JP7282451B2 - power transmission device - Google Patents

Description

The present invention relates to power transmission devices.

Patent documents 1 and 2 disclose a power transmission device having a motor.

JP 2013-221566 A JP 2016-89860 A

In the power transmission device of Patent Document 1, three rotating shafts involved in rotation transmission are arranged in parallel, and it is easy to increase in size in the vertical direction (gravitational direction) (hereinafter referred to as a three-shaft type).

In the power transmission device of Patent Document 2, the rotor of the motor is a hollow shaft, and the drive shaft passes through the inside of this hollow shaft. Therefore, it is possible to reduce the size in the vertical direction compared to the 3-axis type, but the size increases in the vertical direction due to the arrangement of a large counter gear (hereinafter referred to as the 2-axis type). .

This type of power transmission device is required to be able to cool the motor efficiently.

The present invention
a motor;
a counter gear connected downstream of the motor;
a differential connected downstream of the counter gear;
a case member that houses the motor , the counter gear, and the differential ,
The motor, the counter gear, and the differential are arranged in this order along the rotation axis direction of the motor,
The counter gear has a hollow shaft,
The hollow shaft portion is arranged on the outer diameter side of the differential device, one end portion on the differential device side is supported by a first support portion of the case member, and the other end portion on the motor side is supported by the first support portion of the case member. is supported by the second support portion of the case member,
The first support portion is provided with a communication passage that communicates between the internal space of the case member and the internal space of the hollow shaft portion,
A lubricating oil passage extending in the direction of the rotating shaft is opened in the second support portion on the outer circumference of the motor,
A part of the lubricating oil raked up by the rotation of the differential device flows into the hollow shaft portion from the communicating passage and is supplied to the motor via the lubricating oil passage. device.

According to the present invention, lubricating oil is supplied to the motor using the counter gear, so motor cooling can be promoted.

It is a figure explaining the power transmission device concerning this embodiment. It is an enlarged view around the counter gear of a power transmission device. 3 is a diagram for explaining a motor cooling structure in the power transmission device 1; FIG.

Embodiments of the present invention will be described below.
FIG. 1 is a diagram illustrating a power transmission device 1 according to this embodiment.
FIG. 2 is an enlarged view around the counter gear 5 of the power transmission device 1. As shown in FIG.

As shown in FIG. 1, the power transmission device 1 includes a motor 2, a counter gear 5 (reduction gear) that reduces the output rotation of the motor 2 and inputs it to a differential device 6, and drive shafts 8 (8A, 8B). ,have.

In the power transmission device 1 , a counter gear 5 , a differential device 6 , and drive shafts 8 ( 8 A, 8 B) are provided along the output rotation transmission path of the motor 2 .
The output rotation of the motor 2 is decelerated by the counter gear 5 and input to the differential device 6, and then through the drive shafts 8 (8A, 8B) to the left and right drive wheels of the vehicle on which the power transmission device 1 is mounted. (not shown). In FIG. 1, the drive shaft 8A is connected to the left wheel of the vehicle on which the power transmission device 1 is mounted so that rotation can be transmitted, and the drive shaft 8B is connected to the right wheel so that rotation can be transmitted.

Here, the counter gear 5 is connected downstream of the motor 2, the differential gear 6 is connected downstream of the counter gear 5, and the drive shafts 8 (8A, 8B) are connected to the differential gear 6. connected downstream.

In this embodiment, the motor housing 10 , the outer cover 11 , the inner cover 12 , the outer case 13 , and the inner case 14 constitute the body case 9 of the power transmission device 1 .
The motor housing 10, the outer cover 11, and the inner cover 12 constitute a case (first case member) of the motor 2. As shown in FIG.
The outer case 13 and the inner case 14 constitute a case (second case member) that accommodates the counter gear 5 and the differential gear 6 .

A space Sa formed between the outer cover 11 and the inner cover 12 on the inner diameter side of the motor housing 10 serves as a motor chamber that accommodates the motor 2 .
A space Sb formed between the outer case 13 and the inner case 14 serves as a gear chamber that accommodates the counter gear 5 and the differential gear 6 .

The motor 2 has a cylindrical motor shaft 20, a cylindrical rotor core 21 fitted onto the motor shaft 20, and a stator core 25 surrounding the outer circumference of the rotor core 21 at predetermined intervals.

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 fitted on the drive shaft 8B.
The insertion hole 200 of the motor shaft 20 has a connecting portion 201 on the side of one end 20a in the longitudinal direction and a supported portion 202 on the side of the other end 20b in the rotation axis X direction. It is formed with an inner diameter larger than that of the region 203 .

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

In the motor shaft 20, a bearing B1 is externally inserted and fixed to the outer circumference of the position away from the one end 20a toward the other end 20b.
As shown in FIG. 2, a stepped portion 205 provided on the outer circumference of the motor shaft 20 restricts the movement of the bearing B1 toward the rotor core 21 (right side in the drawing).

The outer circumference of the bearing B<b>1 is supported by a 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 (to the left in the drawing) by the stepped portion 121a provided on the inner circumference of the motor support portion 121. As shown in FIG.
Therefore, the motor shaft 20 is rotatably supported by the cylindrical motor support portion 121 of the inner cover 12 via the bearing B1 at the outer periphery of the motor shaft 20 at a position away from the rotor core 21 toward the one end 20a.

As shown in FIG. 1, in the motor shaft 20, a bearing B1 is externally fitted and fixed to the outer circumference 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.

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

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

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.

Rotor core 21 is formed by laminating a plurality of silicon steel plates, and each silicon steel plate is fitted over motor shaft 20 in a state where relative rotation with motor shaft 20 is restricted.
When viewed from the rotation axis X direction of the motor shaft 20, the silicon steel plate has a ring shape, and on the outer peripheral side of the silicon steel plate, magnets with N poles and S poles (not shown) are alternately arranged in the circumferential direction around the rotation axis X. is provided in

One end portion 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 21 b of the rotor core 21 is positioned by a stopper 23 press-fitted onto the motor shaft 20 .

The stator core 25 is formed by laminating a plurality of electromagnetic steel sheets. Each of the electromagnetic steel sheets includes a ring-shaped yoke portion 251 fixed to the motor housing 10 and a ring-shaped yoke portion 251 extending from the inner periphery of the yoke portion 251 to the rotor core 21 side. It has protruding teeth 252 .
In the present embodiment, a stator core 25 in which the winding 253 is distributed over a plurality of teeth 252 is adopted. The length in the direction of the rotation axis X is longer than that of the rotor core 21 by the amount.

A stator core having a structure in which windings are concentratedly wound may be employed for each of the plurality of tooth portions 252 protruding toward the rotor core 21 side.

As shown in FIG. 2, one end 20a side of the motor shaft 20 is arranged so that the motor support portion 121 of the inner cover 12 and the cylindrical support portion 141 of the inner case 14 are positioned on the side of the differential device 6 (left side in the figure). penetrates.

A connecting portion 201 on the one end 20a side of the motor shaft 20 passes through a space Sc formed between the inner cover 12 and the outer case 13, and a space Sb formed by joining the outer case 13 and the inner case 14 together. (gear room).
In the space Sb, the counter gear 5 and the differential gear 6 are accommodated, and lubricating oil OL (oil) for lubricating the counter gear 5 and the differential gear 6 is stored.
When the power transmission device 1 is not driven, the lubricating oil OL is stored up to a height position below the rotation axis X in the direction of gravity.

A bearing B3 is fixed to the inner periphery of a cylindrical support portion 141 of the inner case 14, and the outer periphery of the motor shaft 20 on the one end 20a side is supported by the support portion 141 via the bearing B3.

One end 20a of the motor shaft 20 faces a tip 601a of a cylindrical support portion 601 of the differential gear 6, which will be described later, with a gap in the rotation axis X direction.

In the motor shaft 20, a transmission gear 26 is spline-fitted to the outer circumference of the connecting portion 201 on the one end 20a side. The transmission gear 26 is positioned in the rotation axis X direction by a nut N screwed onto one end 20 a of the motor shaft 20 .

The large-diameter gear 52 of the counter gear 5 meshes with the outer periphery of the transmission gear 26 so as to transmit rotation.
A large-diameter gear 52 in the counter gear 5 is spline-fitted to the outer periphery of a cylindrical hollow shaft portion 51 .

A bearing B4 is externally fitted to one end portion 51a and the other end portion 51b of the hollow shaft portion 51 in the longitudinal direction. A bearing B<b>4 externally inserted on the one end portion 51 a of the hollow shaft portion 51 is inserted into the cylindrical second support portion 135 of the outer case 13 . 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 a bearing B4.

A bearing B<b>4 externally inserted on the other end portion 51 b 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 a bearing B4.

In this state, the hollow shaft portion 51 of the counter gear 5 is provided along the axis X1 parallel to the rotation axis X. As shown in FIG.
The hollow shaft portion 51 of the counter gear 5 rotates around the axis X1 when the output rotation of the motor 2 is input through the large-diameter gear 52 .

In the hollow shaft portion 51, a park gear 53 is provided adjacent to one end portion 51a side (left side in the figure) when viewed from the large diameter gear 52. As shown in FIG.
As shown in FIG. 2 , in the hollow shaft portion 51 , a small diameter gear portion 511 is provided at a position away from the park gear 53 toward the one end portion 51 a side (left 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. 1: R1>R2).

The small-diameter gear portion 511 meshes with the final gear FG fixed to the differential case 60 of the differential gear 6 so as to transmit rotation.

In the power transmission device 1 , the output rotation of the motor 2 is input to the counter gear 5 via the transmission gear 26 rotating integrally with the motor shaft 20 and the large diameter gear 52 meshing with the transmission gear 26 .

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

Then, since the final gear FG with which the small-diameter gear portion 511 engages so as to transmit rotation is fixed to the differential case 60, the differential case 60 rotates around the rotation axis X in conjunction with the rotation of the counter gear 5 around the axis X1. 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. 1).
In the counter gear 5, the large-diameter gear 52 is an input portion for the output rotation of the motor 2, and the small-diameter gear portion 511 is an output portion for the input rotation.
Then, the rotation input to the counter gear 5 is output to the differential case 60 after being largely decelerated.

As shown in FIG. 2, the differential case 60 is formed in a hollow shape that accommodates therein a shaft 61, bevel gears 62A and 62B, and side gears 63A and 63B.
In the differential case 60, cylindrical support portions 601 and 602 are provided on both sides in the direction of the rotation axis X (horizontal direction in the figure). Supports 601 and 602 extend along rotation axis X in a direction away from shaft 61 .

A bearing B<b>2 is fitted to the support portion 602 of the differential case 60 . The bearing B2 externally inserted in the support portion 602 is held by the ring-shaped first support portion 131 of the outer case 13, and the support portion 602 of the differential case 60 is rotatable on the outer case 13 via the bearing B2. supported by

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

A bearing B<b>2 is fitted to the support portion 601 of the differential case 60 . The bearing B<b>2 externally inserted into the support portion 601 is held by the ring-shaped support portion 151 of the support member 15 .
The support member 15 includes a cylindrical portion 152 extending from the outer periphery of the support portion 151 toward the motor 2 (to the right in the figure), and a flange portion 153 surrounding an opening on the tip end side of the cylindrical portion 152 over the entire circumference. have. The flange portion 153 of the support member 15 is fixed to the support portion 141 of the inner case 14 by bolts B passing through the flange portion 153 .

A support portion 601 of the differential case 60 is rotatably supported by the support member 15 via a 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, which is a stationary member, via the bearing B2 and the support member 15. As shown in FIG.

As shown in FIG. 1, the drive shaft 8B passing through the opening 114 of the outer cover 11 is inserted into the support portion 601 of the differential case 60 from the rotation axis X direction.
The drive shaft 8B is provided across the motor shaft 20 of the motor 2, the inner diameter side of the large-diameter gear 52 of the counter gear 5, and the inner diameter side of the transmission gear 26 in the rotation axis X direction. The tip side is rotatably supported by a support portion 601 .

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

As shown in FIG. 2, inside the differential case 60, the side gears 63A, 63B are spline-fitted to the outer periphery of the tip of the drive shaft 8 (8A, 8B). , 8B) are connected so as to be integrally rotatable 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 symmetrical positions with the rotation axis X interposed therebetween.
The shaft holes 60a and 60b are positioned on an axis Y orthogonal to the rotation axis X, and a shaft 61 is inserted into the shaft holes 60a and 60b.

The shaft 61 is fixed to the differential case 60 with a pin P, and rotation of the shaft 61 around the axis Y is prohibited.

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

In the differential case 60, bevel gears 62A and 62B are rotatably supported on the shaft 61 by being fitted thereon.
Two bevel gears 62A and 62B are provided with an interval in the longitudinal direction (axis Y direction) of the shaft 61, and the bevel gears 62A and 62B are arranged with their teeth facing each other. .
Bevel gears 62 A and 62 B are provided on the shaft 61 such that the axial centers of the bevel gears 62 A and 62 B coincide with the axial center of the shaft 61 .
Inside the differential case 60, side gears 63A and 63B are positioned on both sides of the bevel gears 62A and 62B in the rotation axis X direction.
Two side gears 63A and 63B are provided with a gap in the direction of the rotation axis X with their teeth facing each other. are assembled in a state of meshing.

In the power transmission device 1, a gear train (counter gear 5, final gear FG) and a differential device 6 (bevel gears 62A, 62B, side gears 63A, 63B) are provided on a transmission line for output rotation of the motor 2. .
When the power transmission device 1 is driven, heat is generated in the motor 2, and in the gear train (counter gear 5) and the differential device 6, heat is generated at the portions where the gears mesh with each other (the meshing portions of the gears).

Therefore, inside the second case member (outer case 13, inner case 14) that houses the counter gear 5 and the differential gear 6, a cooling medium (lubricating oil OL) is stored up to a predetermined height.
Then, when the differential gear 6 rotates around the rotation axis X, the lubricating oil OL in the second case member is raked up by the differential case 60, and the raked up lubricating oil OL reaches the meshing portion of the gear. supplied. As a result, the heat generated at the meshing portion of the gear is recovered by heat exchange with the lubricating oil OL that has been scraped up, thereby cooling the meshing portion of the gear.

Further, in the present embodiment, the motor housing 10 of the first case member (the motor housing 10, the outer cover 11, and the inner cover 12) that accommodates the motor 2 is supplied with a portion of the lubricating oil OL that has been scraped up in the second case member. A lubricating oil passage 101 is provided through which the oil flows.
By supplying the lubricating oil OL flowing through the lubricating oil passage 101 from the outer peripheral side of the motor 2 into the first case member, the heat generated when the motor 2 is driven is transferred to the lubricating oil OL by heat exchange with the lubricating oil OL. It collects and cools the motor 2 .

The configuration for cooling the motor 2 will be specifically described below.
FIG. 3 is a diagram illustrating a motor cooling structure in the power transmission device 1. FIG. FIG. 3(a) is an enlarged view of the power transmission device 1 around the motor 2. FIG. (b) of FIG. 3 is a diagram illustrating the flow of lubricating oil OL for cooling.

As shown in (a) of FIG. 3 , a lubricating oil passage 101 through which lubricating oil OL flows is provided on the outer peripheral portion of the motor housing 10 using the radial thickness of the motor housing 10 .
The lubricating oil passage 101 is provided parallel to the rotation axis X. As shown in FIG. The lubricating oil passage 101 is
It extends from one end 10a of the motor housing 10 to the vicinity of the other end 10b.

In the lubricating oil passage 101, lubricating oil OL supplied via an in-shaft oil passage 510, which will be described later, flows from one end 10a of the motor housing 10 toward the other end 10b.
In the following description, for convenience of explaining the position of the lubricating oil passage 101 in the direction of the rotation axis X, the region of the lubricating oil passage 101 located on the one end 10a side of the motor housing 10 will be referred to as the "front side" and the other end 10b side. The region of the lubricating oil passage 101 located at is also denoted as "back side".

Inside the motor housing 10, a stator core 25 surrounding the outer circumference of the rotor core 21 of the motor 2 at predetermined intervals is provided.
In the stator core 25 , a bracket 254 for fixing the stator core 25 to the motor housing 10 is provided at the other end 251 b of the ring-shaped yoke portion 251 .

The bracket 254 includes an annular portion 254a extending in a direction away from the stator core 25 along the inner circumference 10c of the motor housing 10, a connecting portion 254b extending radially outward from the end of the annular portion 254a opposite to the stator core 25, have.
The bracket 254 is fixed to the other end 10b of the motor housing 10 with a bolt B passing through the connecting portion 254b.

In this state, one end 251a in the longitudinal direction of the yoke portion 251 is attached to the stopper 10d on the inner periphery of the motor housing 10 from the direction of the rotation axis X while a clearance CL is secured between the yoke portion 251 and the inner periphery 10c of the motor housing 10. It is pressed.
In the present embodiment, a gap CL is formed between the outer circumference 251c of the yoke portion 251 and the inner circumference 10c of the motor housing 10 over the entire length in the rotation axis X direction.
This gap CL is closed by a stopper 10d on the one end 251a side of the yoke portion 251 and is open on the other end 251b side.

As shown in FIG. 3B, the motor housing 10 is provided with oil holes 102 (102a, 102b, 102c) that allow the lubricating oil passage 101 and the clearance CL to communicate with each other.
Each of the oil holes 102 (102a, 102b, 102c) is formed with the same inner diameter.

In this embodiment, in order to discharge more lubricating oil OL from the deep side of the lubricating oil passage 101, the oil hole 102a on the far side is made larger than the other oil holes 102b and 102c. have set.
Specifically, as an example, the largest number of oil holes 102a is four, and there are two oil holes 102b on the front side and two oil holes 102c in an intermediate area between the front side and the back side. .

Further, the oil hole 102a on the far side is provided with a gap Da between the other adjacent oil hole 102a, and the oil hole 102b on the front side is provided with a gap Db between the other adjacent oil hole 102b. is provided. The oil hole 102c in the middle area is provided with a gap Dc between the adjacent oil holes 102a, 102b, and 102c.

The intervals Da, Db, and Dc are set so as to satisfy Da<Db<Dc.
Therefore, in the gap CL between the outer circumference 251c of the yoke portion 251 and the inner circumference 10c of the motor housing 10, the amount of lubricating oil OL supplied from the deep side of the lubricating oil passage 101 (the region where the oil hole 102a is provided) is becomes the most common. Then, the amount of lubricating oil OL supplied from the front side of lubricating oil passage 101 (the region where oil hole 102b is provided) increases next, and the amount of lubricating oil OL supplied from the intermediate region (the region where oil hole 102c is provided) increases. supply is the lowest.

Here, if the oil holes 102 are provided at regular intervals in the direction of the axis X1, the amount of the lubricating oil OL discharged into the clearance CL decreases toward the inner side of the lubricating oil passage 101 . As a result, there is a possibility that cooling of the motor 2 will be insufficient on the far side in the direction of the axis X1 than on the front side.

Here, the gap CL between the outer circumference 251c of the yoke portion 251 and the inner circumference 10c of the motor housing 10 is opened on the side of the other end 251b of the yoke portion 251. As shown in FIG. Therefore, the lubricating oil OL discharged from the front side of the lubricating oil passage 101 into the clearance CL moves toward the other end 251b of the yoke portion 251 (right side in the figure) within the clearance CL. The motor 2 is cooled during the movement of the lubricating oil OL.

In this embodiment, the intervals Da, Db, and Dc are set so that the supply distribution of the lubricating oil OL is as described above, so that the motor 2 is evenly cooled in the rotation axis X direction. there is

Lubricating oil OL is supplied to the lubricating oil path 101 from the one end 10a side of the motor housing 10 .
As shown in FIG. 3A, one end 10a of the motor housing 10 is provided with a boss portion 103 surrounding the lubricating oil passage 101. As shown in FIG. The boss portion 103 protrudes from the joint portion 100 of the motor housing 10 to the inner cover 12 toward the counter gear 5 (left side in the figure).
In the inner cover 12 , a through hole 120 a is formed in the joint portion 120 of the inner case 14 and the second support portion 145 . The through-hole 120a is provided at a position concentric with the rotation axis (axis X1) of the counter gear 5 when the joint portion 120 of the inner cover 12 is joined to the second support portion 145 of the inner case 14 .

The boss portion 103 surrounding the lubricating oil passage 101 penetrates the through hole 120a of the joint portion 120 in the direction of the axis X1. A seal ring S surrounding the lubricating oil passage 101 is provided at the tip 103 a of the boss portion 103 . The boss portion 103 brings the seal ring S provided at the tip 103a into contact with the concave portion 146 surrounding the opening 145a of the second support portion 145 from the direction of the axis X1.

In this embodiment, when the motor housing 10, the inner cover 12, and the inner case 14 are assembled in the direction of the rotation axis X, the lubricating oil passage 101 in the motor housing 10 extends along the rotation axis (axis line X1) of the counter gear 5. placed in In this state, the lubricating oil passage 101 is arranged concentrically with the axis X<b>1 and is arranged with an opening facing the hollow shaft portion 51 of the counter gear 5 .

As shown in FIG. 2, the hollow shaft portion 51 of the counter gear 5 is provided with an in-shaft oil passage 510 . The in-shaft oil passage 510 is formed over the entire length of the hollow shaft portion 51 in the longitudinal direction (the direction of the axis X1).

As described above, one end 51a of the hollow shaft portion 51 is supported by the second support portion 135 of the outer case 13 via the bearing B4, and the other end 51b of the hollow shaft portion 51 is supported via the bearing B4 by the inner case 14. is rotatably supported by the second support portion 145 of the.

One end 510 a of the in-shaft oil passage 510 opens into the space S 1 surrounded by the second support portion 135 on the one end 51 a side of the hollow shaft portion 51 . The other end 510 b of the in-shaft oil passage 510 opens into the space S 2 surrounded by the second support portion 145 on the other end 51 b side of the hollow shaft portion 51 .

The outer case 13 has an inclined wall portion 136 extending outward in the radial direction of the axis X1 from the outer peripheral portion of the second support portion 135 .
As shown in FIG. 2, the inclined wall portion 136 extends upward in the gravitational direction and is inclined toward the inner case 14 (rightward in the drawing) toward the outer diameter side (upward in the gravitational direction). there is

A connecting portion between the inclined wall portion 136 and the second support portion 135 is provided with an annular wall 139 surrounding the axis X1 at a predetermined interval.
The annular wall 139 is formed with an opening diameter that allows insertion of the bearing B4. The annular wall 139 protrudes toward the motor 2 (to the right in the drawing) from the connecting portion between the inclined wall portion 136 and the second support portion 135 . Therefore, the annular wall 139 is positioned on the inner diameter side (axis X1 side) of the inclined wall portion 136 .

The second support portion 135 is provided with an oil passage 134 that opens to the outer diameter side of the annular wall 139 .
The oil passage 134 includes a first oil passage 134a extending in the second support portion 135 in a direction away from the motor 2 (left direction in the drawing), a first oil passage 134a, and a space S1 inside the second support portion 135. and a second oil passage 134b that communicates with.

In the outer case 13 , the outer diameter side end of the inclined wall portion 136 is connected to the outer peripheral wall portion 137 .
The outer peripheral wall portion 137 is provided on the outer diameter side of the counter gear 5 so as to surround the axis X1 with a predetermined interval. The outer peripheral wall portion 137 is provided parallel to the axis X1, and a joint portion 138 with a joint portion 148 of the inner case 14 is provided at the end portion of the outer peripheral wall portion 137 on the inner case 14 side. .

The joint portion 138 of the outer case 13 is joined to the joint portion 148 of the inner case 14 from the rotation axis X direction. The inner case 14 has an outer peripheral wall portion 147 extending from the joint portion 148 toward the motor 2 (right side in the figure). The outer peripheral wall portion 147 is an extension of the outer peripheral wall portion 147 of the outer case 13 and is provided parallel to the axis X1. The outer peripheral wall portion 147 is also provided on the outer diameter side of the counter gear 5 so as to surround the axis X1 at predetermined intervals.

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, a counter gear 5, a differential gear 6, and a drive shaft 8 (8A, 8B) are provided along the transmission path of the output rotation of the motor 2. there is

When the rotor core 21 is rotated around the rotation axis X by driving the motor 2 , rotation is input to the counter gear 5 via the motor shaft 20 that rotates integrally with the rotor core 21 .

In the counter gear 5, a large-diameter gear 52 meshing with the transmission gear 26 of the motor shaft 20 serves as an input portion for output rotation of the motor 2, and a small-diameter gear portion 511 meshing with the final gear FG of the differential case 60 serves as an input portion. 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. 1).
Therefore, the rotation input to the counter gear 5 is largely 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 is meshed.

Then, the drive shaft 8 (8A, 8B) rotates about the rotation axis X when the differential case 60 rotates about the rotation axis X due to 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 on which the power transmission device 1 is mounted.

Here, as described above, inside the second case member (outer case 13, inner case 14) housing the counter gear 5 and the differential gear 6, the cooling medium (lubricating oil OL) is filled up to a predetermined height. are stored.
In the case of the power transmission device 1, the lubricating oil OL in the second case member is raked up by the differential gear 6 (differential case 60) rotating around the rotation axis X.

A portion of the lubricating oil OL that is raked up by the differential gear 6 (differential case 60 ) and supplied to the counter gear 5 reaches the outer peripheral wall portions 137 and 147 that surround the outer periphery of the counter gear 5 .
As described above, the outer peripheral wall portions 137 and 147 are located on the upper side in the gravitational direction based on the mounting state of the power transmission device 1 on the vehicle. Therefore, the lubricating oil OL that has reached the outer peripheral wall portions 137 and 147 moves or drops in the second case member (the outer case 13 and the inner case 14) downward toward the differential gear 6 due to its own weight.

As shown in FIG. 2, part of the lubricating oil OL that has reached the outer wall portions 137 and 147 travels along the inner circumference of the inclined wall portion 136 of the outer case 13 and moves downward toward the axis X1.
An annular wall 139 protruding toward the motor 2 (right side in the figure) is provided at the connecting portion between the inclined wall portion 136 and the second support portion 135, and an oil passage is provided on the outer diameter side of the annular wall 139. 134 is open.

Therefore, the lubricating oil OL, which has moved downward on the axis X1 side along the inner circumference of the inclined wall portion 136 , flows through the oil passage 134 into the space S1 inside the second support portion 135 .
An in-shaft oil passage 510 of the counter gear 5 opens into the space S1. Therefore, the lubricating oil OL that has flowed into the space S1 moves through the in-shaft oil passage 510 from the one end 510a toward the other end 510b.

The other end 510b of the in-shaft oil passage 510 opens into a space S2 within the second support portion 145 that supports the other end 51b of the hollow shaft portion 51 of the counter gear 5. In this space S2, A lubricating oil passage 101 on the motor housing 10 side is open.
Therefore, the lubricating oil OL that has moved through the in-shaft oil passage 510 from one end 510 a toward the other end 510 b flows into the lubricating oil passage 101 located on the extension of the in-shaft oil passage 510 .

In the lubricating oil passage 101 , oil holes 102 ( 102 a , 102 b , 102 c ) are provided in a region on the outer diameter side of the yoke portion 251 of the motor 2 .
The oil hole 102 allows the gap CL between the inner periphery of the motor housing 10 and the outer periphery of the yoke portion 251 to communicate with the lubricating oil passage 101 .

Therefore, the lubricating oil OL that has flowed into the lubricating oil passage 101 is supplied to the clearance CL through the oil hole 102 to cool the heat-generating motor 2 from the outer peripheral side of the yoke portion 251 .
As a result, part of the lubricating oil OL scraped up by the differential gear 6 (differential case 60 ) rotating around the rotation axis X can be supplied to the outer peripheral side of the motor 2 and utilized for cooling the motor 2 .

Here, the motor housing 10, the outer cover 11, and the inner cover 12 constitute a case member according to the invention.
The oil passage 134 of the outer case 13, the in-shaft oil passage 510 of the hollow shaft portion 51, the lubricating oil passage 101 of the motor housing 10, and the gap CL between the inner periphery 10c of the motor housing 10 and the outer periphery 251c of the yoke portion 251. , and an oil hole 102 that communicates the lubricating oil passage 101 and the clearance CL, constitutes a motor cooling structure in the power transmission device 1 .

As described above, the power transmission device 1 according to this embodiment has the following configuration.
(1) The power transmission device 1 is
a motor 2;
a counter gear 5 connected downstream of the motor 2;
and a first case member (motor housing 10 , outer cover 11 , inner cover 12 ) that houses the motor 2 .
The counter gear 5 has a hollow shaft portion 51, and an in-shaft oil passage 510 is provided inside the hollow shaft portion 51 so as to penetrate in the direction of the rotation shaft (axis line X1).
In the first case member, a motor housing 10 surrounding the outer periphery of the motor 2 is provided with a lubricating oil passage 101 extending in the rotation axis X direction on the outer periphery of the motor 2 .
The lubricating oil passage 101 is provided across the outer diameter side of the stator core 25 (yoke portion 251) of the motor 2 in the rotation axis X direction.
The motor housing 10 is provided with an oil hole 102 that allows the lubricating oil passage 101 and the inner circumference 10c of the motor housing 10 to communicate with each other.
The lubricating oil OL is supplied to the outer periphery of the motor 2 through the shaft internal oil passage 510 , the lubricating oil passage 101 and the oil hole 102 in the hollow shaft portion 51 to cool the motor 2 .

With this configuration, it is possible to design the lubricating oil OL to be supplied to a desired position of the stator core 25 of the motor 2 by the lubricating oil passage 101 extending in the direction of the rotation axis X.
Thus, by providing the oil hole 102 toward a portion of the stator core 25 that is particularly likely to become high temperature, the portion that is likely to become high temperature can be efficiently lubricated (cooled).

The lubricating oil passage 101 is provided with its longitudinal direction along the direction of the axis X1. The lubricating oil passage 101 and the in-shaft oil passage 510 in the hollow shaft portion 51 are arranged in series on the axis X1.
When the lubricating oil OL is supplied to the motor 2 side through the shaft oil passage 510 and the lubricating oil passage 101 arranged in this way, lubricating oil is produced inside the shaft oil passage 510 and the lubricating oil passage 101. It is possible to create a state in which the oil OL always stays.
As a result, the amount of lubricating oil OL stored in the space Sb (gear chamber) between the outer case 13 and the inner case 14 is reduced by the amount of the lubricating oil OL retained inside the in-shaft oil passage 510 and the lubricating oil passage 101. . That is, both the in-shaft oil passage 510 and the lubricating oil passage 101 can be used as a catch tank for the lubricating oil OL.

Then, the height (oil surface level) of the lubricating oil OL in the space Sb (gear chamber) is lowered according to the amount of the lubricating oil OL stagnating inside the in-shaft oil passage 510 and the lubricating oil passage 101 .
As a result, the amount of lubricating oil OL stirred by the differential gear 6 (differential case 60) that rotates around the rotation axis X is reduced.
As a result, the agitation resistance of the differential case 60 can be reduced when the vehicle equipped with the power transmission device 1 is running, so the load on the motor 2 can be reduced, and an improvement in electric power consumption can be expected.

The power transmission device 1 according to this embodiment has the following configuration.
(2) The motor housing 10 (first case member) is provided with an oil hole 102a (rear side oil hole) that allows the lubricating oil passage 101 and the inner circumference 10c of the motor housing 10 to communicate with each other.
In the lubricating oil passage 101, the oil hole 102a is provided in a region on the downstream side in the flow direction of the lubricating oil OL in the lubricating oil passage 101 (a region on the far side when viewed from the counter gear 5 side).
The lubricating oil OL discharged into the motor housing 10 from the oil hole 102a is supplied to the far side end of the stator core 25 of the motor 2 located on the far side when viewed from the counter gear 5 side, and cools the far side end. do.
The counter gear 5 is positioned on the upstream side (front side) of the lubricating oil passage 101 in the lubricating oil flowing direction in the lubricating oil passage 101 .

A region on the far side of the motor 2 as viewed from the counter gear 5 side is positioned downstream in the direction in which the lubricating oil OL flows in the lubricating oil passage 101 . Therefore, the region on the far side of the motor 2 is located at a position where it is difficult to supply the lubricating oil OL, and is a region that is difficult to cool.
As described above, by providing the oil hole 102a in the region of the lubricating oil passage 101 on the downstream side in the flow direction of the lubricating oil OL (the region on the far side when viewed from the counter gear 5 side), the motor 2 is hard to be cooled. Lubricating oil OL can be positively supplied to the region on the far side. As a result, it is possible to increase the cooling efficiency of the region on the far side of the motor 2 that is difficult to cool.

The power transmission device 1 according to this embodiment has the following configuration.
(3) The motor housing 10 (first case member) is provided with an oil hole 102b (front side oil hole) that allows the lubricating oil passage 101 and the inner circumference 10c of the motor housing 10 to communicate with each other.
In the lubricating oil passage 101, the oil hole 102b is provided in an upstream region in the lubricating oil passage 101 in the flow direction of the lubricating oil OL (a region on the front side when viewed from the counter gear 5 side).
The lubricating oil OL discharged into the motor housing 10 through the oil hole 102b is supplied to the front end of the stator core 25 of the motor 2 located on the front side when viewed from the counter gear 5 side, and cools the front end. do.

A region on the front side of the motor 2 when viewed from the counter gear 5 side is positioned upstream in the direction in which the lubricating oil OL flows in the lubricating oil passage 101 . With the configuration as described above, the lubricating oil OL can be supplied to the region on the front side of the motor 2 . Thereby, the cooling efficiency of the region on the front side of the motor 2 can be improved.

The power transmission device 1 according to this embodiment has the following configuration.
(4) Between the stator core 25 (yoke portion 251) of the motor 2 and the motor housing 10 (first case member), a radial gap CL (clearance) of the rotation axis X is provided.
The lubricating oil OL discharged from the oil holes 102 (102a, 102b, 102c) is supplied to the clearance CL between the outer circumference 251c of the yoke portion 251 and the inner circumference 10c of the motor housing 10, and the stator core 25 (yoke portion 251) is cooled from the outer diameter side.

Instead of press-fitting the stator core 25 of the motor 2 into the inner circumference of the motor housing 10 (first case member), a clearance CL is provided between the stator core 25 and the motor housing 10 , so that the stator core 25 is removed from the motor housing 10 . heat conduction to the side can be reduced.
Furthermore, by supplying the lubricating oil OL to the gap CL (clearance), the stator core 25 can be cooled by the lubricating oil OL passing through the outer circumference of the stator core 25, so the cooling efficiency of the motor 2 is improved.
In addition, by supplying the lubricating oil OL to the gap CL (clearance) and filling the gap CL with the lubricating oil OL, it leads to a damping effect against the vibration of the motor 2, which is preferable.

In particular, the gap CL between the inner circumference 10c of the motor housing 10 and the stator core 25 (yoke portion 251) of the motor 2 is closed at the front side as viewed from the counter gear 5 and opened at the back side. are doing.
Therefore, the lubricating oil OL discharged from the oil hole 102b into the clearance CL is discharged from the clearance CL after moving from the region on the near side as viewed from the counter gear 5 side to the region on the far side.
As a result, the lubricating oil OL discharged from the oil hole 102b into the clearance CL cools the motor 2 in the process of moving from the area on the front side to the area on the back side as viewed from the counter gear 5 side.
By using both the oil holes 102a and 102b, it is possible to cool the entire motor 2 while securing the cooling efficiency of the region on the far side of the motor 2 that is difficult to be cooled.

Here, the term "connected downstream" in this specification means that there is a connection relationship in which power is transmitted from a part arranged upstream to a part arranged downstream.
For example, the counter gear 5 connected downstream of the motor 2 means that power is transmitted from the motor 2 to the counter gear 5 .
In this specification, the term "direct connection" means that members are connected to each other so as to be able to transmit power without passing through a member such as another speed reduction mechanism, speed increasing mechanism, or speed change mechanism that changes the speed reduction ratio. means

In the embodiment described above, in order to discharge more of the lubricating oil OL from the deep side of the lubricating oil passage 101, the following was done.
(a) Each of the oil holes 102 (102a, 102b, 102c) is formed with the same inner diameter, and the number of the inner oil holes 102a is made larger than the other oil holes 102b, 102c.
Instead of this configuration, the inner diameter of the oil hole 102 located on the far side of the lubricating oil passage 101 is increased so that more lubricating oil OL is discharged from the far side of the lubricating oil passage 101. Also good.

In the embodiment described above, the lubricating oil raked up by the differential case 60 rotating around the rotation axis X is guided to the in-shaft oil passage 510 and supplied from the in-shaft oil passage 510 to the lubricating oil passage 101. exemplified.
For example, when the power transmission device 1 is equipped with an oil pump OP, the following configuration may be used.
- An oil passage is provided in the outer case 13 to allow the oil pump OP and the space S1 surrounded by the second support portion 135 of the outer case 13 to communicate with each other.
The lubricating oil OL discharged by the oil pump OP is supplied to the lubricating oil passage 101 through the in-shaft oil passage 510 to cool the motor 2 .

Although the embodiments of the present invention have been described above, the present invention is not limited only to the aspects shown in these embodiments. It can be changed as appropriate within the scope of the technical idea of the invention.

Reference Signs List 1 power transmission device 10 motor housing 100 joint 101 lubricating oil passage 102 (102a, 102b, 102c) oil hole 103 boss 10c inner circumference 10d stopper 11 outer cover 110 joint 111 motor support 114 opening 12 inner cover 120 joint Part 120a Through hole 121 Motor support 13 Outer case 130 Opening 131 First support 134 Oil passage 134a First oil passage 134b Second oil passage 135 Second support 136 Inclined wall 137 Peripheral wall 138 Joint 139 Annular Wall 14 Inner case 141 Supporting part 145 Second supporting part 145a Opening 146 Recessed part 147 Outer peripheral wall part 148 Joining part 15 Supporting member 151 Supporting part 152 Cylindrical part 153 Flange part 2 Motor 20 Motor shaft 200 Insertion hole 201 Connecting part 202 Supported Part 203 Intermediate Region 204 Large Diameter Part 21 Rotor Core 25 Stator Core 251 Yoke Part 251c Outer Periphery 252 Teeth Part 253 Windings 253a, 253b Coil Ends 254 Bracket 26 Transmission Gear 5 Counter Gear 51 Hollow Shaft Part 510 Shaft Oil Path 511 Small Diameter Gear Part 52 Large-diameter gear 6 Differential gear 60 Differential case 601, 602 Support part 61 Shaft 62A, 62B Bevel gear 63A, 63B Side gear 8 (8A, 8B) Drive shaft 9 Body case B Bolt B1, B2, B3, B4 Bearing CL Gap FG Final Gear N Nut NB Needle bearing OL Lubricant P Pin RS Lip seal S Seal ring Sa Space (motor chamber)
Sb space (gear room)
X rotation axis X1, Y axis

Claims (4)

a motor;
a counter gear connected downstream of the motor;
a differential connected downstream of the counter gear;
a case member that houses the motor , the counter gear, and the differential ,
The motor, the counter gear, and the differential are arranged in this order along the rotation axis direction of the motor,
The counter gear has a hollow shaft,
The hollow shaft portion is arranged on the outer diameter side of the differential device, one end portion on the differential device side is supported by a first support portion of the case member, and the other end portion on the motor side is supported by the first support portion of the case member. is supported by the second support portion of the case member,
The first support portion is provided with a communication passage that communicates between the internal space of the case member and the internal space of the hollow shaft portion,
A lubricating oil passage extending in the direction of the rotating shaft is opened in the second support portion on the outer periphery of the motor,
A part of the lubricating oil raked up by the rotation of the differential device flows into the hollow shaft portion through the communicating passage and is supplied to the motor via the lubricating oil passage. power transmission device. In claim 1,
The case member is provided with a back side oil hole for supplying lubricating oil through the lubricating oil passage to a back side end portion of the stator of the motor located on the back side as viewed from the counter gear side. A power transmission device characterized by: In claim 1 or 2,
A front side oil hole for supplying lubricating oil through the lubricating oil passage is provided in the case member at a front side end portion of the stator of the motor positioned on the front side as seen from the counter gear side. A power transmission device characterized by: In any one of claims 1 to 3,
The stator of the motor and the case member have a radial clearance,
A power transmission device according to claim 1, wherein the case member is provided with an oil hole for supplying lubricating oil to the clearance through the lubricating oil passage.

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