JP2019128010A - Case structure of drive unit - Google Patents

Abstract

To provide a case structure of a drive unit which can install a prescribed component at a support part by making the component close thereto while securing the rigidity of the support part, and can easily reduce a size of a case.SOLUTION: A left case 2 includes: a bearing support part 12 arranged at a left vertical wall 5, and rotatably supporting an input shaft 14 via a bearing; and a lower-side recess 29 formed at the left vertical wall 5 around the bearing support part 12, and bulged to the outside of the input shaft 14 in an axial line direction from the left vertical wall 5 so as to accommodate a parking rod 35, a manual shaft 37 and a manual plate 40. The left case 2 includes a second retainer 42 for connecting a boss part 54 arranged below the bearing support part 12, and a boss part 55 located at a side opposite to the boss part 54 while striding over the lower-side recess 29 from the boss part 54.SELECTED DRAWING: Figure 9

Description

  The present invention relates to a case structure of a driving device.

  The vehicle is provided with a transmission having a parking lock mechanism, and in order to miniaturize the transmission, the parking lock mechanism is in the vicinity of a bearing support that rotatably supports an output shaft to which a parking gear is attached. (See Patent Document 1).

JP, 2006-40480, A

  Such a conventional parking lock mechanism is installed in the vicinity of the bearing support portion, and its storage space is required in the drive device. Further, in consideration of mountability of the drive device on the vehicle, it is necessary to reduce the outer dimensions of the drive device such as a transmission and a reduction gear, so that a recess space is required to accommodate the parking lock mechanism in the case of the drive device. And a parking lock mechanism may be disposed in the recess space. However, since the parking lock mechanism is installed in the vicinity of the bearing support portion, if the housing recess is formed in the vicinity of the bearing support portion of the case of the drive device, the rigidity of the bearing support portion may not be ensured.

  The present invention has been made paying attention to the above-described circumstances, and even if a housing recess is formed in the vicinity of the bearing support portion of the case of the drive device, the case rigidity of the bearing support portion can be secured, and a predetermined part can be secured. An object of the present invention is to provide a case structure that can be installed close to a bearing support portion and can easily achieve miniaturization of a drive device.

  The present invention includes a wall portion, a bearing support portion that is provided on the wall portion and rotatably supports a rotating shaft via a bearing, and is formed on the wall portion around the bearing support portion. A case structure of a drive device having a recess which bulges outward in the axial direction of the rotary shaft from the wall so as to be accommodated, wherein one side of the recess is located around the bearing support. A connecting member for connecting the first portion and the second portion across the recess, the first portion of the wall portion, the second portion of the wall portion positioned on the other side of the recess, and It is characterized by having.

  As described above, according to the present invention, the predetermined part can be installed close to the bearing support part while securing the storage space for the predetermined part, and the rigidity of the support part can be ensured. The size of the apparatus can be easily reduced.

FIG. 1 is a drive device provided with a parking lock mechanism according to an embodiment of the present invention, and is a perspective view of the drive device with the light case removed. FIG. 2 is an inner side view showing the inside of the drive device as seen from the axial direction of the input shaft of the drive device in the state of FIG. FIG. 3 is a cross-sectional view taken along the line III-III in FIG. 2 and shows a state where the input shaft is removed. 4 is a cross-sectional view taken along the line IV-IV in FIG. 2 and shows a parking lock state. FIG. 5 is a view in which the first retainer and the like are removed from the inner side view of FIG. 2, and shows the attached state of the second retainer. FIG. 6 is a diagram in which the second retainer and the like are removed from the inner side view of FIG. 5 and shows the positional relationship between the first retainer and the boss portion to which the second retainer is fixed. 7 is a cross-sectional view taken along the line VII-VII in FIG. FIG. 8 is a sectional view taken along the line VIII-VIII in FIG. FIG. 9 is a cross-sectional view taken along arrow IX-IX in FIG. FIG. 10 is a cross-sectional view in the direction of arrows XX in FIG. 13 in a state in which the parking lock mechanism is housed in a case, and shows a parking lock state. 11 is a cross-sectional view taken along the line XX in FIG. 13 in a state where the parking lock mechanism is housed in the case, and shows the parking lock released state. FIG. 12 is a right side view of the parking lock release state of the parking lock mechanism according to the embodiment of the invention. FIG. 13 is a left side view of the parking lock release state of the parking lock mechanism according to the embodiment of the present invention.

The case structure of the drive device according to one embodiment of the present invention includes a wall portion, a bearing support portion provided on the wall portion and rotatably supporting a rotary shaft through a bearing, and a wall around the bearing support portion. A case structure of a drive device having a recess formed in the recess and extending outward in the axial direction of the rotation shaft from the wall so as to accommodate a predetermined part, wherein one side of the recess supports the bearing support It has a first member of the wall located in the periphery, a second member of the wall located on the other side of the recess, and a connecting member for connecting the first portion and the second portion across the recess. ing.
As a result, a predetermined component can be placed close to the bearing support while securing the rigidity of the bearing support, and the case can be easily miniaturized.

Hereinafter, a case structure of a driving apparatus according to an embodiment of the present invention will be described with reference to the drawings.
FIGS. 1 to 13 are views showing a driving device having a parking lock device according to an embodiment of the present invention. 1 to 13, upper, lower, front, rear, left, and right directions are upper, lower, front, rear, left, and right directions of the drive device installed in the vehicle with respect to the mounted, up, down, front, rear, left, and right. The horizontal direction and the height direction of the driving device are the vertical direction. Further, the depth direction is a direction perpendicular to the mating surfaces of the left and right cases of the drive device, and the mating surface side is referred to as the near side, and the non-coincidence surface side is referred to as the back side. Specifically, in the left case to which the present invention is applied, the near side is the right side in the vehicle mounted state, and the far side is the left side in the vehicle mounted state.

First, the configuration will be described.
In FIG. 1, a drive device 1 is mounted on a vehicle, for example, and decelerates the rotation of a motor (not shown) for driving the vehicle and transmits it to drive wheels (not shown). The driving device 1 includes a left case 2 disposed on the left side and a light case 4 disposed on the right side. The left and right cases are combined to form an outer shell of the drive device 1, and a gear and a parking lock device are disposed inside thereof. Further, the input shaft 14, the counter shaft 16, and the differential device 20, which are built in the left and right cases, are disposed along the left and right direction, and are supported by the left and right cases in a bridged state via bearings. .

  The outer periphery of the left case 2 is provided with a first joint 3A and a second joint 3B as the joint 3, and the first case 3A and the second joint 3B have a right case 4 ( The joint 4A and the joint 4B (see FIG. 4) provided on the outer peripheral edge of FIG. 4 and FIG. 7 are joined. That is, the first joint 3A and the second joint 3B of the left case 2 constitute a mating surface with the light case 4. This mating surface is a surface perpendicular to the left-right direction, and the first joint portion 3A extends along the front-rear direction at a position above and below the mating surface, and the second joint portion 3B is a position before and after the mating surface. It extends along the vertical direction.

  The joint 4A and the joint 4B extend in the front-rear direction and the vertical direction of the light case 4 in the same manner as the first joint 3A and the second joint 3B. 2 is in a plane-symmetrical relationship with the joint portion 3B. The light case 4 of the present embodiment constitutes a case member of the present invention.

  The left case 2 and the right case 4 are arranged such that the first joint portion 3A and the second joint portion 3B are aligned with the joint portion 4A and the joint portion 4B, and the first joint portion 3A and The joint 4A, the second joint 3B, and the joint 4B are fastened to be integrated.

  In the driving device 1, an outer shell is formed by the left case 2 and the right case 4, and a sealed space is formed inside the outer shell. The left case 2 of the present embodiment constitutes the case of the present invention.

  The first joint 3 </ b> A extends in the front-rear direction at the upper and lower end edges of the left case 2. The second joint 3 </ b> B extends in the vertical direction at the front and rear edges of the left case 2. The rear second joint 3B extends in the vertical direction while being curved along the outer peripheral edge of the final driven gear 22 described later.

  On the back side (left side) in the depth direction of the left case 2, a left vertical wall 5 constituting a side wall on the left side of the drive device 1 is provided. The left case 2 has a rear vertical wall 7 that extends rightward from the rear end of the left vertical wall 5 (see FIG. 4). The front end of the rear vertical wall 7 extending rightward is a joint 3B. The left case 2 has a front vertical wall 8, and the front vertical wall 8 extends rightward from the front end of the left vertical wall 5. The front end of the front vertical wall 8 extending rightward is a joint 3B.

  The left case 2 has an upper wall 9 (see FIG. 3). The upper wall 9 extends rightward from the upper end of the left vertical wall 5 and connects the upper end of the rear vertical wall 7 and the upper end of the front vertical wall 8 doing. The tip of the upper wall 9 extending to the right is a joint 3A.

  The left case 2 has a bottom wall 10 (see FIG. 3), and the bottom wall 10 extends rightward from the lower end of the left vertical wall 5 and connects the lower end of the rear vertical wall 7 and the lower end of the front vertical wall 8 doing. The right end of the bottom wall 10 is a joint 3A. As a result, a space 11 surrounded by the left vertical wall 5, the rear vertical wall 7, the front vertical wall 8, the upper wall 9 and the bottom wall 10 is formed inside the left case 2. A mating surface is formed on the right end of each of the rear vertical wall 7, the front vertical wall 8, the top wall 9 and the bottom wall 10.

  1 and 2, the left vertical wall 5 is formed with a bearing support portion 12 (first bearing support portion) that has a space for housing the bearing 13 therein and holds the bearing. The bearing support portion 12 extends from the left vertical wall 5 so as to protrude from the left vertical wall 5 into the inner space of the drive device 1 on the front side (right side). The bearing support 12 supports the input shaft 14 via a bearing 13. That is, one end portion in the axial direction of the input shaft 14 is rotatably supported by the bearing support portion 12 via the bearing 13. The bearing support 12 of the present embodiment constitutes a bearing support of the present invention.

  The other axial end of the input shaft 14 is rotatably supported by a bearing support (not shown) provided on the light case 4 via a bearing 26A (see FIG. 7). Thus, the input shaft 14 is rotatably supported by the left case 2 and the light case 4 along the left-right direction. The input shaft 14 of the present embodiment constitutes the rotary shaft of the present invention.

  The input shaft 14 is a rotating shaft that receives a driving force from a driving force source such as a motor in the driving device 1. An input gear 15 for transmitting a driving force is provided on the input shaft 14 in the vicinity of the bearing support 12 of the left vertical wall 5, and the input gear 15 rotates integrally with the input shaft 14.

  A second bearing support (not shown) is formed on the left vertical wall 5, and the second bearing support is formed side by side with the bearing support 12 in the front-rear direction. Specifically, the second bearing support portion is formed slightly below the rear side of the bearing support portion 12. One end portion of the counter shaft 16 in the axial direction is rotatably supported by the second bearing support portion via a bearing (not shown).

  The counter shaft 16 is disposed slightly behind the input shaft 14 in parallel with the input shaft 14, and the other axial end of the counter shaft 16 is supported by a bearing support portion (not shown) provided in the light case 4. It is rotatably supported via 26B (see FIG. 7).

  Thus, the counter shaft 16 is rotatably supported by the left case 2 and the right case 4. The axial directions of the input shaft 14 and the counter shaft 16 are axial directions of the respective rotation central axes, and are directions in which the input shaft 14 and the counter shaft 16 extend (left and right direction, depth direction of the left case 2).

  The counter shaft 16 is provided with a counter gear 17, a parking gear 18 and a final drive gear 19 in order from the left vertical wall 5 side. The counter gear 17, the parking gear 18 and the final drive gear 19 are integrated with the counter shaft 16. Rotate at. The counter gear 17 has a larger diameter than the input gear 15 and meshes with the input gear 15.

  That is, the counter shaft 16 receives driving force from the input gear 15 of the input shaft 14 by the counter gear 17, and conversely, the input shaft 14 receives reaction force from the counter gear 17 of the counter shaft 16 by the input gear 15. The counter gear 17 and the parking gear 18 have substantially the same outer diameter. The final drive gear 19 has a smaller diameter than the counter gear 17 and the parking gear 18.

  A differential device 20 is provided on the rear side opposite to the input shaft 14 with respect to the counter shaft 16. The differential device 20 includes a differential case 21, a final driven gear 22 attached to the outer periphery of the differential case 21, and a differential mechanism 23 accommodated in the differential case 21.

  The differential case 21 has a support cylinder part 21A on the right side, and the support cylinder part 21A is rotatably supported by a bearing support part (not shown) provided in the light case 4 via a bearing (not shown). The center of rotation of the differential case 21 is disposed slightly behind the counter shaft 16 in parallel with the counter shaft 16.

  The differential case 21 has a support cylinder (not shown) on the left side on the left vertical wall 5 side, and this support cylinder is connected to a third bearing support (not shown) provided on the left vertical wall 5 via a bearing (not shown). And is supported rotatably. As a result, the differential case 21 is disposed with its pivot axis in the left-right direction, and is rotatably supported by the left case 2 and the light case 4.

  The third bearing support portion is formed side by side with the second bearing support portion in the front-rear direction. In detail, the third bearing support is formed slightly behind the second bearing support. For this reason, the 1st bearing support part (bearing support part 12), the 2nd bearing support part, and the 3rd bearing support part are arranged in the left vertical wall 5 along with linear form.

  The final driven gear 22 has a larger diameter than the input gear 15 and the counter gear 17, and achieves a large reduction ratio by meshing with the final drive gear 19 having a smaller diameter than the input gear 15 and the counter gear 17.

  One end portions of left and right drive shafts (not shown) are respectively inserted into the right support cylindrical portion 21A and the left support cylindrical portion, and one end portions of the left and right drive shafts are connected to the differential mechanism 23. The differential mechanism 23 distributes the driving force to the left and right drive shafts so as to be differentially rotatable.

  The other ends of the left and right drive shafts are respectively connected to drive wheels (not shown), and the left and right drive shafts transmit the driving force from the differential mechanism 23 to the drive wheels.

  When driving force of a motor (not shown) is transmitted to input shaft 14, driving device 1 transmits power from input gear 15 to counter shaft 16 via counter gear 17, and then from final drive gear 19 to final driven gear 22. Power is transmitted to the

  As a result, the differential case 21 rotates, the driving force of the motor is distributed to the left and right drive shafts by the differential mechanism 23, the left and right drive shafts rotate, and the left and right drive shafts rotate, whereby the motor driving force is changed to the left and right drive shafts. Is transmitted to the driving wheel. As a result, the driving wheel rotates and the vehicle travels.

  A parking lock mechanism 31 is accommodated in the left case 2. The parking lock mechanism 31 includes a parking gear 18, a parking pole 32, a parking pole shaft 33, a return spring 34 (see FIGS. 5 and 6), and a parking rod 35 (see FIG. 4).

  Furthermore, the parking lock mechanism 31 includes a support member 36 (see FIG. 4), a manual shaft 37, a detent plate 38, a detent spring 39, a manual plate 40, a first retainer 41 and a second retainer 42.

  In the parking lock mechanism 31, all parts constituting the parking lock mechanism 31 are accommodated in the left case 2. That is, in the drive device 1 according to one embodiment of the present invention, the parking lock mechanism 31 is attached only to the left case 2 except the parking gear 18, and the light case 4 is not necessary for the attachment. Improvements and improvements in mechanism reliability have been made.

  The parking gear 18 is provided between the counter gear 17 and the final driven gear 22 in the direction in which the counter shaft 16 extends. On the outer periphery of the parking gear 18, a plurality of teeth 18A are provided at equal intervals in the circumferential direction. Between the teeth 18A, a groove is formed in a cut-off state along the axial direction of the counter shaft 16 and into which the claws 32A of the parking pole 32 enter.

  The parking pole 32 is swingably supported by the left vertical wall 5 via the parking pole shaft 33 when the parking pole shaft 33 penetrates, and swings around the parking pole shaft 33. That is, the parking pole 32 is disposed below the input shaft 14 and the counter shaft 16, and its rear end is swingably supported by the parking pole shaft 33 disposed below the counter shaft 16, and its front end is rocked. It is the tip part of the movement (the part where the moving distance by the rocking is large).

  The parking pole 32 is formed with a claw portion 32A that protrudes toward the parking gear 18 at the tip of the swing. When the parking pole 32 swings in one direction (direction approaching the parking gear 18) about the parking pole shaft 33, the claw portion 32A enters the groove of the parking gear 18 and meshes with the tooth portion 18A.

When the parking pawl 32 swings in the other direction (a direction away from the parking gear 18) about the parking pawl shaft 33, the engagement between the pawl 32A and the tooth 18A is released.
Thus, the parking pole 32 swings around the parking pole shaft 33 between the meshing position where the claw portion 32A and the tooth portion 18A mesh with each other and the release position where the meshing between the claw portion 32A and the tooth portion 18A is released. Do.

  When the claws 32A mesh with the teeth 18A, the parking gear 18 can not rotate and the rotation of the counter shaft 16 is restricted. Since the final drive gear 19 of the counter shaft 16 meshes with the final driven gear 22 of the differential device 20, the rotation of the final driven gear 22 is restricted when the counter shaft 16 cannot be rotated. As a result, when the claw portion 32A meshes with the tooth portion 18A, the rotation of the driving wheel is restricted and the vehicle is kept stopped.

  As shown in FIG. 4, a boss portion 51 is provided on the left vertical wall 5 of the left case 2, and a parking pole shaft 33 is supported by the boss portion 51 by being inserted into a hole of the boss portion 51. The parking pole shaft 33 of the present embodiment constitutes a support shaft of the present invention. As shown in FIG. 6, the boss portion 51 is provided on the left vertical wall 5 at a position close to the bottom wall 10 below the counter shaft 16 when viewed from the axial direction. The boss portion 51 is on the front side (right side) from the left vertical wall 5 and protrudes from the left vertical wall 5 into the internal space of the drive device 1. At the tip of the boss 51 in the protruding direction, a contact surface with which the parking pole 32 contacts and a hole into which the parking pole shaft 33 is inserted are formed.

  A small diameter portion 51A is formed at the tip of the boss 51 in the protruding direction, and the outer diameter of the small diameter portion 51A is smaller than the base side (rear side) of the boss 51. The back side is the side of the left vertical wall 5 with respect to the first joint 3 </ b> A and the second joint 3 </ b> B, and the near side is the first joint 3 </ b> A with respect to the left vertical wall 5. And the side of the second joint 3B.

  A return spring 34 acting on the parking pole 32 is attached to the small diameter portion 51A. The return spring 34 includes a winding portion 34A wound around the small diameter portion 51A (see FIG. 13), and the winding portion 34A is installed on the outer peripheral portion of the small diameter portion 51A (see FIGS. 4 and 5). That is, the small diameter portion 51 </ b> A is inserted into the coiled portion of the winding portion 34 </ b> A of the return spring 34. In FIG. 5, the return spring 34 has a first arm portion 34B and a second arm portion 34C.

  The first arm portion 34B is in contact with the protrusion 5A provided on the left case 2, and the second arm portion 34C is in contact with the upper surface of the parking pole 32 (see FIG. 13).

  The return spring 34 biases the parking pole 32 so that the claw portion 32A moves in a direction (downward) away from the parking gear 18. Thus, the parking pole 32 is urged by the return spring 34 so as to swing from the meshing position to the release position about the parking pole shaft 33.

  That is, in FIG. 2, the parking pole 32 is urged clockwise around the parking pole shaft 33. Then, the return spring 34 presses the parking pole 32 against the upper surface of the support member 36 to restrict the swinging of the parking pole 32 in the parking lock release state.

  In FIG. 6, a parking rod 35 is installed below the bearing support portion 12. As shown in FIG. 10, the parking rod 35 has a straight portion 35A and a bent portion 35B. The straight portion 35A extends in the same direction as the axial direction of the input shaft 14 and the counter shaft 16, the bent portion 35B bends upward from the end of the straight portion 35A, and the parking rod 35 has an L shape as a whole. Is formed.

  The parking rod 35 is movable along the axial direction of the input shaft 14 and the counter shaft 16 according to the movement of the manual plate 40. The axial direction of the parking rod 35 is a direction in which the straight portion 35A extends (left and right direction, depth direction of the left case 2).

  A cam member 43 is attached to the tip of the straight portion 35A. The linear portion 35A is inserted into the cam member 43, and the cam member 43 is movable along the axial direction of the linear portion 35A at the outer peripheral portion of the linear portion 35A.

  A stopper 35a that regulates the position of the cam spring 44 is formed on the side of the bent portion 35B of the straight portion 35A. A cam spring 44 is provided around the straight portion 35A between the cam member 43 and the stopper portion 35a. A stopper portion 35b that prevents the cam member 43 from coming off is formed at the tip of the straight portion 35A.

  The cam spring 44 biases the cam member 43 in a direction away from the stopper portion 35a, and biases the cam member 43 until the cam member 43 contacts the stopper portion 35b in the parking lock release state. The stopper portion 35b is formed to have a larger diameter than the straight portion 35A, and the cam member 43 is prevented from coming out of the parking rod 35 by contacting the stopper portion 35b.

  The cam member 43 is a cylindrical member that is concentric with the straight portion 35A, and has a conical cam surface 43a that tapers from the stopper portion 35a toward the stopper portion 35b at the distal end in the extending direction of the straight portion 35A. Have.

  The bent portion 35 </ b> B is inserted into the hole of the manual plate 40, is prevented from being detached, and is attached to the manual plate 40 so as to be swingable. The manual plate 40 is attached to the manual shaft 37 in the vicinity of the bottom wall 10 on the lower end portion 37b side with respect to the upper end portion 37a of the manual shaft 37 (see FIG. 2).

  More specifically, the manual plate 40 is a flat plate-like member perpendicular to the manual shaft 37 and has an attachment cylinder portion through which the manual shaft 37 is inserted, and is attached by a spring pin that penetrates the attachment cylinder portion and the manual shaft 37. It is done. As shown in FIGS. 8 and 9, the manual plate 40 swings in the range of the outward position from the position overlapping with the bearing support 12 in the axial direction of the input shaft. And as shown in FIG. 10, the connection part of the bending part 35B and the manual plate 40 is located outward rather than the bearing 13. As shown in FIG.

  The manual shaft 37 is disposed on the front vertical wall 8 side with respect to the bearing support 12 and extends in the height direction (vertical direction) of the left case 2 orthogonal to the extending direction of the input shaft 14 and the counter shaft 16 ing. That is, the manual shaft 37 is installed along the front vertical wall 8 between the bearing support portion 12 and the front vertical wall 8. The manual shaft 37 is installed so as to overlap with the bearing support 12 within the range of the bearing support 12 in the axial direction of the input shaft 14, that is, as seen from the front-rear direction as shown in FIGS. 7 and 10.

  In FIG. 1, the upper end portion 37 a of the manual shaft 37 is rotatably supported by the upper wall 9 of the left case 2. A lower end portion 37 b of the manual shaft 37 penetrates the bottom wall 10 of the left case 2 and protrudes downward from the bottom wall 10, and is rotatably supported by the bottom wall 10.

  A lever (not shown) is attached to a portion of the lower end 37b of the manual shaft 37 projecting downward from the bottom wall 10, and one end of a parking cable (not shown) is connected to the lever. The other end of the parking cable is connected to a selector (not shown) disposed in the vehicle cabin and operated by the driver.

  The lever of the selector is moved by the driver to either the parking range or the non-parking range. At this time, the movement of the lever of the selector is transmitted via the parking cable, the manual shaft 37 rotates, and the manual plate 40 swings as the manual shaft 37 rotates, thereby moving the parking rod 35 in the axial direction. Let

  In FIG. 5, a support member 36 is installed below the bearing support 12. The support member 36 is disposed below the parking pole 32 and is disposed on the front side of the manual plate 40. The support member 36 is formed in a U shape when viewed from the axial direction of the input shaft 14 so as to match the shape of the cam member 43 so as to receive the cam member 43.

  As shown in FIG. 10, on the upper surface (U-shaped groove portion) of the support member 36, a conical surface 36 a whose diameter decreases from the back side in the depth direction of the left case 2 toward the front side (from the left side to the right side); A cylindrical surface 36b extending horizontally from the reduced diameter end of the conical surface 36a toward the near side (right side) is formed.

  Next, achievement of parking lock will be described. In the parking lock mechanism 31, when the selector is operated to the parking range, the manual shaft 37 rotates in one direction, and the manual plate 40 swings (rotates) in one direction as the manual shaft 37 rotates.

  At this time, the parking rod 35 moves to the parking pole 32 side, and as shown in FIG. 10, the cam member 43 is guided by the conical surface 36a of the support member 36 and rides on the cylindrical surface 36b. When the cam member 43 rides on the cylindrical surface 36b, the conical cam surface 43a of the cam member 43 abuts on the lower portion of the parking pole 32, and pushes the parking pole 32 upward.

  At this time, the parking pole 32 is swung counterclockwise in FIG. 2 about the parking pole shaft 33 against the urging force of the return spring 34. Then, the cylindrical portion of the cam member 43 enters between the parking pole 32 and the support member 36, and the cam member 43 suppresses the return of the parking pole 32 (swinging in the clockwise direction in FIG. 2).

  As a result, the claws 32A of the parking pole 32 engage with the teeth 18A of the parking gear 18, and the rotation of the parking gear 18 is restricted. In this state, the cam member 43 is positioned between the parking pole 32 and the support member 36 by the biasing force of the cam spring 44, so that the engagement between the claw portion 32A and the tooth portion 18A is not released.

  Note that the pawl portion 32A of the parking pole 32 and the tooth portion 18A of the parking gear 18 are in the same position so that the pawl portion 32A cannot enter the groove of the parking gear 18 and the cam member 43 pushes the parking pole 32 upward. When it is not possible to compress the cam spring 44, the driver's operation by the selector can be completed.

  Thereafter, when the parking gear 18 rotates, the contact between the claw portion 32A and the top surface of the tooth portion 18A is eliminated, and the claw portion 32A reaches the groove position between the tooth portions 18A. The member 43 enters between the parking pole 32 and the support member 36, and the claws 32A engage with the teeth 18A to restrict the rotation of the parking gear 18. At this time, the restoring force of the cam spring 44 exceeds the frictional force between the cam member 43 and the parking pole 32 or the support member 36 and the restoring force of the return spring 34.

  As a result, the cam member 43 surely enters between the support member 36 and the parking pole 32, reliably swings the parking pole 32 so that the claw 32A moves toward the parking gear 18, and maintains the parking lock state. can do.

  Next, release of the parking lock will be described. In the parking lock mechanism 31, when the shift lever is operated from the parking range to the non-parking range, the manual shaft 37 rotates in the other direction (the direction opposite to the direction in which the parking lock is activated). The manual plate 40 is swung in the other direction (rear side).

  At this time, the parking rod 35 moves to the far side away from the parking pole 32 as the manual plate 40 rotates. Then, as shown in FIG. 11, the cam member 43 moves from the cylindrical surface 36b of the support member 36 to the conical surface 36a, and the cam member 43 gets out of the space between the parking pole 32 and the support member 36. 42 moves into the guide hole 64A.

  When the cam member 43 is removed, the parking pole 32 is swung in the clockwise direction of FIG. 2 about the parking pole shaft 33 by the urging force of the return spring 34.

  Thus, the claws 32A of the parking pole 32 are separated from the teeth 18A of the parking gear 18, and the engagement between the claws 32A and the teeth 18A is released. As a result, the rotation of the parking gear 18 is not restricted.

  As described above, the manual plate 40 of this embodiment swings integrally with the manual shaft 37 with the manual shaft 37 as the swing center, so that the rotation of the manual shaft 37 is moved in the axial direction of the parking rod 35. Convert.

  As shown in FIGS. 1 and 2, a detent plate 38 is attached to an upper end portion 37 a of the manual shaft 37 in the vicinity of the upper wall 9. Specifically, the detent plate 38 is a flat plate-like member perpendicular to the manual shaft 37 and has an attachment cylinder portion through which the manual shaft 37 is inserted, and is attached by a spring pin that penetrates the attachment cylinder portion and the manual shaft 37. It is done. The detent plate 38 is swung as the manual shaft 37 rotates. The detent plate 38 has a fan shape that spreads toward the front side, and fitting grooves 38A and 38B are formed on the outer periphery of the detent plate 38 on the front side.

  A detent spring 39 is provided on the upper part of the left vertical wall 5 above the bearing support portion 12. The detent spring 39 is a leaf spring, and its plate surface is disposed so as to be perpendicular to the axis of the input shaft 14, and its rear end is fastened and fixed to the left vertical wall 5 from the axis direction of the input shaft 14. . Detent spring 39 is arranged to extend in the front-rear direction along upper wall 9, and detent spring 39 is disposed behind input shaft 15 and counter gear 17 behind manual shaft 37. ing.

  A roller member 39A is rotatably provided at the front end portion of the detent spring 39. The roller member 39A can be freely fitted into the fitting groove 38A and the fitting groove 38B of the detent plate 38, and the detent spring 39 has a pressing force to press the roller member 39A from the front side to the outer peripheral edge of the detent plate 38. Have.

  When the driver's shift operation causes the manual shaft 37 to rotate in one direction, the detent plate 38 swings, and the roller member 39A is fitted in the fitting groove 38A, the parking rod 35 moves to the parking pole 32 side. The claw portion 32A of the parking pole 32 is in a position to achieve a parking lock state in which the claw portion 32A of the parking gear 32 meshes with the tooth portion 18A of the parking gear 18. The parking lock state can be maintained by fitting the fitting groove 38A and the roller member 39A.

  On the other hand, when the driver's shift operation causes the manual shaft 37 to rotate in the other direction and the detent plate 38 swings and the roller member 39A is fitted in the fitting groove 38B, the parking rod 35 moves to the back side. The claw portion 32A of the parking pole 32 is in the release position of the parking lock which is disengaged from the tooth portion 18A of the parking gear 18. By fitting the fitting groove 38B and the roller member 39A, the released state of the parking lock can be maintained.

  The detent plate 38 and the detent spring 39 constitute a detent mechanism, and a portion of the detent plate 38 at a position where the detent plate 38 is fitted (contacted) with the roller member 39A at the time of a driver's shift operation is defined as a fitting groove 38A and a fitting groove 38B. By moving between the positions, it is possible to give the driver a sense of positioning in each position and a feeling of switching (so-called click feeling) at the time of the shift operation.

  Further, the detent plate 38 swings integrally with the manual shaft 37 with the manual shaft 37 as the swing center, and the roller member 39A is inserted into another groove formed between the fitting groove 38A and the fitting groove 38B. By positioning, the manual shaft 37 is positioned in the rotational direction. The manual shaft 37 of the present embodiment constitutes the operating shaft of the present invention.

  As shown in FIG. 2, an intermediate concave portion 27, an upper concave portion 28, and a lower concave portion 29 are formed in a portion of the left vertical wall 5 between the bearing support portion 12 and the front vertical wall 8 in the front-rear direction. Yes.

  As shown in FIG. 7, the intermediate concave portion 27 bulges outward from the left vertical wall 5 in the axial direction of the input shaft 14, and the intermediate concave portion 27 accommodates an intermediate portion 37 c in the vertical direction of the manual shaft 37. Yes. The axially outward direction of the input shaft 14 from the left vertical wall 5 is the left side of the left vertical wall 5 opposite to the first joint 3A and the second joint 3B.

  In other words, the portion of the left vertical wall 5 between the bearing support portion 12 and the front vertical wall 8 is recessed deeper than the bearing support portion 12 (so that at least the deepest portion is deeper than the bearing 13). An intermediate recess 27 is formed, and a manual shaft 37 is disposed in a space extended from the left vertical wall 5 by the intermediate recess 27.

  The intermediate recess 27 has a width in the front-rear direction that is larger than the diameter of the manual shaft 37 and is formed in a groove shape in the vertical direction along the manual shaft 37. The middle recess 27 is U-shaped in cross section, and the front and rear walls thereof are disposed on the front and rear of the manual shaft 37. Further, the left vertical wall 5 disposed at the front and back of the intermediate recess 27 is disposed at the same position as the manual shaft 37 at the position in the axial direction of the input shaft 14 or closer to the mating surface than the manual shaft 37.

  The upper recess 28 is provided above the middle recess 27 continuously with the middle recess 27. The upper recessed portion 28 bulges outward in the axial direction of the input shaft 14 from the intermediate recessed portion 27, and the upper recessed portion 28 accommodates the upper end portion 37 a of the manual shaft 37 and a part of the detent plate 38.

  That is, an upper concave portion 28 that is larger than the intermediate concave portion 27 and is recessed toward the back side is formed in a portion of the left vertical wall 5 that is above the intermediate concave portion 27, and is extended from the left vertical wall 5 by the upper concave portion 28. A part of the detent plate 38 is disposed in the space. The upper recessed portion 28 has a shape that is larger than the intermediate recessed portion 27 and recessed toward the back side in order to accommodate the mounting cylinder portion of the detent plate 38 having a larger diameter than the manual shaft 37 and to allow the detent plate 38 to swing. And is also widely formed in the front-rear direction.

  The lower concave portion 29 is provided continuously with the lower end of the intermediate concave portion 27 and below the intermediate concave portion 27, and bulges outward in the axial direction of the input shaft 14 than the upper concave portion 28. In FIG. 8, a part of the parking rod 35 (left side part), the lower part of the manual shaft 37, and the manual plate 40 are accommodated in the lower recess 29.

  That is, a lower concave portion 29 that is larger than the intermediate concave portion 27 and is recessed to the back side is formed in a portion of the left vertical wall 5 that is lower than the intermediate concave portion 27. The manual plate 40 is disposed in the space expanded by the. The lower concave portion 29 has a shape that is recessed deeper than the intermediate concave portion 27 in order to allow the manual plate 40 to swing.

  Further, the manual plate 40 is disposed below the input shaft 14. However, the manual plate 40 needs to be disposed at a position as high as possible in order to ensure the minimum ground clearance of the vehicle, and in the vicinity of the bearing support portion 12. A lower concave portion 29 is formed in the upper portion. Specifically, as shown in FIG. 6, the lower concave portion 29 is formed from the lower end of the bearing support portion 12 in the vertical direction, and the lower concave portion 29 is formed from the vicinity of the axis of the input shaft 14 to the front side in the front-rear direction. The lower recess 29 is a recess continuous with the bearing support 12.

  Thus, the intermediate recess 27, the upper recess 28 and the lower recess 29 bulge outward from the left vertical wall 5 in the axial direction of the input shaft 14 rather than the left vertical wall 5. The parking rod 35, the manual shaft 37 and the manual plate 40 of this embodiment constitute predetermined parts of the present invention. The lower recess 29 constitutes a recess according to the present invention.

  1 and 2, stopper ribs 28 </ b> A and 28 </ b> B are provided on the inner wall surface of the upper recess 28, and the stopper ribs 28 </ b> A and 28 </ b> B are located in the same plane as the detent plate 38. In other words, the stopper ribs 28A and 28B are located at the same height as the detent plate 38.

  The stopper rib 28A is provided on one side in the swing direction of the detent plate 38, and the stopper rib 28B is provided on the other side in the swing direction of the detent plate 38.

  The stopper ribs 28A and 28B are in contact with or not in contact with the detent plate 38 as the manual shaft 37 rotates, and function as stoppers for restricting the rotation of the manual shaft 37 when in contact with the detent plate 38.

  That is, the stopper rib 28A restricts the detent plate 38 from further swinging from the state in which the roller member 39A is fitted in the fitting groove 38A, and the stopper rib 28B is fitted with the roller member 39A. The detent plate 38 is further restricted from swinging to the other side from the state of being fitted in the groove 38B.

  3 and 4, the first retainer 41 is installed on the front side of the parking pole 32 in the depth direction of the left case 2 (on the right side when mounted on the vehicle), and extends in the front-rear direction orthogonal to the depth direction. (See FIG. 2).

  The second retainer 42 is installed on the far side of the parking pole 32 in the depth direction of the left case 2 (left side in a vehicle-mounted state). Thereby, the parking pole 32 is sandwiched between the first retainer 41 and the second retainer 42 in the depth direction, and its swing is guided.

  1 and 2, the first retainer 41 includes a cylindrical portion 61, a first connecting portion 62 that extends rearward from the cylindrical portion 61, and a second connecting portion 63 that extends forward from the cylindrical portion 61. Have.

  As shown in FIG. 10, in the cylindrical portion 61, a fitting hole 61A and a fitting portion 61B are formed. The tip of the parking rod 35 can enter into the fitting hole 61A. A support member 36 is fitted into the fitting portion 61B. At the rear end of the first connecting portion 62, a fitting portion 62B and a fastening portion 62A are formed.

  An end of a parking pole shaft 33 that protrudes through the parking pole 32 is inserted into the fitting portion 62B, and a bolt 71A is inserted into the fastening portion 62A from the axial direction of the input shaft 14 so that the left case 2 It is fastened and fixed to the boss portion 52 of the left vertical wall 5 (see FIG. 12). The fitting portion 62B and the fastening portion 62A are the rear end portions of the first retainer 41 and are disposed below the counter shaft 16.

  A fastening portion 63A is formed at the front end portion of the second connecting portion 63, and a bolt 71B is inserted into the fastening portion 63A from the axial direction of the input shaft 14, and the boss portion 53 of the left vertical wall 5 of the left case 2 is inserted. (See FIG. 12). The positions of the bosses 52 and 53 of the left vertical wall 5 of the left case 2 are shown in FIG.

  The bosses 52 and the bosses 53 are provided in the vicinity of the first joint 3 A of the left case 2. The boss portion 52 is erected from the left vertical wall 5 and is connected to a reinforcing rib 72 that connects the left vertical wall 5 and the bottom wall 10, and the boss portion 53 is erected from the left vertical wall 5. And connected to the bottom wall 10 of the left case 2.

  As shown in FIG. 6, the boss portion 53 is installed so that the cam member 43 is positioned on an imaginary line L <b> 1 connecting the boss portion 53 and the counter shaft 16 when viewed from the axial direction of the input shaft 14. Further, the claw portion 32A of the parking pole 32 corresponding to the meshing position with the tooth portion 18A is located on the virtual line L1. By arranging in this manner, the reaction force from the parking pole 32 can be effectively received by the boss portion 53.

  The boss portion 53 is in the vicinity of the joint portion between the lower end of the front vertical wall 8 and the front end of the bottom wall 10 and is a rigid portion of the case in shape, and connects the left case 2 and the right case 4 together. The bolt to be operated is disposed in the vicinity, and the reaction force from the parking pole 32 can be received by the boss portion 53 more effectively.

  As shown in FIG. 6, when viewed from the axial direction of the input shaft 14, the boss portion 52 includes a meshing point (meshing circle) including a meshing point between the claw portion 32 </ b> A and the tooth portion 18 </ b> A around the rotation axis of the counter shaft 16. It is installed on an imaginary line L2 passing through the central axis of rotation of the parking pole shaft 33 in the tangential direction of. With this arrangement, the rotational force of the parking gear 18 transmitted through the parking pole 32 can be effectively received by the boss portion 52.

  The fastening portion 62A of the first connecting portion 62 is fixed to the boss portion 52 by a bolt 71A, and the fastening portion 63A of the second connecting portion 63 is fixed to the boss portion 53 by a bolt 71B. Thereby, the first retainer 41 is fixed to the left case 2.

  The fitting portion 62B formed in the first connecting portion 62 is provided on the front side of the fastening portion 62A. A front end (right end) of the parking pole shaft 33 is fitted to the fitting portion 62B, and the first retainer 41 prevents and supports the parking pole shaft 33 ( (See FIG. 4).

  In FIG. 4, the boss portion 51 projects from the left vertical wall 5 on the far side in the depth direction of the left case 2 to the front side (right side) through the side of the second retainer 42, and the parking pole shaft 33. The left end of the is supported. Thus, the parking pole shaft 33 is supported by the boss portion 51 and the fitting portion 62B of the first retainer 41.

  In FIG. 5, the second retainer 42 is installed on the front side (right side) of the manual shaft 37, and has a cylindrical portion 64 (see FIG. 4) and a first connection extending from the back side to the rear side of the cylindrical portion 64. A portion 65 and a second connecting portion 66 extending from the front side to the front side of the cylindrical portion 64 are provided.

  As shown in FIGS. 10 and 13, a guide hole 64A is formed in the cylindrical portion 64, and the parking rod 35 and the cam member 43 are inserted through the guide hole 64A. Thereby, the parking rod 35 and the cam member 43 are guided by the cylindrical portion 64 to move in the axial direction.

  As shown in FIG. 10, a fitting portion 64B is formed on the cylindrical portion 64 of the second retainer 42, and a support member 36 is fitted on the fitting portion 64B. A fitting portion 61B is formed in the cylindrical portion 61 of the first retainer 41, and a support member 36 is fitted in the fitting portion 61B. Thereby, the support member 36 is positioned and supported by the first retainer 41 and the second retainer 42 by the fitting portion 61B and the fitting portion 64B.

  That is, the support member 36 is prevented from being detached by the step portions formed in the fitting portion 61B and the fitting portion 64B by being sandwiched between the cylindrical portion 61 and the cylindrical portion 64 in the depth direction (left-right direction) of the left case 2. It is supported by the first retainer 41 and the second retainer 42 in the closed state.

  In FIG. 1, a fastening portion 65A is formed at the rear end of the first connection portion 65, and a bolt 71C is inserted through the fastening portion 65A (see FIGS. 5 and 12).

  Fastening portions 66A and 66B are formed at the front end portion of the second connecting portion 66 so as to be spaced apart in the vertical direction, and bolts 71D and 71E are inserted through the fastening portions 66A and 66B (see FIGS. 5 and 12). ).

  In FIG. 6, a boss 54 is provided around the bearing support 12, that is, in the lower part of the bearing support 12. The boss portion 54 extends forward from the left vertical wall 5 along the axial direction of the input shaft 14, and the upper portion of the boss portion 54 is connected to the lower portion of the bearing support portion 12. That is, the boss portion 54 is connected to the left vertical wall 5 and the bearing support portion 12.

  Boss portions 55 and 56 are provided on the front vertical wall 8, and the boss portions 55 and 56 are formed to protrude rearward from the front vertical wall 8. The boss portions 55 and 56 are separated in the vertical direction along the second joint portion 3B of the left case 2 so as to be separately arranged above and below the manual plate 40, and along the axial direction of the input shaft 14. It extends toward the 2nd junction part 3B from the lower side recessed part 29 (refer FIG. 8, FIG. 9). The upper boss portion 55 may be provided on the left vertical wall 5 on the front side of the intermediate recess 27. This position is located forward at the same height as the bearing support portion 12 and is in the vicinity of the joint between the front vertical wall 8 and the left vertical wall 5, so that the rigidity of the boss portion 55 is improved.

  As shown in FIG. 6, the bosses 55 and 56 are located on the side of the front vertical wall 8 opposite to the boss 54 with the lower recess 29 in the front-rear direction. In other words, the lower recess 29 is provided between the boss 54 and the bosses 55 and 56 in the front-rear direction.

  The left vertical wall 5 and the front vertical wall 8 of the present embodiment constitute a wall of the present invention. The left vertical wall 5 constitutes the vertical wall of the present invention provided on the back side in the axial direction of the input shaft 14 with respect to the first joint portion 3A and the second joint portion 3B. The front vertical wall 8 connects the left vertical wall 5 including the lower concave portion 29 and the second joint portion 3 </ b> B, and constitutes the side wall of the present invention extending along the axial direction of the input shaft 14.

  The first bonding portion 3A and the second bonding portion 3B constitute a bonding portion of the present invention. The boss portion 54 constitutes the first portion and the first boss portion of the present invention, and the boss portions 55 and 56 constitute the second portion and the second boss portion of the present invention.

  In FIG. 6, the boss portion 54 is disposed on the left side with respect to the perpendicular L3 passing through the rotation center axis O of the input shaft 14, and is on the counter shaft 16 side opposite to the lower concave portion 29 with respect to the perpendicular L3. Is formed. That is, the boss portion 54 is formed on the left vertical wall 5 behind the lower recess 29.

  As shown in FIG. 9, the boss portion 54 has a fastening surface 54a to which the fastening portion 65A of the second retainer 42 is fastened by a bolt 71C. The boss portion 55 has a fastening surface 55a to which the fastening portion 66A of the second retainer 42 is fastened by the bolt 71D.

  As shown in FIG. 8, the boss portion 56 has a fastening surface 56a fastened to the fastening portion 66B of the second retainer 42 by a bolt 71E.

  As shown in FIGS. 8 and 9, at the height position in the axial direction of the input shaft 14 of the boss portion 54 and the boss portions 55, 56, the first joining portion 55a, 56a is a first joint portion than the fastening surface 54a. It is formed in steps so that it may be located in 3A and the 2nd junction part 3B side.

  In other words, the boss portion 54 and the boss portions 55 and 56 are formed in steps so that the fastening surfaces 55a and 56a are farther from the bearing support portion 12 than the fastening surface 54a at the position in the axial direction of the input shaft 14. Yes. The fastening surface 54a of the present embodiment constitutes the first fastening surface of the present invention, and the fastening surfaces 55a and 56a constitute the second fastening surface of the present invention.

  As shown in FIGS. 3 and 9, the second retainer 42 is formed in a stepped manner so that the fastening portion 65A is located on the left vertical wall 5 side with respect to the fastening portions 66A and 66B. Although FIG. 3 and FIG. 9 do not illustrate the fastening portion 66B, the fastening portion 66B is provided at the same position as the fastening portion 66A in the axial direction of the input shaft 14.

  The fastening portion 65A of the first connecting portion 65 is fixed to the boss portion 54 by a bolt 71C, and the fastening portions 66A and 66B of the second connecting portion 66 are fixed to the boss portions 55 and 56 by bolts 71D and 71E. Has been. Thereby, the second retainer 42 is fixed to the left case 2.

  The second retainer 42 of this embodiment connects the boss portion 54 and the boss portions 55 and 56 located on the opposite side of the boss portion 54 across the lower concave portion 29 from the boss portion 54. That is, the second retainer 42 connects the boss portions 54 and the boss portions 55, 56 disposed on both the front and rear sides of the lower recess 29. More specifically, as shown in FIG. 9, the second retainer 42 connects both sides of the lower recess 29 in a state of being erected on the side of the manual shaft 37 so as to surround the manual shaft 37 together with the lower recess 29. doing. The 2nd retainer 42 of a present Example comprises the connection member of this invention.

  As described above, the first retainer 41 and the second retainer 42 are fixed to the left case 2, whereby the parking pole 32, the parking pole shaft 33, the parking rod 35, the support member 36, and the manual plate 40 are Are installed in a space surrounded by the lower retainer 41, the second retainer 42, the lower portion of the left vertical wall 5, the lower recessed portion 29, and the lower portion of the front vertical wall 8.

  Since the fastening surfaces 55a and 56a are located closer to the first joint 3A and the second joint 3B than the fastening surface 54a in the axial direction of the input shaft 14, the fastening surfaces in the axial direction of the input shaft 14 54a will be located in the bearing support part 12 side behind the fastening surfaces 55a, 56a. Note that the fastening surface 54a protrudes closer to the mating surface than the bearing support portion 12 as shown in FIG. 9 in order to facilitate processing of the end surface.

  Since the fastening surface 54a is at a position deeper than the fastening surfaces 55a and 56a, the height of the boss 54 can be lowered, and a space for installing the head of the bolt 71C can be secured. Then, the boss portion 54 can be installed on the back side of the parking pole 32, that is, at the same position as the parking pole 32 when viewed from the axial direction of the input shaft 14 and hidden behind the parking pole 32.

Further, as shown in FIG. 9, the second retainer 42 (connecting member) is attached so as to spread from the fastening surface 54 a disposed in the vicinity of the bearing support portion 12 toward the fastening surfaces 55 a and 56 a toward the mating surface. Therefore, the load acting on the bearing support 12 can be effectively transmitted to the front vertical wall 8 by the second retainer 42 together with the shape of the lower recess 29 which extends from the bearing support 12 to the opposite side.
In FIG. 6, an imaginary line L4 connecting the rotation center axis O of the input shaft 14 and a rotation center axis of the counter shaft 16 as viewed in the axial direction of the input shaft 14 and an imaginary line L5 connecting the boss 54 and the boss 55 The boss portions 54 and 55 are installed so that and are substantially parallel to each other.

  In FIG. 6, the boss portion 56 is installed so that a virtual line L6 connecting the boss portion 54 and the boss portion 56 passes through the rotation center axis of the counter shaft 16, and the virtual line L6 is relative to the virtual line L5. It is the parking rod 35 side opposite to the virtual line L4. A virtual line connecting the bosses 55 and 56, a virtual line L4, and a virtual line L5 form a triangle.

  That is, the virtual line L5 and the virtual line L6 form a depression angle. Each boss portion 54, 55, 56 is located within this included angle so that a line parallel to an imaginary line L 4 connecting the rotation center axis O of the input shaft 14 and the rotation center axis of the counter shaft 16 passes through the boss portion 54. When the is installed, the reaction force of the gear can be effectively received by the second retainer 42 (connection member).

  The boss portion 56 farthest from the rotation center axis O of the input shaft 14 is installed at the corner of the left case 2 where the bottom wall 10 and the front vertical wall 8 intersect. This corner portion is a portion where the surfaces in different directions are coupled and the light case 4 is coupled at the mating surface, and is a highly rigid portion. Therefore, the force from the second retainer 42 can be effectively received.

  As described above, the left case 2 of the present embodiment is provided on the left vertical wall 5, and the bearing support portion 12 that rotatably supports the input shaft 14 via the bearing 13, and the left vertical wall around the bearing support portion 12. And a lower concave portion 29 that bulges outward from the left vertical wall 5 in the axial direction of the input shaft 14 so as to accommodate the parking rod 35, the lower portion of the manual shaft 37, and the manual plate 40. .

  In addition to this, the left case 2 includes a boss portion 54 provided at a lower portion of the bearing support portion 12 and boss portions 55 and 56 located on the opposite side of the boss portion 54 across the lower concave portion 29 from the boss portion 54. And a second retainer 42 connecting the two.

  Thus, even when the lower concave portion 29 for accommodating the parking rod 35, the manual shaft 37, and the manual plate 40 is formed around the bearing support portion 12 that requires rigidity for supporting the input shaft 14, the first The bearing support portion 12 can be reinforced by the two retainers 42, and the rigidity of the bearing support portion 12 can be increased. That is, in the left case 2 of the drive device 1, even if the space for storing the components is formed in the portion around the bearing support portion 12, both sides of the space are connected by the second retainer 42 (connection member). The rigidity of the bearing support 12 can be secured.

  Therefore, the parking pole 32, the parking rod 35, the support member 36 and the manual shaft 37 can be installed close to the bearing support portion 12, and the bulging shape in which the rigidity of the case tends to decrease is necessary for the left case 2 Can be formed in place. Therefore, the left case 2 can be downsized, and as a result, the drive device 1 can be downsized.

  Further, according to the strong structure of the left case 2 of the present embodiment, the left case 2 has the first joint portion 3 </ b> A and the second joint portion 3 </ b> B joined to the right case 4.

  The left case 2 includes a left vertical wall 5 provided on the back side in the axial direction of the input shaft 14 with respect to the first joint 3A and the second joint 3B, and a left vertical wall including a lower recess 29 5 and the 2nd junction part 3B are connected, and it is comprised including the front vertical wall 8 extended along the axial direction of the input shaft 14. As shown in FIG.

  The boss portion 54 is connected to the bearing support portion 12, and the boss portions 55 and 56 are connected to the front vertical wall 8 and extend from the lower recess 29 toward the second joint portion 3B. In addition to this, the second retainer 42 is fastened to the boss portions 54, 55, 56 by bolts 71C, 71D, 71E.

  Thereby, the rigidity of the boss | hub part 54 can be made high by connecting the boss | hub part 54 to the bearing support part 12 with high rigidity. In addition to this, by connecting the bosses 55, 56 to the front vertical wall 8 near the second joint 3B having high rigidity by being fastened to the light case 4, the rigidity of the bosses 55, 56 Can be high.

  Since the boss portion 56 is installed at the corner of the left case 2 where the bottom wall 10 and the front vertical wall 8 intersect, the rigidity of the boss portion 56 can be further increased.

  When the vehicle travels, a reaction force acts in a tangential direction of the input gear 15 and the counter gear 17 by the meshing between the input gear 15 and the counter gear 17, and the reaction force F from the input gear 15 via the input shaft 14 (see FIG. 2) ) Acts. The reaction force F acts in a direction orthogonal to a virtual line L4 shown in FIG.

  On the other hand, the left case 2 of the present embodiment can reinforce the bearing support 12 by fixing the second retainer 42 to the bosses 54, 55, 56 having high rigidity, and the rigidity of the bearing support 12 Can be increased more effectively. Therefore, the support rigidity of the input shaft 14 can be more effectively increased with respect to the reaction force F.

  Further, according to the left case 2 of the present embodiment, the boss portion 54 is formed on the opposite side to the lower concave portion 29 with respect to the perpendicular L3 passing through the rotation center axis O of the input shaft 14.

  The boss portion 54 has a fastening surface 54a to which the second retainer 42 is fastened by a bolt 71C, and the boss portions 55 and 56 are fastening surfaces 55a and 56a to which the second retainer 42 is fastened by bolts 71D and 71E. Have

  In addition to this, in the bosses 54 and the bosses 55, 56, the fastening surfaces 55a, 56a are closer to the first joint 3A and the second joint 3B than the fastening surface 54a in the axial direction of the input shaft 14. It is formed in a step so that it may be located.

  As a result, in the second retainer 42, the fastening portions 66A and 66B can be formed in a stepped manner so as to be positioned closer to the first joining portion 3A and the second joining portion 3B than the fastening portions 65A.

  The second retainer 42 having such a shape is fixed to the boss portions 54, 55, 56 by bolts 71C, 71D, 71E, so that the second retainer 42 is directed from the boss portion 54 to the boss portions 55, 56. It can be spread and installed so as to approach the second joint 3B in the axial direction of the input shaft 14. Further, the second retainer 42 can be installed in a state in which the second retainer 42 extends from the boss portion 54 toward the boss portions 55, 56 and expands in the vertical direction from the vicinity of the bearing support portion 12 toward the front. Therefore, the rigidity of the bearing support 12 can be more effectively enhanced.

  Further, according to the left case 2 of the present embodiment, the parking lock mechanism 31 is accommodated in the left case 2. The lower portion of the parking rod 35 and the manual shaft 37 and the manual plate 40 are accommodated in the lower recess 29. The second retainer 42 is installed in the lower recess 29 to support the support member 36 on the left case 2.

  Thereby, even when the left case 2 is curved to install the parking lock mechanism 31 in the vicinity of the input shaft 14 and the storage space is formed in the vicinity of the bearing support 12, the rigidity of the bearing support 12 can be increased. it can. In addition, since the bearing support portion 12 can be reinforced using the second retainer 42 that supports the support member 36, the number of parts required for reinforcement of the left case 2 can be reduced.

  Further, according to the left case 2 of the present embodiment, a virtual line L4 that connects the rotation center axis O of the input shaft 14 and the rotation center axis of the counter shaft 16 when viewed from the axial direction of the input shaft 14, and the boss portion 54 The bosses 54 and 55 are installed so that they are substantially parallel to an imaginary line L5 connecting the bosses 55.

  In addition to this, an imaginary line L6 connecting the boss portion 54 and the boss portion 56 is set on the side of the parking rod 35 opposite to the imaginary line L4 with respect to the imaginary line L5, and forms a triangular shape with the imaginary line L5. The boss 54 and the boss 56 are installed in the

  Thereby, the 2nd retainer 42 can be fixed to the boss | hub parts 54, 55, and 56 installed in the triangular vertex. For this reason, the bearing support portion 12 can be more effectively reinforced by the second retainer 42, and the reaction force acting on the bearing support portion 12 from the input shaft 14 through the input gear 15 due to the meshing of the input gear 15 and the counter gear 17. The rigidity of the bearing support 12 can be increased relative to F. As a result, the support rigidity of the input shaft 14 can be increased.

  In addition to this, when the reaction force acts such that the input gear 15 and the counter gear 17 separate in the direction of the imaginary line L4 by the meshing between the input gear 15 and the counter gear 17, a load is applied to the left vertical wall 5 There is a fear.

  On the other hand, the left vertical wall 5 can be reinforced by the second retainer 42 fastened to the triangular bosses 54, 55, 56, and the left vertical wall 5 vibrates or deforms. This can be suppressed. Thereby, the rigidity of the bearing support portion 12 can be increased, and the support rigidity of the input shaft 14 can be more effectively stiffened.

  Further, the boss portions 54 and 56 are installed so that a virtual line L6 connecting the boss portion 54 and the boss portion 56 passes through the rotation center axis of the counter shaft 16.

  Thereby, depending on the traveling state of the vehicle, when the reaction force due to the meshing between the input gear 15 and the counter gear 17 is applied from the counter gear 17 via the counter shaft 16 in the direction of the imaginary line L6, the reaction force in the direction of the imaginary line L6 On the other hand, the rigidity of the bearing support that supports the countershaft 16 can be increased. As a result, in addition to the support rigidity of the input shaft 14, the support rigidity of the counter shaft 16 can be increased.

  Further, when the parking pole 32 is swung from the unlocking position to the meshing position, the second retainer 42 is supported by the cam member 43 by the restoring force of the cam spring 44 or the force received by the parking pole 32 from the parking gear 18. A large load is applied through the member 36.

  According to the left case 2 of the present embodiment, in addition to fixing the second retainer 42 to the bosses 54, 55, 56 having high rigidity, the second retainer 42 is made of, for example, high strength cast iron or the like. By doing this, it is possible to ensure sufficient strength of the second retainer 42 with respect to impact load and operation load.

  Furthermore, the parking rod 35 can be stably moved in the axial direction by the second retainer 42 that supports the support member 36.

  In this embodiment, the left case 2 is applied to the left case of the driving device 1, but the present invention is not limited to this. In other words, the present invention can be applied to any device as long as it has a recess that bulges outward from the wall in the axial direction of the rotation shaft.

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

  DESCRIPTION OF SYMBOLS 1 ... Drive device, 2 ... Left case (case), 3A ... 1st junction part (joint part), 3B ... 2nd junction part (joint part), 4 ... right Case (case member), 5 ... Left vertical wall (wall part, vertical wall), 8 Front vertical wall (wall part, side wall), 12 ... Bearing support part, 13 ... Bearing, 14 ... Input shaft (rotary shaft), 18 ... Parking gear, 18A ... Teeth, 29 ... Lower recess (recess), 31 ... Parking lock mechanism, 32 ... Parking pole, 32A ... . Claw part, 33 ... Parking pole shaft (support shaft), 35 ... Parking rod, 36 ... Support member, 37 ... Manual shaft (operation shaft), 42 ... Second retainer ( Connecting member), 43 ... cam member, 54 ... boss part (first part, first boss part), 54a ... fastening surface (first fastening surface), 55, 56 ... Boss (second part, second boss), 55a 56a ... fastening surface (the second fastening surface), 71C, 71D, 71E ... bolt

Claims (4)

A wall portion, a bearing support portion provided on the wall portion and rotatably supporting a rotating shaft via a bearing, and the wall portion around the bearing support portion are formed to accommodate predetermined components. A case structure of a drive device, comprising: a recess that bulges outward in the axial direction of the rotation shaft from the wall portion,
A first part of the wall located on the periphery of the bearing support on one side of the recess and a second part of the wall located on the other side of the recess;
A case structure of a drive device comprising a connecting member for connecting the first portion and the second portion across the recess. The case has a joint to be joined to the case member,
The wall portion connects a vertical wall provided on the back side in the axial direction of the rotary shaft with respect to the joint, the vertical wall including the recess, and the joint, and an axis of the rotary shaft And a side wall extending along the direction,
The first portion has a first boss portion coupled to the bearing support portion,
The second portion has a second boss portion connected to the side wall and extending from the recess toward the joint portion.
The case structure of the drive unit according to claim 1, wherein the connection member is fastened to the first boss and the second boss by a bolt. The first boss portion is formed on the opposite side of the recess with respect to a vertical line passing through a rotation center axis of the rotation axis when viewed from the axial direction of the rotation axis.
The first boss portion has a first fastening surface fastened to the connection member by the bolt.
The second boss has a second fastening surface fastened to the connecting member by the bolt.
The first boss portion and the second boss portion are formed stepwise such that the second fastening surface is positioned closer to the joint portion than the first fastening surface in the axial direction of the rotation shaft. The case structure of the drive device according to claim 2, wherein the case structure is provided. The driving device has a plurality of rotating shafts including the rotating shaft,
A parking lock mechanism is accommodated in the case,
The parking lock mechanism is
A parking gear having a toothed portion and attached to the rotating shaft so as to rotate integrally with one of the plurality of rotating shafts;
A parking pawl having a claw portion that meshes with the tooth portion, and swingably supported by the case via a support shaft;
A parking rod having a cam member and provided so as to be axially movable;
An operating shaft having a manual plate attached to the parking rod, the manual plate being attached to swing the manual plate;
And a support member configured to swing the parking pole so that the claws mesh with the teeth when the cam member runs on with the movement of the parking rod.
The predetermined part comprises at least the parking rod, the operation shaft and the manual plate,
The case structure of a drive unit according to any one of claims 1 to 3, wherein the connection member supports the support member on the case.

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