 30, the hollow shaft 31 is spline-fitted to the outer circumference of the small diameter portion 301.
Bearings B2 and B2 are externally inserted on both sides of the hollow shaft 31 in the direction of the rotation axis Xa.
The hollow shaft 31 is supported by the third support portion 137 on the outer case 13 side and the support portion 151 on the support member 15 side via bearings B2 and B2. Therefore, the support shaft 30 is supported by the third support portion 147 on the outer case 13 side and the third support portion 147 on the inner case 14 side via the hollow shaft 31.

In the hollow shaft 31, a gear portion 311 is integrally formed on the outer circumference of a region between the bearings B2 and B2.

The large-diameter gear 52 of the counter gear 5 meshes with the outer periphery of the gear portion 311 so that rotation can be transmitted. In the counter gear 5, the large diameter gear 52 is spline-fitted to the outer circumference of the hollow cylindrical shaft portion 51.

Bearings B3 and B3 are externally fitted to one end 51a and the other end 51b of the hollow shaft 51 in the longitudinal direction.
One end portion 51a of the hollow shaft portion 51 is rotatably supported by the second support portion 135 of the outer case 13 via the bearing B3.
The other end portion 51b of the hollow shaft portion 51 is rotatably supported by the second support portion 145 of the inner case 14 via the bearing B3.

In this state, the hollow shaft portion 51 of the counter gear 5 is provided along the rotation axis Xb parallel to the rotation axis Xa.
In the hollow shaft portion 51, a small diameter gear portion 511 is provided adjacent to the other end portion 51b side (right side in the drawing) when viewed from the large diameter gear 52. The small-diameter gear portion 511 is formed integrally with the hollow shaft portion 51 and has an outer diameter R2 smaller than the outer diameter R1 of the large-diameter gear 52 (see FIG. 5: R1>R2).

The small-diameter gear portion 511 meshes with a final gear FG fixed to the differential case 60 of the differential gear 6 so as to be capable of transmitting rotation.
In the differential case 60, tubular support parts 601 and 602 are provided on both sides in the direction of the rotation axis Xc (left and right direction in the figure). The support parts 601 and 602 extend along a rotation axis Xc parallel to the rotation axis Xa.
Bearings B4 and B4 are externally fitted to the support portions 601 and 602 of the differential case 60.
The support portion 602 is held by the ring-shaped first support portion 131 of the outer case 13 via the bearing B4.
The support portion 602 is held by the ring-shaped first support portion 141 of the inner case 14 via the bearing B4.

The drive shaft 8B penetrating the opening 140 of the inner case 14 is inserted into the support portion 601 of the differential case 60 from the direction of the rotation axis Xc.
The drive shaft 8A penetrating the opening 130 of the outer case 13 is inserted into the support portion 602 of the differential case 60 from the direction of the rotation axis Xc.

Inside the differential case 60, side gears 63A and 63B are spline-fitted to the outer periphery of the tip of the drive shaft 8 (8A, 8B).
Inside the differential case 60, a cylindrical shaft 61 is provided along an axis line Y orthogonal to the rotation axis X, and the side gears 63A and 63B face each other in the rotation axis Xc direction with the shaft 61 interposed therebetween. ing.

Bevel gears 62</b>A and 62</b>B are externally inserted and rotatably supported on the shaft 61.
Two bevel gears 62A and 62B are provided at intervals in the longitudinal direction of the shaft 61 (axial direction of the axis Y), and the bevel gears 62A and 62B are arranged with their teeth facing each other. ing.

In the differential case 60, side gears 63A and 63B are located on both sides of the bevel gears 62A and 62B in the rotation axis X direction, and the bevel gears 62A and 62B and the side gears 63A and 63B are in a state where their teeth are meshed with each other. It is assembled in.

The operation of the power transmission device 1A having such a configuration will be described.
As shown in FIG. 5, in the power transmission device 1A, the transmission mechanism 3A, the counter gear 5, the differential device 6, the drive shaft 8 (8A, 8B) are provided along the transmission path of the output rotation of the motor 2. , Are provided.

When the rotor core 21 rotates about the rotation axis X by driving the motor 2, the rotation is input to the transmission mechanism 3A via the motor shaft 20 that rotates integrally with the rotor core 21.
In the speed change mechanism 3A, the ring gear 42 of the planetary gear set 4 serves as a rotation input unit and a rotation output unit to which the carrier 45 is input.

In the speed change mechanism 3A, a low speed stage is realized while the band brake 49 is operating, and a high speed stage is realized while the clutch 47 is operating.
Therefore, the rotation input to the speed change mechanism 3 is output to the hollow shaft 50 from the connecting portion 453 of the carrier 45 after the speed is changed. The rotation input to the hollow shaft 50 is input to the counter gear 5 via the large diameter gear 52 meshed with the gear portion 311 of the hollow shaft 50.

In the counter gear 5, the outer diameter R2 of the small diameter gear portion 511 is smaller than the outer diameter R1 of the large diameter gear 52 (see FIG. 4).
Therefore, the rotation input to the counter gear 5 is greatly decelerated and then output to the differential case 60 (differential device 6) via the final gear FG with which the small diameter gear portion 511 meshes.

The drive shaft 8 (8A, 8B) rotates around the rotation axis Xc by rotating the differential case 60 around the rotation axis Xc by the input rotation. As a result, the output rotation of the motor 2 is transmitted to the left and right drive wheels (not shown) of the vehicle equipped with the power transmission device 1A.

The power transmission device 1A employs a speed change mechanism 3A including a planetary gear set 4, a clutch 47, and a band brake 49, and the output rotation of the motor 2 is changed by the speed change mechanism 3A and transmitted to the counter gear 5. ing.
The speed change mechanism 3A is designed to switch between a low speed stage and a high speed stage by changing the combination of engagement/release of the clutch 47 and operation of the band brake 49. Therefore, unlike the meshing type engagement device, it is possible to prevent a situation in which the shift speed cannot be switched.

In the speed change mechanism 3, the band brake 49 overlaps the clutch 47 and the planetary gear set 4 in the radial direction of the rotation axis X, and when viewed from the radial direction of the rotation axis X, the band brake 49 includes the clutch. 47 and the planetary gear set 4 so as to overlap each other. Therefore, in the power transmission device 1, the length of the portion of the speed change mechanism 3 in the rotation axis X direction can be shortened.

In the present embodiment, of the three rotation elements (sun gear 41, ring gear 42, carrier 45) included in the planetary gear set 4, the sun gear 41 is the first rotation element and the ring gear 42 is the second rotation element. Was illustrated.
The present invention is not limited to this aspect.
The first rotating element may be any one of the sun gear 41, the carrier 45, and the ring gear 42, and the second rotating element and the third rotating element may be any of the remaining two.

As described above, the power transmission device 1A according to the present embodiment has the following configuration.
(7) The power transmission device 1A is
The transmission mechanism 3A includes a planetary gear set 4 having first to third rotating elements, an engaging element, and a tubular portion.
The engagement element is a clutch 47 (multi-plate friction clutch) having a drive plate 471 and a driven plate 472.
The tubular portion is the outer wall portion 481 of the clutch drum 48, and the clutch drum 48 rotates integrally with the sun gear 41 (first rotating element).
The clutch drum 48 is connected to the ring gear 42 (second rotating element) via the clutch 47.
The drive plate 471 and the driven plate 472 of the clutch 47 are radially sandwiched between the planetary gear set 4 and the outer wall portion 481 of the clutch drum 48.

According to this structure, the planetary gear set 4, the drive plate 471 and the driven plate 472, and the outer wall portion 481 of the clutch drum 48 are arranged to overlap each other in the radial direction of the rotation axis X of the power transmission device 1A. .. When viewed from the radial direction of the rotation axis X, the planetary gear set 4, the drive plate 471 and the driven plate 472, and the outer wall portion 481 are arranged so as to overlap each other.
As a result, the speed change mechanism 3A can be shortened in the rotation axis X direction, and the power transmission device 1A that employs the multi-plate friction clutch in the speed change mechanism 3A can be provided without increasing the size in the rotation axis X direction.

Here, the first rotating element may be any one of the sun gear 41, the carrier 45, and the ring gear 42, and the second rotating element and the third rotating element may each be the remaining two. ..
An outer wall portion 481 (cylindrical portion) pulled out to the outer peripheral side of the planetary gear set 4 is provided on the clutch drum 48 that rotates integrally with the first rotating element, and the outer wall portion 481, the planetary gear set 4, and the clutch 47 are provided. And are arranged so as to overlap each other in the radial direction of the rotation axis X. As a result, the transmission mechanism 3A can be shortened in the direction of the rotation axis X.

The power transmission device 1 according to the present embodiment has the following configuration.
(8) The clutch drum 48 has a disc portion 480 (wall portion) that connects the outer wall portion 481 and the first rotating element.
The disk portion 480 is arranged laterally of the planetary gear set 4 in the rotation axis X direction.
The piston 475 of the clutch 47 is disposed between the planetary gear set 4 and the disc portion 480 so as to be sandwiched in the axial direction.
The disc portion 480 constitutes a part of a piston hydraulic chamber that supplies hydraulic pressure to the piston 475.

By using the disc portion 480 (wall portion) of the clutch drum 48 as a wall of the hydraulic chamber of the piston 475, it is not necessary to separately prepare a member for forming the hydraulic chamber between the piston 475 and the piston 475.
As a result, it is possible to further reduce the size of the speed change mechanism 3A in the rotation axis X direction.

(9) The first rotating element is the sun gear 41.
The outer wall portion 481 of the clutch drum 48 is arranged on the outer periphery of the ring gear 42.
The outer wall portion 481 of the clutch drum 48 is connected to a fixed element (inner case 14) provided on the outer peripheral side of the planetary gear set 4 via a band brake 49 (brake element).

With this configuration, the disk portion 480 of the clutch drum 48 when viewed from the direction of the rotation axis X has the sun gear 41 located closest to the inner diameter side in the radial direction of the rotation axis X and the ring gear located closest to the outer diameter side. It is provided in a range straddling 42.
This maximizes the range of the disk portion 480 in the radial direction of the rotation axis X. Therefore, when the hydraulic chamber of the piston 475 is formed using the disk portion 480, the size of the hydraulic chamber in the radial direction of the rotation axis X is increased. Can be maximized.

Thereby, when the volume of the hydraulic chamber of the piston 475 is set to a predetermined volume, it is possible to shorten the rotation axis X direction.

The power transmission device 1 according to the present embodiment has the following configuration.
(9) The power transmission device 1A has a motor 2.
The speed change mechanism 3A is connected downstream of the motor 2.

Since the output torque of the motor 2 tends to decrease as the rotation speed increases, the configuration that can reduce friction at the high speed stage is particularly suitable for a power transmission device using a motor as a drive source.

FIG. 7 is a skeleton diagram schematically showing the structure of the speed change mechanisms 3 and 3A.
8 to 11 are skeleton diagrams for explaining modified examples of the transmission mechanism.
In the following description, the symbol “S” means the sun gear 41 of the planetary gear set 4, the symbol “R” means the ring gear 42, and the symbol “C” means the carrier 45. ..
Further, reference numeral “BB” means the band brake 49, reference numeral “CL” means the clutch 47, reference numeral “P” means the piston 475, and reference numeral “DR” means the clutch drum 48. However, the symbol “HB” means a hub. Further, the symbol “P” means the piston 475.

The above-mentioned speed change mechanism 3, 3A can be shown as in FIG.
In the above-described speed change mechanisms 3 and 3A, the case where the planetary gear set 4 is a single pinion having one pinion gear 43 is illustrated.
In the transmissions 3 and 3A, the ring gear 42(R) of the planetary gear set 4 is an input unit for rotation, and the carrier 45 is an output unit. Then, the clutch 47 (C) engages the ring gear 42 (R) and the sun gear (S) in a relatively non-rotatable manner, and the band brake 49 (BB) is connected to the clutch drum 48 (DR) to the sun gear 41 ( Fix S).

The speed change mechanism applicable to the power transmission device according to the present invention is not limited to this mode.
The modes of the applicable speed change mechanism will be listed below with reference to FIGS. 8 to 11.

For example, when the rotation of the sun gear S is fixed by the band brake BB with the single pinion, the modes shown in FIGS. 8A and 8B may be adopted.
In the mode of FIG. 8A, the ring gear R of the planetary gear set is an input unit for rotation, the carrier C is an output unit, and the band brake BB fixes the sun gear S connected to the clutch drum DR. .. The clutch CL fastens the sun gear S connected to the clutch drum DR and the carrier C connected to the hub HB so that they cannot rotate relative to each other.

In the mode of (b) of FIG. 8, the ring gear R of the planetary gear set is an input part for rotation, the carrier C is an output part, and the band brake BB fixes the sun gear S connected to the hub HB. The clutch CL fastens the ring gear R and the carrier C connected to the clutch drum DR such that they cannot rotate relative to each other.

When the rotation of the carrier C is fixed by the band brake BB with a single pinion, the modes shown in (a), (b) and (c) of FIG. 9 may be adopted.
In the mode of (a) of FIG. 9, the sun gear S of the planetary gear set is a rotation input part, the ring gear R is an output part, and the band brake BB fixes the carrier C coupled to the hub HB. The clutch CL fastens the sun gear S and the ring gear R connected to the clutch drum DR such that they cannot rotate relative to each other.

In the mode of FIG. 9B, the sun gear S of the planetary gear set is a rotation input unit, the ring gear R is an output unit, and the band brake BB fixes the carrier C coupled to the hub HB. The clutch CL fastens the sun gear S connected to the clutch drum DR and the carrier C connected to the hub HB so that they cannot rotate relative to each other.
In the mode of (c) of FIG. 9, the sun gear S of the planetary gear set is an input part for rotation, the ring gear R is an output part, and the band brake BB fixes the carrier C connected to the clutch drum DR. .. The clutch CL fastens the carrier C, which is connected to the clutch drum DR, and the ring gear R such that they cannot rotate relative to each other.

Further, when the rotation of the ring gear R is fixed by the band brake BB with the single pinion, the modes shown in (d), (e) and (f) of FIG. 9 may be adopted.
In the mode of (d) of FIG. 9, the sun gear S of the planetary gear set is an input part for rotation, the carrier C is an output part, and the band brake BB fixes the ring gear R. The clutch CL fastens the sun gear S and the ring gear R connected to the clutch drum DR such that they cannot rotate relative to each other.

In the mode of (e) of FIG. 9, the sun gear S of the planetary gear set is a rotation input unit, the carrier C is an output unit, and the band brake BB fixes the ring gear R. The clutch CL fastens the sun gear S and the carrier C connected to the clutch drum DR such that they cannot rotate relative to each other.
In the mode of (f) of FIG. 9, the sun gear S of the planetary gear set is an input unit for rotation, the carrier C is an output unit, and the band brake BB fixes the ring gear R. The clutch CL fastens the ring gear R connected to the clutch drum DR and the carrier C connected to the hub HB so that they cannot rotate relative to each other.

When the rotation of the sun gear S is fixed by the band brake BB with the double pinion, the modes shown in (a), (b) and (c) of FIG. 10 may be adopted.
In the mode of (a) of FIG. 10, the carrier C of the planetary gear set is an input part for rotation, the ring gear R is an output part, and the band brake BB fixes the sun gear S connected to the clutch drum DR. .. The clutch CL fastens the ring gear R and the sun gear S connected to the clutch drum DR such that they cannot rotate relative to each other.

In the mode of FIG. 10B, the carrier C of the planetary gear set is an input part for rotation, the ring gear R is an output part, and the band brake BB fixes the sun gear S connected to the clutch drum DR. .. The clutch CL fastens the sun gear S connected to the clutch drum DR and the carrier C connected to the hub HB so that they cannot rotate relative to each other.
In the mode of (c) of FIG. 10, the carrier C of the planetary gear set is a rotation input unit, the ring gear R is an output unit, and the band brake BB fixes the sun gear S connected to the hub HB. The clutch CL fastens the carrier C, which is connected to the clutch drum DR, and the ring gear R such that they cannot rotate relative to each other.

When the rotation of the carrier C is fixed by the band brake BB with the double pinion, the modes shown in (d), (e) and (f) of FIG. 10 may be adopted.
In the mode of (d) of FIG. 10, the sun gear S of the planetary gear set is an input part for rotation, the ring gear R is an output part, and the band brake BB fixes the carrier C connected to the hub HB. The clutch CL fastens the sun gear S and the ring gear R connected to the clutch drum DR such that they cannot rotate relative to each other.

In the mode of (e) of FIG. 10, the sun gear S of the planetary gear set is an input unit for rotation, the ring gear R is an output unit, and the band brake BB fixes the carrier C connected to the hub HB. The clutch CL fastens the sun gear S connected to the clutch drum DR and the carrier C connected to the hub HB so that they cannot rotate relative to each other.
In the mode of (f) of FIG. 10, the sun gear S of the planetary gear set is an input part for rotation, the ring gear R is an output part, and the band brake BB fixes the carrier C connected to the clutch drum DR. .. The clutch CL fastens the carrier C, which is connected to the clutch drum DR, and the ring gear R such that they cannot rotate relative to each other.

When the rotation of the ring gear R is fixed by the band brake BB with the double pinion, the modes shown in (a), (b) and (c) of FIG. 11 may be adopted.
In the mode of (a) of FIG. 11, the sun gear S of the planetary gear set is an input part for rotation, the carrier C is an output part, and the band brake BB fixes the ring gear R. The clutch CL fastens the sun gear S and the ring gear R connected to the clutch drum DR such that they cannot rotate relative to each other.

In the mode of (b) of FIG. 11, the sun gear S of the planetary gear set is an input part for rotation, the carrier C is an output part, and the band brake BB fixes the ring gear R. The clutch CL fastens the carrier C, which is connected to the clutch drum DR, and the sun gear S so that they cannot rotate relative to each other.
In the mode of (c) of FIG. 11, the sun gear S of the planetary gear set is an input unit for rotation, the carrier C is an output unit, and the band brake BB fixes the ring gear R. The clutch CL fastens the carrier C coupled to the hub HB and the ring gear R coupled to the clutch drum DR such that they cannot rotate relative to each other.

As described above, all 18 patterns of possible modes of the speed change mechanism are illustrated in FIGS. 7 to 11.
Among all 18 patterns, in the mode shown in FIG. 7, the mode shown in (e) of FIG. 9, the mode shown in (a) of FIG. 10, and the mode shown in (f) of FIG. It is possible to switch between the low-speed stage and the high-speed stage while maintaining the forward rotation direction.
In the mode shown in FIG. 7 and the mode shown in FIG. 10A, the outer diameter of the clutch drum DR is the largest, so that the clutch CL can be brought into the engaged state with a margin.

Further, the clutch CL that engages two elements of the constituent elements of the planetary gear set (sun gear S, ring gear R, carrier C) may be provided anywhere in the transmission mechanism.
For example, the clutch CL may be provided between the band brake BB and the ring gear R as in the modes shown in (a), (b) of FIG. 8 and (c) of FIG. 9.

In the clutch CL shown in FIG. 8A, between the band brake BB and the ring gear R, the clutch drum DR connected to the sun gear S is provided on the outer diameter side, and the hub HB connected to the carrier C is set to the inner diameter. The carrier C and the sun gear S are fastened to each other.

In the clutch CL shown in FIG. 8B, a hub HB connected to the sun gear S is provided on the outer diameter side between the band brake BB and the ring gear R, and an inner diameter of the clutch drum DR connected to the carrier C is provided. It is provided on the side to fasten the carrier C and the ring gear R.

In the clutch CL shown in FIG. 9C, the clutch drum DR fixed to the carrier C is provided between the band brake BB and the ring gear R on the outer diameter side of the ring gear R, and the carrier C and the ring gear R are provided. Conclude with R.

Further, a clutch may be provided on the inner diameter side of the sun gear S, for example, as in the modes shown in (a), (b), and (d) to (f) of FIG. 9.

In the clutch CL shown in (a) of FIG. 9, a clutch drum DR connected to the ring gear R is provided on the inner diameter side of the sun gear S to fasten the sun gear S and the ring gear R.
In the clutch CL shown in FIG. 9B, a hub HB connected to the carrier C is provided on the outer diameter side of the clutch drum DR connected to the sun gear S to connect the sun gear S and the carrier C.

In the clutch CL shown in (d) of FIG. 9, a clutch drum DR connected to the ring gear R is provided on the inner diameter side of the sun gear S to connect the sun gear S and the ring gear R.
In the clutch CL shown in (e) of FIG. 9, a clutch drum DR connected to the carrier C is provided on the inner diameter side of the sun gear S to connect the sun gear S and the carrier C.
In the clutch CL shown in (f) of FIG. 9, the hub HB connected to the carrier C is provided on the inner diameter side of the sun gear S, and the clutch drum DR connected to the ring gear R is provided on the inner diameter side of the hub HB. , The carrier C and the ring gear R are connected.

Thus, the clutch CL may be provided on either the outer diameter side of the ring gear R or the inner diameter side of the sun gear S.

The same applies to a double pinion having two pinion gears.
As shown in (a), (b), (c), and (f) of FIG. 10, a clutch CL may be provided on the outer diameter side of the ring gear R.

In the clutch CL shown in FIG. 10A, the clutch drum DR connected to the sun gear S is provided on the outer diameter side of the ring gear R to fasten the sun gear S and the ring gear R.
In the clutch CL shown in FIG. 10B, the hub HB connected to the carrier C is provided on the outer diameter side of the ring gear R, and the clutch drum DR connected to the sun gear S is provided on the outer diameter side of the hub HB. And the sun gear S and the ring gear R are connected to each other.

In the clutch CL shown in FIG. 10C, the clutch drum DR connected to the carrier C is provided on the outer diameter side of the ring gear R, and the hub HB connected to the sun gear S is attached to the outer diameter side of the clutch drum DR. In the clutch CL shown in FIG. 10(f), which is provided on the side to connect the sun gear S and the carrier C, a clutch drum DR connected to the carrier C is provided on the outer diameter side of the ring gear R, Connect R and carrier C

As shown in (d) and (e) of FIG. 10 and (a), (b), and (c) of FIG. 11, a clutch CL may be provided on the inner diameter side of the sun gear S.
In the clutch CL shown in FIG. 10D, the clutch drum DR connected to the ring gear R is provided on the inner diameter side of the sun gear S to connect the sun gear S and the ring gear R.
In the clutch CL shown in (e) of FIG. 10, the clutch drum DR connected to the sun gear S is provided on the inner diameter side of the sun gear S, and the hub HB connected to the carrier C is provided on the outer side of the clutch drum DR. It is provided on the radial side to connect the sun gear S and the carrier.

In the clutch CL shown in FIG. 11A, the clutch drum DR connected to the ring gear R is provided on the inner diameter side of the sun gear S to connect the sun gear S and the ring gear R.
In the clutch CL shown in FIG. 11B, the clutch drum DR connected to the carrier C is provided on the inner diameter side of the sun gear S to connect the sun gear S and the carrier C.
In the clutch CL shown in FIG. 11C, the hub HB connected to the carrier C is provided on the outer diameter side of the sun gear S, and the clutch drum DR connected to the ring gear R is formed on the inner diameter side of the hub HB. It is provided on the side and connects the carrier C and the ring gear R.

In the mode shown in FIG. 9C and the mode shown in FIG. 11B, it is necessary to reverse the output revision direction of the motor 2 when switching between the low speed stage and the high speed stage.

Here, the term “downstream connection” in the present specification means that power is transmitted from a component arranged upstream to a component arranged downstream.
For example, when the transmission mechanism 3 is connected downstream of the motor 2, it means that power is transmitted from the motor 2 to the transmission mechanism 3.
In addition, the term “direct connection” in the present specification means that the members are connected to each other so that power can be transmitted without using another member such as a speed reducing mechanism, a speed increasing mechanism, or a speed change mechanism that changes a speed reduction ratio. Means

Although the embodiments of the present invention have been described above, the present invention is not limited to the modes shown in these embodiments. The invention can be appropriately modified within the technical idea of the invention.

1, 1A Power transmission device 10 Motor housing 11 Outer cover 110 Joint part 111 Motor support part 112 Support part 114 Opening part 12 Inner cover 120 Joining part 121 Motor supporting part 13 Outer case 130 Opening part 131 First supporting part 135 Second supporting part Part 137 Third support part 14 Inner case 141 First support part 142 Partition wall 145 Second support part 147 Third support part 15 Support member 151 Support part 151a Supply path 152 Cylindrical part 153 Flange part 2 Motor 20 Motor shaft 201 Connection Part 202 Supported part 203 Intermediate region 208 Large diameter part 21 Rotor core 25 Stator core 251 Yoke part 252 Teeth part 253 Winding 253a, 253b Coil end 3, 3A Transmission mechanism 30 Support shaft 31 Hollow shaft 311 Gear part 301 Small diameter part 302 Large diameter Part 303 flange part 4 planetary gear set 41 sun gear 42 ring gear 421 peripheral wall part 422 disc part 423 connecting part 424 shaft part 43 pinion gear 44 pinion shaft 45 carrier 451, 452 side plate part 453 connecting part 47 clutch 471 drive plate 472 driven plate 475 Piston 475a Pressing part 475b Base part 475c Cylinder wall part 475d Slit 476 Spring retainer 48 Clutch drum 480 Disc part 480a Recessed part 480b Guide piece 481 Outer wall part 482 Inner wall part 483a Base end part 483 4a end part 483b 483a Base end part 483b Band brake 5 Counter gear 50 Hollow shaft 501 Connection part 502 Gear part 51 Hollow shaft part 511 Small diameter gear part 52 Large diameter gear 53 Park gear 6 Differential device 60 Differential case 601, 602 Support part 61 Shaft 62A, 62B Bevel gear 63A, 63B Side gear 8 (8A, 8B) Drive shaft 9 Main body case B Bolt B1, B2, B3, B4, B5 Bearing S Sun gear R Ring gear C Carrier DR Clutch drum HB hub BB Band brake CL clutch FG Final gear NB Needle bearing OL Oil P pin RS Lip Seal SL Seal Lin Gu Sa space (motor room)
Sb space (first gear room)
Sp Spring Sc Space (2nd gear chamber)
X, Xa, Xb, Xc Rotation axis X1, X3, Y axis

Claims (6)

A transmission mechanism having a planetary gear set having first to third rotating elements, an engagement element, and a tubular portion,
The tubular portion rotates integrally with the first rotating element,
The tubular portion is connected to the second rotating element via the engaging element,
The power transmission device, wherein the drive plate and the driven plate of the engagement element are arranged so as to be sandwiched in the radial direction between the planetary gear set and the tubular portion. In claim 1,
A wall portion that connects the tubular portion and the first rotating element,
The piston of the engagement element is disposed so as to be sandwiched in the axial direction between the planetary gear set and the wall portion,
The power transmission device, wherein the wall portion constitutes a part of a piston hydraulic chamber that supplies hydraulic pressure to the piston. In claim 2,
The first rotating element is a sun gear,
The power transmission device, wherein the tubular portion is arranged on an outer circumference of a ring gear. In claim 3,
The power transmission device, wherein the tubular portion is connected to a fixed element provided on an outer peripheral side of the planetary gear set via a braking element. In claim 2,
The first rotating element is a ring gear,
The power transmission device, wherein the tubular portion is arranged on an inner circumference of a sun gear. In any one of Claim 1 thru|or Claim 5,
Have a motor,
The power transmission device, wherein the speed change mechanism is connected downstream of the motor.

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