JP7183053B2 - reduction gear - Google Patents

Description

An embodiment of the present invention relates to a speed reducer.

2. Description of the Related Art Conventionally, a speed reducer is known that uses a combination of an external gear and an internal gear having more teeth than an external gear to reduce the speed of rotation of a motor and output the output from the internal gear. The external gear revolves around the rotation axis, causing the internal gear to rotate around the rotation axis. A speed reducer is provided with a guide plate that restricts the rotation of the external gear (Patent Document 1).

JP 2018-080791 A

However, in the conventional configuration, the guide plate restricts the rotation of the external gear, so that the load acts on the housing of the speed reducer from the guide plate. The load may deform the housing.

Accordingly, the present invention has been made in view of the above, and provides a reduction gear transmission capable of suppressing deformation of the housing.

A speed reducer according to an embodiment of the present invention includes, as an example, a driven gear that is rotated around a rotation shaft by the driving force of a drive mechanism, and a first gear that is moved in the circumferential direction of the rotation shaft by the driven gear. , a rotation transmission mechanism having a restriction member that restricts rotation of the first gear, and a second gear that is rotated around the rotation shaft by the first gear; a housing having an outer surface and provided with an accommodation opening that opens to the outer surface and accommodates the rotation transmission mechanism; and a cover that is attached to the housing and covers the accommodation opening, wherein the restricting member comprises: a first guide that allows the first gear to move in a first direction orthogonal to the axial direction and restricts relative rotation between the restricting member and the first gear; and a second guide protruding in a second direction orthogonal to the axial direction and different from the first direction, wherein the accommodation opening includes the driven gear, the first gear, the second and a first accommodation portion in which the gear and the first guide are accommodated; a second receiving portion in which two guides are received; the housing includes an inner surface of the second receiving portion that limits relative rotation of the housing and the restricting member; a first engaging portion located on one side of the guide in a third direction orthogonal to the axial direction and orthogonal to the second direction; a coupling portion positioned on said one side in said third direction relative to said second guide and spaced from said housing and couplable to a vehicle seat; a second engagement portion positioned on the side of the housing and engaged with the first engagement portion to limit deformation of the housing such that the first engagement portion moves away from the rotation axis; have. Therefore, as an example, a part of the housing on one side of the second guide in the third direction is prevented from deforming away from the rotation axis even if a load is input from the second guide. . That is, deformation of the housing is suppressed.

In the reduction gear transmission, as an example, one of the first engaging portion and the second engaging portion is provided with an opening, and the other of the first engaging portion and the second engaging portion is provided with an opening. has a projection that fits into the opening. Therefore, as an example, a portion of the housing on one side in the third direction with respect to the second guide is deformed to move away from the rotating shaft, deform to approach the rotating shaft, or deform in the circumferential direction of the rotating shaft. Deformation is suppressed. Therefore, deformation of the housing is suppressed.

In the reduction gear transmission described above, for example, the first engaging portion has a first wall, and the second engaging portion extends radially outward of the rotating shaft relative to the first wall. located and extending along said first wall. Therefore, as an example, the size of the speed reducer is suppressed in the radial direction.

In the speed reducer described above, as an example, the first engaging portion has a second wall positioned between the pawl and the second guide in the circumferential direction and facing the pawl. For example, a portion of the housing on one side in the third direction with respect to the second guide deforms so as to move in the circumferential direction when a load is input in the circumferential direction from the second guide. However, the deformation is suppressed by supporting the second wall with the claw. Therefore, deformation of the housing is suppressed.

In the reduction gear transmission described above, as an example, the first engaging portion has a third wall facing the pawl, and the pawl is located between the second wall and the third wall in the circumferential direction. located in between. For example, a portion of the housing on one side of the second guide in the third direction moves in the circumferential direction and twists away from the rotation axis when a load is applied in the circumferential direction from the second guide. be The twist causes the housing to input a load to the pawl. However, since the third wall supports the nail, deformation of the nail is suppressed.

In the reduction gear transmission described above, as an example, the first engaging portion is positioned radially outward of the rotating shaft relative to the pawl, and is connected to the second wall and the third wall. It has 4 walls. Therefore, as an example, the first to fourth walls are formed in a frame shape, and the rigidity of the first engaging portion is improved.

FIG. 1 is an exemplary side view schematically showing a seat according to the first embodiment. FIG. FIG. 2 is an exemplary side view schematically showing the driving device of the first embodiment. FIG. 3 is an exemplary front view schematically showing the driving device of the first embodiment. 4 is an exemplary cross-sectional view schematically showing the driving device of the first embodiment along line F4-F4 of FIG. 2. FIG. FIG. 5 is an exemplary perspective view schematically showing an exploded driving device of the first embodiment. 6 is an exemplary cross-sectional view schematically showing part of the housing and part of the stopper plate of the first embodiment along line F6-F6 of FIG. 4. FIG. FIG. 7 is a side view showing the housing and stopper plate of the first embodiment. FIG. 8 is an exemplary side view schematically showing the housing of the first embodiment; FIG. 9 is an exemplary side view schematically showing part of the housing and part of the stopper plate of the first embodiment; FIG. 10 is an exemplary perspective view schematically showing the housing and washer of the first embodiment; FIG. 11 is an exemplary cross-sectional view schematically showing a speed reducer according to the second embodiment.

(First embodiment)
A first embodiment will be described below with reference to FIGS. 1 to 10. FIG. In addition, in this specification, multiple expressions may be described for the constituent elements according to the embodiment and the description of the relevant elements. Components and descriptions that are multiple-worded may be worded otherwise. Further, components and descriptions not described in multiple terms may also be referred to in other terms not listed.

FIG. 1 is an exemplary side view schematically showing a seat 11 according to the first embodiment. A seat 11 is mounted on a vehicle 1 such as a four-wheeled vehicle. A seat 11 is provided with, for example, a slide rail 12 and a seat lifter 13 .

The slide rails 12 enable the seat 11 to slide in the longitudinal direction of the vehicle 1 . The slide rail 12 has, for example, a pair of upper rails 21 and a pair of lower rails 22 . Lower rail 22 is attached to floor 1 a of vehicle 1 . The upper rail 21 is attached to the lower rail 22 so as to be slidable in the longitudinal direction of the vehicle 1 .

The seat lifter 13 enables the seat 11 to move up and down in the vertical direction of the vehicle 1 . The seat lifter 13 has, for example, a pair of base plates 24 , a pair of arms 25 , a pair of front links 26 , a pair of rear links 27 , a rod 28 and a drive device 29 . The drive 29 may be referred to, for example, as a gearbox motor.

A base plate 24 is attached to the upper rail 21 . The arm 25 is attached to the base plate 24 via a front link 26 and a rear link 27 so as to be vertically movable with respect to the vehicle 1 .

One end of front link 26 is rotatably attached to the front end of base plate 24, for example by a pin. The other end of front link 26 is rotatably attached to the front end of arm 25, for example by a pin.

One end of the rear link 27 is rotatably attached to the rear end of the base plate 24, for example by a pin. The other end of rear link 27 is rotatably attached to the rear end of arm 25 by, for example, rod 28 . A pair of arms 25 are connected to each other by a rod 28 .

The seat lifter 13 includes a base plate 24, an arm 25, a front link 26, and a rear link 27 to form a four-bar rotation mechanism. By rotating the front link 26 or the rear link 27 , the arm 25 moves up and down with respect to the base plate 24 .

A gear portion 27 a is provided on the rear link 27 . The gear portion 27a has a plurality of teeth arranged in a substantially circular arc with the rod 28 as the center. The driving device 29 is attached to the arm 25 together with the rear link 27 provided with the gear portion 27a. The drive device 29 has a pinion 29a. The pinion 29 a is fitted to the gear portion 27 a of the rear link 27 .

When the driving device 29 is driven, the pinion 29a rotates. A pinion 29 a meshing with the gear portion 27 a rotates the rear link 27 . Thereby, the arm 25 moves up and down with respect to the base plate 24 .

FIG. 2 is an exemplary side view schematically showing the driving device 29 of the first embodiment. FIG. 3 is an exemplary front view schematically showing the driving device 29 of the first embodiment. FIG. 4 is an exemplary cross-sectional view schematically showing the driving device 29 of the first embodiment along line F4-F4 of FIG. FIG. 5 is an exemplary perspective view schematically showing an exploded driving device 29 of the first embodiment.

As shown in FIG. 2 , the driving device 29 has a motor 31 and a reduction device 32 . Motor 31 may be referred to as, for example, a drive mechanism. The driving device 29 decelerates the rotation of the motor 31 by the reduction device 32 to rotate the pinion 29a.

As shown in FIG. 5, the motor 31 has a case 31a and components housed in the case 31a. Components include, for example, motor shafts, stators, rotors, coils, and magnets. The motor 31 is driven by electric power and rotates the motor shaft around the rotation axis Ax1.

The speed reducer 32 is a so-called Taumel mechanism and has a rotation transmission mechanism 35 , a housing 36 , a cover 37 and a washer 38 . The rotation transmission mechanism 35 can be called, for example, a deceleration section. Cover 37 may be referred to as a cap, for example.

The rotation transmission mechanism 35 is housed in the housing 36 . The rotation transmission mechanism 35 has a first speed reduction section 41 , a second speed reduction section 42 and an output shaft 43 . The driving force of the motor 31 is transmitted to the second reduction section 42 via the first reduction section 41 and further transmitted from the second reduction section 42 to the output shaft 43 .

The output shaft 43 is rotatably supported by the housing 36 and the cover 37 around the rotation axis Ax2. The rotation axis Ax2 is the central axis of the output shaft 43 extending in a direction intersecting the axial direction of the rotation axis Ax1. The rotation axis Ax2 may be referred to as a rotation axis or a first rotation axis.

In the following description, an axial direction is defined as a direction along an axis of rotation, such as axis of rotation Ax1 and axis of rotation Ax2. Further, the radial direction is defined as the direction perpendicular to the axis of rotation, and the circumferential direction is defined as the direction of rotation about the axis of rotation.

A pinion 29 a of the drive device 29 is provided on the output shaft 43 . The pinion 29 a protrudes outside the housing 36 . The pinion 29a is rotatable integrally with the output shaft 43 around the rotation axis Ax2.

The first deceleration section 41 has a worm 51 and a worm wheel 52 . Worm wheel 52 may be referred to as a driven gear. The worm 51 is coupled to the motor shaft of the motor 31 and rotates together with the motor shaft around the rotation axis Ax1.

As shown in FIG. 4, the worm wheel 52 is supported by the housing 36 and the output shaft 43 so as to be rotatable around the rotation axis Ax2. The worm wheel 52 is formed in a substantially disc shape centered on the rotation axis Ax2, and has a first end face 52a, a second end face 52b, a plurality of teeth 52c, and support projections 52d. The first end face 52a faces one side in the axial direction of the rotation axis Ax2 (upward in FIG. 4). The second end face 52b is located opposite the first end face 52a. The second end face 52b faces the other side in the axial direction of the rotation axis Ax2 (downward in FIG. 4) and is supported by the housing . The plurality of teeth 52c are arranged at substantially equal intervals in the circumferential direction of the rotation axis Ax2 and mesh with the worm 51. As shown in FIG. 52 d of support protrusions protrude from the 2nd end surface 52b, and are extended in the circumferential direction of rotating shaft Ax2.

In the first deceleration unit 41, when the worm 51 rotates around the rotation axis Ax1 by the driving force of the motor 31, the worm wheel 52 rotates around the rotation axis Ax2. That is, the worm wheel 52 is rotated around the rotation axis Ax2 by the driving force of the motor 31 . The first deceleration unit 41 decelerates the motor shaft of the motor 31 to rotate the worm wheel 52 .

The second speed reduction section 42 has an eccentric shaft 61 , an external gear 62 , a bushing 63 , a stopper plate 64 and an internal gear 65 . External gear 62 may be referred to as a first gear or gear. Stopper plate 64 may be referred to as a limiting member. Internal gear 65 may be referred to as a second gear or gear. In this embodiment, the eccentric shaft 61 is a part integral with the worm wheel 52 , and the internal gear 65 is a part integral with the output shaft 43 .

The eccentric shaft 61 protrudes from the first end surface 52a of the worm wheel 52 along the rotation axis Ax3. The rotation axis Ax3 can be called a second rotation axis. The rotation axis Ax3 is parallel to the rotation axis Ax2 and is at a different position from the rotation axis Ax2. That is, the rotation axis Ax3 that is the center of the eccentric shaft 61 is eccentric from the rotation axis Ax2 that is the center of the worm wheel 52 .

The eccentric shaft 61 has an outer peripheral surface 61a. The outer peripheral surface 61a is a substantially cylindrical outer surface centered on the rotation axis Ax3 and faces outward in the radial direction of the rotation axis Ax3. Further, the eccentric shaft 61 is provided with an insertion hole 61b. The insertion hole 61b extends along the rotation axis Ax2. The rotation axis Ax3, which is the center of the outer peripheral surface 61a, is eccentric from the rotation axis Ax2, which is the center of the insertion hole 61b. The output shaft 43 is rotatably supported by the eccentric shaft 61 by being inserted through the insertion hole 61b. The output shaft 43, the worm wheel 52 and the eccentric shaft 61 are rotatable relative to each other.

The outer peripheral surface 61a has a first portion 61aa and a second portion 61ab. The first portion 61aa and the second portion 61ab are arranged in the axial direction of the rotation axis Ax3. The surface roughness of the first portion 61aa is made lower than the surface roughness of the second portion 61ab by cutting or grinding, for example.

The eccentric shaft 61 can rotate integrally with the worm wheel 52 . The worm wheel 52 that rotates about the rotation axis Ax2 causes at least the portion of the eccentric shaft 61 having the outer peripheral surface 61a to move in the circumferential direction of the rotation axis Ax2. In other words, the eccentric shaft 61 revolves around the rotation axis Ax2. Along with the eccentric shaft 61, the rotation axis Ax3 also moves (revolves) in the circumferential direction of the rotation axis Ax2.

The external gear 62 is formed in a plate shape around the rotation axis Ax3. The external gear 62 is provided with an insertion hole 62a extending along the rotation axis Ax3. The eccentric shaft 61 is inserted through the insertion hole 62a so as to be relatively rotatable with respect to the external gear 62 around the rotation axis Ax3.

The rotating worm wheel 52 and the revolving eccentric shaft 61 cause the external gear 62 to move in the circumferential direction of the rotation axis Ax2 while drawing a circular locus whose radius is the distance between the rotation axis Ax2 and the rotation axis Ax3. be done. In other words, the external gear 62 revolves around the rotation axis Ax2.

The external gear 62 includes a first flat surface 62b, a second flat surface 62c, a concave surface 62d, a convex surface 62e, a plurality of external teeth 62f, a flange 62g, two guide projections 62h shown in FIG. and an inner peripheral surface 62i. The first plane 62b may be referred to as the fourth plane. The second plane 62c may be referred to as the fifth plane. Concave surface 62d may be referred to as a first surface. Convex surface 62e may be referred to as a second surface. External tooth 62f may be referred to as a first tooth.

The first plane 62b is a substantially flat annular surface facing one side in the axial direction of the rotation axis Ax3. The second plane 62c is located on the opposite side of the first plane 62b and is a substantially flat annular surface facing the other side in the axial direction of the rotation axis Ax3.

The concave surface 62d is a substantially flat surface recessed from the first plane 62b and closer to the second plane 62c than the first plane 62b. The concave surface 62d faces one side in the axial direction of the rotation axis Ax3 and is located inside the first plane 62b in the radial direction of the rotation axis Ax3. One end of the insertion hole 62a opens at a concave surface 62d.

The convex surface 62e is a substantially flat surface that protrudes from the second plane 62c and is farther from the first plane 62b than the second plane 62c. The convex surface 62e is located on the opposite side of the concave surface 62d and faces the other side in the axial direction of the rotation axis Ax3. The convex surface 62e is positioned inside the second plane 62c in the radial direction of the rotation axis Ax3. The other end of the insertion hole 62a opens at a convex surface 62e. The second flat surface 62c and the convex surface 62e face the worm wheel 52 with a gap therebetween.

The external teeth 62f are positioned outside the first plane 62b in the radial direction of the rotation axis Ax3. The external teeth 62f protrude outward in the radial direction of the rotation axis Ax3 and are arranged at substantially equal intervals in the circumferential direction of the rotation axis Ax3.

The flange 62g is a substantially annular portion surrounding the second plane 62c. The flange 62g is connected to the second plane 62c so as to protrude from the second plane 62c to the other side in the axial direction of the rotation axis Ax3.

As shown in FIG. 5, the guide protrusion 62h protrudes from the flange 62g to the other side in the axial direction of the rotation axis Ax3. The two guide protrusions 62h are separated from each other in the first direction D1. The first direction D1 is a direction orthogonal to the axial direction of the rotation axis Ax2 (rotation axis Ax3). The insertion hole 62a, the second flat surface 62c, and the convex surface 62e are positioned between the two guide projections 62h in the first direction D1.

The first flat surface 62b, the second flat surface 62c, the concave surface 62d, the convex surface 62e, the external teeth 62f, the flange 62g, and the guide projections 62h are formed by, for example, half punching (embossing, half punching, half shearing). be done. Therefore, as shown in FIG. 4, the distance (thickness) between the first plane 62b and the second plane 62c is equal to the distance (thickness) between the concave surface 62d and the convex surface 62e, and It is equal to the thickness of flange 62g. The processing method and thickness of the external gear 62 are not limited to this example.

The inner peripheral surface 62i forms an insertion hole 62a. In other words, the inner peripheral surface 62i is the edge of the insertion hole 62a. The inner peripheral surface 62i faces the outer peripheral surface 61a of the eccentric shaft 61 via the bushing 63 .

The bush 63 is made of synthetic resin, for example. Note that the bush 63 may be made of another material. The bushing 63 has a tubular portion 63a, a first flange portion 63b, and a second flange portion 63c. One of the first flange portion 63b and the second flange portion 63c of the bush 63 may be omitted.

The cylindrical portion 63 a is formed in a substantially cylindrical shape and is press-fitted into the insertion hole 62 a of the external gear 62 . The cylindrical portion 63 a contacts the inner peripheral surface 62 i of the external gear 62 and is interposed between the inner peripheral surface 62 i and the outer peripheral surface 61 a of the eccentric shaft 61 . The tubular portion 63a contacts the first portion 61aa of the outer peripheral surface 61a. The coefficient of friction at the contact portion between the cylindrical portion 63a and the first portion 61aa is lower than the coefficient of friction when the cylindrical portion 63a and the second portion 61ab are in contact with each other. A second portion 61ab of the outer peripheral surface 61a is separated from the bush 63 in the axial direction of the rotation axis Ax3.

The first flange portion 63b protrudes outward from the cylinder portion 63a in the radial direction of the rotation axis Ax3 and is formed in a substantially annular shape. The first collar portion 63 b contacts the concave surface 62 d of the external gear 62 . The outer diameter of the first collar portion 63b is smaller than the outer diameter of the concave surface 62d.

The second collar portion 63c protrudes outward from the cylindrical portion 63a in the radial direction of the rotation axis Ax3 and is formed in a substantially annular shape. The second collar portion 63 c contacts the convex surface 62 e of the external gear 62 . A portion of the external gear 62 is held between the first flange portion 63b and the second flange portion 63c. Therefore, the external gear 62 and the bush 63 are restricted from moving relative to each other in the axial direction of the rotation axis Ax3.

In the bushing 63 of this embodiment, the first collar portion 63b is formed in advance. The second collar portion 63c is formed, for example, by caulking after the external gear 62 is press-fitted into the cylindrical portion 63a. Note that the first collar portion 63b may be formed by crimping.

The stopper plate 64 is positioned between the worm wheel 52 and the external gear 62 in the axial direction of the rotation axis Ax2 (rotation axis Ax3). The stopper plate 64 is supported by the housing 36 and supports the external gear 62 .

The stopper plate 64 is made of metal, for example. Note that the stopper plate 64 may be made of another material. The stopper plate 64 is molded by press working, for example. Therefore, the stopper plate 64 has a sagging surface 64a and a burr surface 64b. The sagging surface 64a may be referred to as a first surface. Burr surface 64b may be referred to as a second surface.

The sagging surface 64a is a substantially flat surface facing one side in the axial direction of the rotation axis Ax2. The sagging surface 64 a faces the external gear 62 and supports a flange 62 g of the external gear 62 . The burr surface 64b is on the opposite side of the sagging surface 64a and is a substantially flat surface facing the other side in the axial direction of the rotation axis Ax2. A portion of the burr surface 64 b faces the housing 36 and is supported by the housing 36 . Another part of the burr surface 64b faces the worm wheel 52 through a gap.

FIG. 6 is an exemplary cross-sectional view schematically showing part of the housing 36 and part of the stopper plate 64 of the first embodiment along line F6-F6 of FIG. As shown in FIG. 6, the stopper plate 64 has a hanging edge 64c and a projecting edge 64d.

The hanging edge portion 64c is a so-called shear drop, and is a portion that hangs down (recessed) from the edge of the shear drop surface 64a toward the burr surface 64b. The projecting edge portion 64d is a so-called burr, and is a portion projecting from the edge of the burr surface 64b to the other side in the axial direction of the rotation axis Ax2. The other side in the axial direction of the rotation axis Ax2 is the direction away from the sagging surface 64a. The hanging edge portion 64c and the protruding edge portion 64d may be formed by a method other than press working.

FIG. 7 is a side view showing the housing 36 and stopper plate 64 of the first embodiment. As shown in FIG. 7, the stopper plate 64 has a first guide 71 and two second guides 72 .

The first guide 71 and the second guide 72 are arranged in the second direction D2. The second direction D2 is a direction orthogonal to the axial direction of the rotation axis Ax2 (rotation axis Ax3) and different from the first direction D1. In this embodiment, the second direction D2 is a direction orthogonal to the first direction D1. The first guide 71 and the second guide 72 each have a sagging surface 64a and a burr surface 64b.

The first guide 71 is formed in a rotationally symmetrical and mirror-symmetrical shape. Note that the shape of the first guide 71 is not limited to this example. The first guide 71 is provided with an insertion hole 71a and two guide grooves 71b. The insertion hole 71a and the guide groove 71b extend in the axial direction of the rotation axis Ax2 and open to the sagging surface 64a and the burr surface 64b of the first guide 71, respectively.

The insertion hole 71 a is positioned substantially in the center of the first guide 71 . As shown in FIG. 4, the eccentric shaft 61 is inserted through the insertion hole 71a. The diameter of the insertion hole 71 a is larger than the diameter of the outer peripheral surface 61 a of the eccentric shaft 61 . The eccentric shaft 61 is separated from the stopper plate 64 even if it moves in the circumferential direction of the rotation axis Ax2.

As shown in FIG. 7, the two guide grooves 71b are separated from each other in the first direction D1. In this embodiment, the guide groove 71b is a notch that opens at the end of the first guide 71 in the first direction D1. Note that the guide groove 71b is not limited to this example. The insertion hole 71a is positioned between the two guide grooves 71b in the first direction D1.

The guide projections 62h of the external gear 62 are fitted into the corresponding guide grooves 71b. The guide projection 62h is supported by the first guide 71 so as to be movable in the first direction D1 along the guide groove 71b. Thereby, the first guide 71 allows movement of the external gear 62 in the first direction D1, and restricts relative rotation between the stopper plate 64 and the external gear 62 around the rotation axis Ax3. The first guide 71 may restrict relative rotation between the stopper plate 64 and the external gear 62 by other means so that the external gear 62 can move in the first direction D1.

The two second guides 72 protrude from the first guide 71 to one side and the other side in the second direction D2. In other words, the two second guides 72 protrude from the first guide 71 in opposite directions.

Hereinafter, one of the second guides 72 may be referred to as the second guide 72A and the other as the second guide 72B. Note that the second guides 72A and 72B are simply referred to as the second guides 72 in the description common to the second guides 72A and 72B.

The center C1 of the second guide 72A is different from the center C2 of the second guide 72B in a third direction D3 orthogonal to the axial direction of the rotation axis Ax2 (rotation axis Ax3) and orthogonal to the second direction D2. in position. In this embodiment, the third direction D3 is substantially the same direction as the first direction D1. Note that the third direction D3 and the first direction D1 may be different.

In the present embodiment, the center C1 of the second guide 72A is at substantially the same position as the center C3 of the stopper plate 64 in the third direction D3. On the other hand, the center C2 of the second guide 72B is located at a position different from the center C3 of the stopper plate 64 in the third direction D3.

The second guides 72 each have a first side edge 72a and a second side edge 72b. The first side edge 72a faces one side of the third direction D3 (upward in FIG. 7) and extends in the second direction D2. The second side edge 72b faces the other side of the third direction D3 (downward in FIG. 7) and extends in the second direction D2.

The first side edge 72a of the second guide 72A and the first side edge 72a of the second guide 72B are arranged on the same line. In other words, in the third direction D3, the first side edge 72a of the second guide 72A and the first side edge 72a of the second guide 72B are at substantially the same position.

On the other hand, in the third direction D3, the second side edge 72b of the second guide 72A is located at a position different from the second side edge 72b of the second guide 72B. Therefore, the length (width) of the second guide 72A and the length (width) of the second guide 72B are different in the third direction D3.

The positions and widths of the second guides 72A and 72B are not limited to the above examples. For example, both the center C1 of the second guide 72A and the center C2 of the second guide 72B may be at positions different from the center C3 of the stopper plate 64 in the third direction D3.

The second guide 72 is supported by the housing 36 so as to be movable in the second direction D2. Thereby, the stopper plate 64 is restricted from rotating relative to the housing 36 around the center C3.

As described above, the stopper plate 64 restricts the rotation (rotation) of the external gear 62 about the rotation axis Ax3. Therefore, the external gear 62 translates (revolves) in the circumferential direction of the rotation axis Ax2 while its rotation is restricted.

As shown in FIG. 4, the internal gear 65 is formed in a plate shape centered on the rotation axis Ax2. The output shaft 43 is integrally rotatable with the internal gear 65 around the rotation axis Ax2.

The internal gear 65 has a flat surface 65b, a flange 65c and a plurality of internal teeth 65d. Plane 65b may be referred to as a third plane. The inner tooth 65d may be referred to as a second tooth.

The plane 65b is a substantially flat surface facing the other side in the axial direction of the rotation axis Ax2. The plane 65b faces the first plane 62b of the external gear 62 through a gap. Note that the plane 65b may contact the first plane 62b.

The distance between the flat surface 65b and the first flat surface 62b of the external gear 62 is shorter than the distance between the flat surface 65b and the concave surface 62d. That is, the first plane 62b is closer to the plane 65b than the concave surface 62d. Also, the distance between the flat surface 65b and the concave surface 62d is longer than the thickness of the bushing 63 . Therefore, the first collar portion 63b of the bushing 63 is separated from the flat surface 65b.

The flange 65c is a substantially annular portion surrounding the plane 65b. The flange 65c is connected to the plane 65b so as to protrude from the plane 65b toward the other side in the axial direction of the rotation axis Ax2. Flange 65 c is supported by flange 62 g of external gear 62 .

The internal teeth 65d protrude inward in the radial direction of the rotation axis Ax2 from the flange 65c and are arranged at substantially equal intervals in the circumferential direction of the rotation axis Ax2. At least one of the internal teeth 65 d meshes with at least one of the external teeth 62 f of the external gear 62 .

In this embodiment, the number of internal teeth 65d is greater than the number of external teeth 62f. For example, the number of internal teeth 65d is one or two more than the number of external teeth 62f. The inner teeth 65d and the outer teeth 62f mesh at one point. When the external gear 62 moves in the circumferential direction of the rotation axis Ax2, the meshing portion between the internal teeth 65d and the external teeth 62f moves around the rotation axis Ax2, and the internal gear 65 rotates around the rotation axis Ax2. That is, the internal gear 65 is rotated by the external gear 62 around the rotation axis Ax2.

Since the number of internal teeth 65 d is greater than the number of external teeth 62 f in the second reduction section 42 , the internal gear 65 rotates at a reduced speed with respect to the worm wheel 52 . The output shaft 43 attached to the internal gear 65 and the pinion 29 a provided on the output shaft 43 rotate integrally with the internal gear 65 . The external gear 62 and internal gear 65 transmit rotation between the worm wheel 52 and the output shaft 43 .

The housing 36 is made of synthetic resin, for example. However, the housing 36 may be made of other materials such as metal. As shown in FIG. 5 , the housing 36 has a motor holding portion 81 and a mechanism holding portion 82 .

A mounting opening 84 is provided in the motor holding portion 81 . The mounting opening 84 is a hole that opens in the axial direction of the rotation axis Ax1. The motor 31 is attached to the motor holding portion 81 by being fitted into the attachment opening 84 .

The mechanism holding portion 82 is formed integrally with the motor holding portion 81 . The mechanism holding portion 82 has an outer surface 82a facing one side in the axial direction of the rotation axis Ax2. A housing opening 85 is provided in the mechanism holding portion 82 . The accommodation opening 85 is a bottomed hole that opens to the outer surface 82a. The accommodation opening 85 communicates with the mounting opening 84 . The rotation transmission mechanism 35 and washer 38 are housed in the housing opening 85 .

FIG. 8 is an exemplary side view that schematically illustrates the housing 36 of the first embodiment. As shown in FIG. 8 , the receiving opening 85 has a first receiving portion 87 and two second receiving portions 88 .

As shown in FIG. 4 , the output shaft 43 , the worm wheel 52 , the eccentric shaft 61 , the external gear 62 , the bushing 63 , the first guide 71 of the stopper plate 64 , and the internal gear 65 are installed in the first accommodating portion 87 . is accommodated. The housing 36 has an inner surface 87a and a bottom surface 87b of the first accommodating portion 87. As shown in FIG. The inner surface 87a of the first receiving portion 87 may be referred to as the inner surface of the receiving opening. The bottom surface 87b of the first receiving portion 87 may be referred to as the bottom surface of the receiving opening.

The inner surface 87a of the first accommodating portion 87 faces inward in the radial direction of the rotation axis Ax2 and faces the rotation transmission mechanism 35 with a gap therebetween. A bottom surface 87b of the first housing portion 87 faces one side in the axial direction of the rotation axis Ax2 and faces the rotation transmission mechanism 35 with a gap therebetween.

As shown in FIG. 8 , the housing 36 further has a first support portion 91 , a second support portion 92 and a plurality of ribs 93 . The first support portion 91 , the second support portion 92 and the ribs 93 each protrude from the bottom surface 87 b of the first accommodation portion 87 .

The first support portion 91 and the second support portion 92 are each formed in a substantially annular shape extending in the circumferential direction of the rotation axis Ax2. The first support portion 91 and the second support portion 92 are not limited to this example, and may be formed by, for example, a plurality of protrusions protruding from the bottom surface 87b and arranged in the circumferential direction of the rotation axis Ax2. The first support portion 91 and the second support portion 92 are separated from the inner surface 87a of the first housing portion 87 inward in the radial direction of the rotation axis Ax2.

The inner diameter of the first support portion 91 is larger than the outer diameter of the second support portion 92 . Therefore, the second support portion 92 is separated from the first support portion 91 inward in the radial direction of the rotation axis Ax2. The output shaft 43 is fitted inside the second support portion 92 . Thereby, the second support portion 92 supports the output shaft 43 rotatably around the rotation axis Ax2.

The rib 93 extends in the radial direction of the rotation axis Ax2 between the first support portion 91 and the second support portion 92 . In other words, the ribs 93 extend radially. The rib 93 is connected to the first support portion 91 and the second support portion 92 .

The two second accommodation portions 88 extend from the first accommodation portion 87 to one side and the other side in the second direction D2. As shown in FIG. 7, the corresponding second guide 72 is accommodated in the second accommodating portion 88 so as to allow movement of the stopper plate 64 in the second direction D2. The housing 36 has respective inner surfaces 88a and bottom surfaces 88b of the second receiving portions 88 .

The inner surface 88 a of the second housing portion 88 faces the first side edge 72 a and the second side edge 72 b of the second guide 72 . The inner surface 88 a limits relative rotation of the housing 36 and the stopper plate 64 by supporting the second guide 72 . That is, the second guide 72 is accommodated in the second accommodation portion 88 so as to restrict the relative rotation of the housing 36 and the stopper plate 64 .

As shown in FIG. 4, the bottom surface 88b of the second accommodating portion 88 faces the burr surface 64b of the corresponding second guide 72 with a space therebetween, toward one side in the axial direction of the rotation axis Ax2. The bottom surface 88b is closer to the stopper plate 64 than the bottom surface 87b of the first accommodating portion 87 is.

Housing 36 further has two protrusions 95 . Each projecting portion 95 projects from the bottom surface 88b of the corresponding second accommodating portion 88 and supports the burr surface 64b of the corresponding second guide 72 . As a result, the protruding edge 64d of the stopper plate 64 is separated from the bottom surface 88b.

As shown in FIG. 8 , the projecting portion 95 is spaced apart from the inner surface 88 a of the second housing portion 88 . The center of the projecting portion 95 is positioned at the center of the bottom surface 88b of the corresponding second accommodating portion 88 in the third direction D3. The protruding portion 95 is positioned at the end closer to the first accommodating portion 87 among both ends of the bottom surface 88b corresponding in the second direction D2. On the other hand, the projecting portion 95 is separated from the end far from the first receiving portion 87 among the corresponding ends of the bottom surface 88b in the second direction D2. The projecting portion 95 is spaced apart from the projecting edge portion 64d by being arranged as described above.

As shown in FIG. 7, the housing 36 has an engaging wall 101, an engaging projection 102, a first positioning projection 103, and a second positioning projection 104. As shown in FIG. Each of the engaging wall 101 and the engaging projection 102 can be called a first engaging portion. Engagement protrusion 102 may be referred to as a protrusion. The engaging wall 101 and the engaging projection 102 are positioned on one side of the second guide 72 in the third direction D3 (upward direction in FIGS. 7 and 8).

The engagement wall 101 is closer to the second guide 72B than the engagement protrusion 102 in the circumferential direction of the rotation axis Ax2. The engaging protrusion 102 is closer to the second guide 72A than the engaging wall 101 in the circumferential direction of the rotation axis Ax2.

FIG. 9 is an exemplary side view schematically showing part of the housing 36 and part of the stopper plate 64 of the first embodiment. As shown in FIG. 9, the engagement wall 101 is provided with an opening 101a. The opening 101a is a bottomed hole that opens to the outer surface 82a of the mechanism holding portion 82 at a position spaced outward from the first accommodating portion 87 in the radial direction of the rotation axis Ax2.

The engagement wall 101 has a first wall 101b, a second wall 101c, a third wall 101d and a fourth wall 101e. The first wall 101b is located between the opening 101a and the first housing portion 87. As shown in FIG.

The second wall 101c and the third wall 101d protrude outward in the radial direction of the rotation axis Ax2 from the first wall 101b. The opening 101a is positioned between the second wall 101c and the third wall 101d in the circumferential direction of the rotation axis Ax2. The second wall 101c is closer to the second guide 72B than the third wall 101d.

The fourth wall 101e is connected to the second wall 101c and the third wall 101d. An opening 101a is formed by the first wall 101b, the second wall 101c, the third wall 101d, and the fourth wall 101e.

As shown in FIG. 8 , each of the engaging protrusion 102 , the first positioning protrusion 103 , and the second positioning protrusion 104 has a substantially cylindrical shape and protrudes from the outer surface 82 a of the mechanism holding portion 82 . The diameter and cross-sectional area of the engaging protrusion 102 are greater than the diameter and cross-sectional area of the first positioning protrusion 103 and the diameter and cross-sectional area of the second positioning protrusion 104 . Furthermore, the engaging projection 102 is positioned radially outward of the rotation axis Ax2 relative to the first positioning projection 103 .

The first positioning protrusion 103 is positioned on one side of the second guide 72 in the third direction D3. The second positioning projection 104 is located on the other side of the second guide 72 in the third direction D3 (downward in FIGS. 7 and 8).

Two fixing holes 108 are provided in the housing 36 . The fixing hole 108 opens on the outer surface 82 a of the mechanism holding portion 82 .

The fixing hole 108 is located on the other side of the second guide 72 in the third direction D3.

The first positioning projection 103 is positioned between the engagement wall 101 and the engagement projection 102 in the circumferential direction of the rotation axis Ax2. Therefore, the engagement wall 101 is positioned between the second guide 72B and the first positioning protrusion 103 in the circumferential direction of the rotation axis Ax2. Also, the engaging projection 102 is positioned between the second guide 72A and the first positioning projection 103 in the circumferential direction of the rotation axis Ax2.

As shown in FIG. 4, the cover 37 is made of metal, for example. Note that the cover 37 may be made of other materials such as synthetic resin. As shown in FIG. 5, cover 37 is attached to housing 36 by, for example, three screws 111 and covers receiving opening 85 . The screw 111 , for example, penetrates the cover 37 and is inserted into a hole opened in the outer surface 82 a of the mechanism holding portion 82 .

As shown in FIG. 2 , the cover 37 is provided with an exposure hole 113 , two insertion holes 114 and two positioning holes 115 . By inserting the output shaft 43 through the exposure hole 113 , the pinion 29 a provided on the output shaft 43 is exposed to the outside of the housing 36 and the cover 37 . Two bolts 116 pass through the fixing hole 108 and the insertion hole 114 and are fixed to the arm 25 of FIG. 1, for example. The bolts 116 thereby connect the housing 36 and the cover 37 to the seat 11 of the vehicle 1 . The first positioning projection 103 and the second positioning projection 104 are fitted in the positioning hole 115 . Thereby, the cover 37 is positioned with respect to the housing 36 .

The cover 37 has a coupling portion 121 , an engaged claw 122 and an engaged portion 123 . Each of the engaged claw 122 and the engaged portion 123 can be referred to as a second engaging portion. Engaged pawl 122 may be referred to as a pawl. The coupling portion 121 , the engaged claw 122 , and the engaged portion 123 are positioned on one side of the second guide 72 in the third direction D<b>3 .

The joint 121 is, for example, a bolt welded to the cover 37 . Note that the coupling portion 121 is limited to this example, and may be, for example, a portion for coupling such as a rivet or a welded portion. The coupling portion 121 is positioned between the second guide 72A and the engaging projection 102 in the circumferential direction of the rotation axis Ax2. The coupling portion 121 is separated from the engaging protrusion 102 and the first positioning protrusion 103 . The distance between the coupling portion 121 and the first positioning protrusion 103 is longer than the distance between the coupling portion 121 and the engaging protrusion 102 .

The coupling portion 121 floats from the housing 36 in the axial direction of the rotation axis Ax2. In other words, coupling portion 121 is spaced apart from housing 36 . Separating the coupling portion 121 from the housing 36 improves the degree of freedom in arranging the coupling portion 121 . The joint 121 is fixed to the arm 25 of FIG. 1, for example. Thereby, the connecting portion 121 of the cover 37 is connected to the seat 11 of the vehicle 1 .

The speed reducer 32 is coupled to the seat 11 by a coupling portion 121 on one side of the second guide 72 in the third direction D3. Also, the reduction gear 32 is coupled to the seat 11 by a bolt 116 on the other side of the second guide 72 in the third direction D3. That is, the housing 36 is not coupled to the seat 11 on one side of the second guide 72 in the third direction D3. Note that the housing 36 is not limited to this example.

The engaged claw 122 is, for example, part of the cover 37 and is formed by bending. The engaged pawl 122 is inserted into the opening 101 a of the engaging wall 101 . Thereby, the engaged claw 122 engages with the engaging wall 101 .

The engaged claw 122 is positioned radially outward of the rotation axis Ax2 from the first wall 101b of the engaging wall 101 and extends along the first wall 101b. The engaged claw 122 has a thickness in the radial direction of the rotation axis Ax2 that is smaller than a width in the circumferential direction of the rotation axis Ax2.

As shown in FIG. 9, the second wall 101c of the engaging wall 101 is positioned between the engaged pawl 122 and the second guide 72B in the circumferential direction of the rotation axis Ax2. The engaged pawl 122 is positioned between the second wall 101c and the third wall 101d in the circumferential direction of the rotation axis Ax2 and faces the second wall 101c and the third wall 101d.

The fourth wall 101e is positioned radially outward of the rotation axis Ax2 relative to the engaged pawl 122. As shown in FIG. The engaged pawl 122 is positioned between the first wall 101b and the fourth wall 101e in the radial direction of the rotation axis Ax2.

The engaged claw 122 engages with the engaging wall 101 to limit deformation of the housing 36 such that the engaging wall 101 moves away from the rotation axis Ax2. The engagement between the engaging wall 101 and the engaged claw 122 will be illustrated in detail below.

For example, a collision may occur in front of the vehicle 1 and a load may be applied to the seat 11 due to the impact. At this time, a load acts on the stopper plate 64 via the rear link 27, the pinion 29a, the output shaft 43, the internal gear 65, and the external gear 62 in the circumferential direction of the rotation axis Ax3. Thereby, the second guide 72</b>B applies the load Fr<b>1 to the inner surface 88 a of the second housing portion 88 .

The load Fr1 acts on the portion 36a of the housing 36 located on one side in the third direction D3 with respect to the second guide 72B. The portion 36a includes an inner surface 88a of the second accommodation portion 88 in which the second guide 72B is accommodated, and an engagement wall 101. As shown in FIG.

The load Fr1 may deform the portion 36a so that the engagement wall 101 moves away from the rotation axis Ax2. In other words, load Fr1 may deform portion 36a such that receiving opening 85 is enlarged.

When the load Fr1 acts on the portion 36a, the engaged pawl 122 supports the first wall 101b of the engaging wall 101 from the outside in the radial direction of the rotation axis Ax2. Therefore, the engaged claw 122 limits deformation of the housing 36 such that the engaging wall 101 moves away from the rotation axis Ax2.

Furthermore, when the load Fr1 acts on the portion 36a, the pushed portion 36a moves slightly. For example, the second wall 101c moves away from the rotation axis Ax2 and approaches the engaged pawl 122 . Also, the third wall 101d moves away from the rotation axis Ax2 and away from the engaged pawl 122 . Generally, the movement of the second wall 101c and the third wall 101d increases the closer it is to the outer surface 82a of the mechanism holding portion 82 and the closer it is to the second guide 72B. Therefore, the portion 36a is twisted and deformed.

The engaged claw 122 supports the moving second wall 101c in the circumferential direction of the rotation axis Ax2. Thereby, the engaged pawl 122 limits deformation of the housing 36 . Furthermore, the second wall 101c applies a load to the engaged pawl 122 . However, the deformation of the engaged pawl 122 is restricted by the third wall 101 d supporting the engaged pawl 122 .

The engaging wall 101 and the engaged claw 122 are positioned between the second guide 72B, the first positioning projection 103 and the positioning hole 115 in the circumferential direction of the rotation axis Ax2. Therefore, the load caused by the load Fr1 acts more on the engaging wall 101 and the engaged claw 122 than on the first positioning projection 103 and the positioning hole 115 . Therefore, the durability of the portion where the first positioning projection 103 and the positioning hole 115 are fitted is improved.

Further, the engaging wall 101 and the engaged claw 122 are positioned between the second guide 72B and the portion where the cover 37 is attached to the housing 36 by the screw 111 in the circumferential direction of the rotation axis Ax2. Therefore, the load caused by the load Fr1 acts more on the engaging wall 101 and the engaged claw 122 than on the portion where the screws 111 are attached. For this reason, the durability of the mounting portion by the screws 111 is improved.

As shown in FIG. 2, the engaged portion 123 is part of the cover 37, for example. The engaged portion 123 is provided with an opening 123a. The opening 123a is, for example, a substantially circular hole. Further, the engaged portion 123 has an edge 123b that forms (defines) an opening 123a.

The engagement protrusion 102 is fitted in the opening 123 a of the engaged portion 123 . Thereby, the engaged portion 123 is engaged with the engaging projection 102 . A part of the edge 123b of the engaged portion 123 is located outside the engaging projection 102 in the radial direction of the rotation axis Ax2.

The gap between the engaging protrusion 102 and the edge 123b of the opening 123a is larger than the gap between the first positioning protrusion 103 and the edge of the positioning hole 115, and the gap between the second positioning protrusion 104 and the positioning hole 115 larger than the gap between the edges. Note that the sizes of the engaging projection 102 and the opening 123a are not limited to this example.

The engaged portion 123 engages with the engaging projection 102 to limit deformation of the housing 36 such that the engaging projection 102 moves away from the rotation axis Ax2. The engagement between the engaging protrusion 102 and the engaged portion 123 will be exemplified in detail below.

For example, a collision may occur behind the vehicle 1 and a load may be applied to the seat 11 due to the impact. At this time, a load acts on the stopper plate 64 in the circumferential direction of the rotation axis Ax3. As a result, the second guide 72A applies a load Fr2 to the inner surface 88a of the second accommodating portion 88, as shown in FIG.

The load Fr2 acts on the portion 36b of the housing 36 located on one side of the second guide 72A in the third direction D3. The portion 36b includes an inner surface 88a of a second accommodation portion 88 in which the second guide 72A is accommodated, and an engaging projection 102. As shown in FIG.

The load Fr2 may deform the portion 36b such that the engaging protrusion 102 moves away from the rotation axis Ax2. In other words, load Fr2 may deform portion 36b such that receiving opening 85 is enlarged.

When the load Fr2 acts on the portion 36b, the edge 123b of the engaged portion 123 supports the engaging projection 102 from the outside in the radial direction of the rotation axis Ax2. Therefore, the engaged portion 123 limits deformation of the housing 36 such that the engaging projection 102 moves away from the rotation axis Ax2.

The engaging protrusion 102 and the engaged portion 123 are positioned between the second guide 72A and the first positioning protrusion 103 and the positioning hole 115 in the circumferential direction of the rotation axis Ax2. Therefore, the load caused by the load Fr2 acts more on the engaging projection 102 and the engaged portion 123 than on the first positioning projection 103 and the positioning hole 115 . Therefore, the durability of the portion where the first positioning projection 103 and the positioning hole 115 are fitted is improved.

Furthermore, the engaging protrusion 102 and the engaged portion 123 are positioned between the second guide 72A and the attachment portion by the screw 111 in the circumferential direction of the rotation axis Ax2. For this reason, the load caused by the load Fr2 acts more on the engaging projection 102 and the engaged portion 123 than on the attachment portion by the screw 111 . For this reason, the durability of the mounting portion by the screws 111 is improved.

Since the connecting portion 121 is connected to the sheet 11 , a tensile load is generated between the connecting portion 121 and, for example, the engaging protrusion 102 and the engaged portion 123 . However, the engaging protrusion 102 and the engaged portion 123 are separated from the coupling portion 121 in the circumferential direction of the rotation axis Ax2. Therefore, the load can be dispersed between the engaging protrusion 102 and the engaged portion 123 and the connecting portion 121 .

Furthermore, in the circumferential direction of the rotation axis Ax2, the first positioning projection 103 and the positioning hole 115 are further away from the coupling portion 121 than the engaging projection 102 and the engaged portion 123 are. As a result, the load acts more on the engaging projection 102 and the engaged portion 123 than on the first positioning projection 103 and the positioning hole 115 . Therefore, the durability of the portion where the first positioning projection 103 and the positioning hole 115 are fitted is improved.

The engaging protrusion 102 and the engaged portion 123 are positioned radially outward of the rotation axis Ax2 relative to the coupling portion 121 . Therefore, the engaging projection 102 and the engaged portion 123 can limit deformation of the housing 36 such that the engaging projection 102 moves away from the rotation axis Ax2.

The load Fr2 acting from a rearward collision of the vehicle 1 is generally stronger than the load Fr1 acting from a frontal collision of the vehicle 1 . In this embodiment, the load resulting from the load Fr1 is input to the engaged claw 122 as the bending load. On the other hand, the load caused by the load Fr2 is input to the edge 123b of the engaged portion 123 as a shear load. In this manner, designing such that a stronger load acts on the engaged portion 123 with higher durability improves the durability of the reduction gear 32 .

As shown in FIG. 5, in this embodiment the washer 38 is a wave washer. The washer 38 has three first ridges 38a, three second ridges 38b and an inner edge 38c. The number of first peaks 38a and second peaks 38b is not limited to this example, and may be more than three or less than three.

As shown in FIG. 4, the first peak 38a is the apex of the washer 38 on one side in the axial direction of the rotation axis Ax2. The second peak 38b is the vertex of the washer 38 on the other axial side of the rotation axis Ax2. That is, the washer 38 forms three vertices (first ridges 38a) on one side in the axial direction of the rotation axis Ax2, and three vertices (second ridges 38b) on the other side in the axial direction of the rotation axis Ax2. is formed into a corrugated shape that forms a

As shown in FIG. 4 , the washer 38 is interposed between the bottom surface 87 b of the first accommodating portion 87 and the worm wheel 52 of the rotation transmission mechanism 35 . The first peak 38a contacts the support projection 52d of the worm wheel 52. As shown in FIG. The second peak 38b contacts the bottom surface 87b of the first housing portion 87. As shown in FIG.

The contact area between the washer 38 and the bottom surface 87 b of the first accommodation portion 87 is larger than the contact area between the washer 38 and the worm wheel 52 . Therefore, even if the worm wheel 52 rotates, the washer 38 is kept substantially at the same position without rotating with respect to the housing 36 .

A portion of output shaft 43 , worm wheel 52 , eccentric shaft 61 and internal gear 65 are located between cover 37 and washer 38 . The washer 38 pushes a portion of the output shaft 43 , the worm wheel 52 , the eccentric shaft 61 and the internal gear 65 toward the cover 37 due to its elasticity. As a result, for example, the output shaft 43 and the internal gear 65 are pressed against the cover 37, and the rotation transmission mechanism 35 is prevented from generating noise. Note that the washer 38 may push other parts of the rotation transmission mechanism 35 toward the cover 37 .

FIG. 10 is an exemplary perspective view schematically showing the housing 36 and washer 38 of the first embodiment. As shown in FIG. 10, the washer 38 is positioned between the first support portion 91 and the inner surface 87a of the first housing portion 87 in the circumferential direction of the rotation axis Ax2. An inner surface 87 a of the first accommodating portion 87 is separated from the washer 38 .

The inner edge 38c is an inner edge of the washer 38 in the radial direction of the rotation axis Ax2. Therefore, the inner edge 38c faces inward in the radial direction of the rotation axis Ax2. Further, the inner edge 38c faces the output shaft 43 with a gap therebetween.

The first support portion 91 is interposed between the inner edge 38 c of the washer 38 and the output shaft 43 . An inner edge 38 c of the washer 38 can be supported by the first support portion 91 at a position spaced apart from the output shaft 43 . In other words, the first support portion 91 restricts the washer 38 from approaching the output shaft 43 .

In the speed reducer 32 according to the first embodiment described above, the second guide 72 of the stopper plate 64 protrudes from the first guide 71 in the second direction D2 orthogonal to the axial direction of the rotation axis Ax2. . A second accommodation portion 88 accommodates the second guide 72 , and an inner surface 88 a of the second accommodation portion 88 limits relative rotation of the housing 36 and the stopper plate 64 . That is, when the stopper plate 64 tries to rotate with respect to the housing 36, the second guide 72 abuts against the inner surface 88a of the second accommodating portion 88, and the inner surface 88a of the second accommodating portion 88 is aligned with the rotation axis Ax2. Input loads Fr1 and Fr2 in the circumferential direction of . In addition, the coupling portion 121 of the cover 37 is positioned on one side of the second guide 72 in a third direction D3 orthogonal to the axial direction of the rotation axis Ax2 and orthogonal to the second direction D2. , and is coupled to the seat 11 of the vehicle 1 . Therefore, on one side of the third direction D3 with respect to the second guide 72, the housing 36 is not directly coupled to the seat 11 and is free with respect to the seat 11. FIG. The portions 36a and 36b of the housing 36 on one side of the second guide 72 in the third direction D3 may deform away from the rotation axis Ax2 when the loads Fr1 and Fr2 are applied.

In this embodiment, the housing 36 has an engaging wall 101 and an engaging projection 102 located on one side of the second guide 72 in the third direction D3. Further, the cover 37 engages with the engaging wall 101 and the engaging projection 102 to limit deformation of the housing 36 such that the engaging wall 101 and the engaging projection 102 move away from the rotation axis Ax2. 122 and engaged portion 123 . As a result, the portions 36a and 36b of the housing 36 on one side of the second guide 72 in the third direction D3 are kept away from the rotation axis Ax2 even if the loads Fr1 and Fr2 are input from the second guide 72. Deformation is suppressed. That is, deformation of the housing 36 is suppressed.

An opening 123a is provided in the engaged portion 123, and the engaging projection 102 is fitted in the opening 123a. As a result, the portion 36b of the housing 36 on one side of the third direction D3 with respect to the second guide 72 is deformed to move away from the rotation axis Ax2, deformed to approach the rotation axis Ax2, and deformed to move closer to the rotation axis Ax2. Deformation in the circumferential direction is suppressed. Therefore, deformation of the housing 36 is suppressed.

The engaged claw 122 is a claw extending along the first wall 101 b of the engaging wall 101 . This suppresses the reduction gear 32 from becoming large in the radial direction. Furthermore, the degree of freedom in arrangement of the engaging wall 101 and the engaged claw 122 is improved.

The engaging wall 101 has a second wall 101c located between the engaged pawl 122 and the second guide 72B in the circumferential direction of the rotation axis Ax2 and facing the engaged pawl 122 . The portion 36a of the housing 36 on one side of the third direction D3 with respect to the second guide 72 moves in the circumferential direction when the load Fr1 is input from the second guide 72 in the circumferential direction of the rotation axis Ax2. Transform into However, the deformation is suppressed by the engaged claw 122 supporting the second wall 101c. Therefore, deformation of the housing 36 is suppressed.

The engaged claw 122 is positioned between the second wall 101c and the third wall 101d in the circumferential direction of the rotation axis Ax2. When the load Fr1 is input from the second guide 72 in the circumferential direction of the rotation axis Ax2, the portion 36a of the housing 36 on one side of the second guide 72 in the third direction D3 moves in the circumferential direction and It is twisted away from the rotation axis Ax2. The twist causes the housing 36 to input a load to the engaged claws 122 . However, since the third wall 101d supports the engaged claw 122, deformation of the engaged claw 122 is suppressed.

The fourth wall 101e is positioned radially outward of the rotation axis Ax2 from the engaged pawl 122 and is connected to the second wall 101c and the third wall 101d. Thereby, the first wall 101b, the second wall 101c, the third wall 101d, and the fourth wall 101e are formed in a frame shape, and the rigidity of the engaging wall 101 is improved.

The bush 63 protrudes from the tubular portion 63a interposed between the outer peripheral surface 61a of the eccentric shaft 61 and the inner peripheral surface 62i of the external gear 62 and the radially outer side of the rotation axis Ax3, and contacts the concave surface 62d. and a first collar portion 63b. The contact area between the bushing 63 and the external gear 62 is increased by the first flange portion 63b. As a result, relative rotation between the bush 63 and the external gear 62 is suppressed, and relative rotation between the eccentric shaft 61 and the external gear 62 is stabilized. Furthermore, the bush 63 is prevented from coming off from the insertion hole 62a.

The bushing 63 has a second collar portion 63c that protrudes outward from the cylindrical portion 63a in the radial direction of the rotation axis Ax3 and contacts the convex surface 62e. The contact area between the bushing 63 and the external gear 62 is further increased by the second collar portion 63c. As a result, relative rotation between the bush 63 and the external gear 62 is suppressed, and relative rotation between the eccentric shaft 61 and the external gear 62 is stabilized. Furthermore, since the external gear 62 is held between the first flange portion 63b and the second flange portion 63c, the bush 63 is prevented from coming off from the insertion hole 62a.

The external gear 62 has a first plane 62b closer to the plane 65b than the concave plane 62d. The bushing 63 is separated from the internal gear 65 . As a result, noise due to contact between the bush 63 and the internal gear 65 and reduction in meshing between the external teeth 62f and the internal teeth 65d are suppressed.

The external gear 62 has a second plane 62c located opposite the first plane 62b. The distance between concave surface 62d and convex surface 62e is equal to the distance between first plane 62b and second plane 62c. As a result, reduction in the thickness of the external gear 62 is suppressed, and the external gear 62 can stably hold the eccentric shaft 61 . Further, the concave surface 62d can be formed by half-blanking, for example. Therefore, the distance (depth) between the concave surface 62d and the first flat surface 62b can be easily adjusted according to the thickness of the first brim portion 63b so that the bush 63 is spaced apart from the internal gear 65. .

The outer peripheral surface 61a has a first portion 61aa that contacts the cylindrical portion 63a and a second portion 61ab that is spaced apart from the bush 63 in the axial direction of the rotation axis Ax2. The surface roughness of the first portion 61aa is lower than the surface roughness of the second portion 61ab. As a result, wear of the tubular portion 63a is suppressed, and the durability of the bush 63 is improved. Furthermore, there is no need for processing to reduce the surface roughness of the second portion 61ab, and an increase in the cost of the speed reducer 32 is suppressed.

An inner edge 38 c of the washer 38 can be supported by the first support portion 91 at a position spaced apart from the output shaft 43 . As a result, deterioration of the durability of the washer 38 and abnormal noise due to rubbing between the inner edge 38c of the washer 38 and the output shaft 43 are suppressed.

An inner surface 87 a of the first accommodation portion 87 of the accommodation opening 85 is separated from the washer 38 . This suppresses interference between the inner surface 87a of the first accommodating portion 87 and the elastically deformable washer 38 .

The second support portion 92 protrudes from the bottom surface 87 b of the first accommodation portion 87 of the accommodation opening 85 , is spaced inward from the first support portion 91 in the radial direction of the rotation axis Ax 2 , and supports the output shaft 43 . That is, the first support portion 91 is positioned radially outward of the rotation axis Ax2 relative to the second support portion 92 that supports the output shaft 43 . Furthermore, the washer 38 is separated from the first support portion 91 to the outside in the radial direction of the rotation axis Ax2. As a result, the washer 38 contacts the worm wheel 52 relatively outside in the radial direction of the rotation axis Ax<b>2 , and the rotation transmission mechanism 35 can be stably pushed toward the cover 37 .

The housing 36 has ribs 93 that protrude from the bottom surface 87b of the first accommodating portion 87, extend in the radial direction of the rotation axis Ax2, and are connected to the first support portion 91 and the second support portion 92. As shown in FIG. This suppresses deformation of the first support portion 91 and the second support portion 92 .

The washer 38 is a wave washer having three or more first ridges 38a contacting the rotation transmission mechanism 35 and three or more second ridges 38b contacting the bottom surface 87b of the first housing portion 87. be. This allows the washer 38 to stably push the rotation transmission mechanism 35 toward the cover 37 . Further, since the washer 38 is a wave washer, load fluctuations are moderated.

The stopper plate 64 has two second guides 72 projecting from the first guide 71 to one side and the other side in a second direction D2 orthogonal to the axial direction of the rotation axis Ax2. In a third direction D3 orthogonal to the axial direction of the rotation axis Ax2 and orthogonal to the second direction D2, the center C1 of the second guide 72A is at a position different from the center C2 of the second guide 72B. This prevents the stopper plate 64 from being arranged in the housing opening 85 in an incorrect posture in which the sagging surface 64a and the burr surface 64b are reversed.

The two second guides 72 have different lengths in the third direction D3. This prevents the stopper plate 64 from being arranged in the housing opening 85 in an incorrect posture in which the sagging surface 64a and the burr surface 64b are reversed.

The first side edge 72a of the second guide 72A and the first side edge 72a of the second guide 72B are arranged on the same line. However, in the third direction D3, the second side edge 72b of the second guide 72A is at a different position than the second side edge 72b of the second guide 72B. This prevents the stopper plate 64 from being arranged in the housing opening 85 in an incorrect posture in which the sagging surface 64a and the burr surface 64b are reversed.

The stopper plate 64 includes a sagging surface 64a facing the external gear 62, a burr surface 64b on the opposite side of the sagging surface 64a and at least partially facing the housing 36, and a burr surface 64b extending from the edge of the sagging surface 64a toward the burr surface 64b. It has a drooping edge 64c and a projecting edge 64d projecting from the edge of the burr surface 64b in a direction away from the sagging surface 64a. The hanging edge portion 64c and the projecting edge portion 64d may be formed by, for example, press working. In this case as well, the burr surface 64b on which the projecting edge 64d is provided faces the housing 36 instead of facing the external gear 62, thereby preventing the movement of the external gear 62 from being hindered.

For example, the hanging edge 64c of the sagging surface 64a may be further chamfered. In this case, for example, the chamfered hanging edge 64c can avoid the connecting portion (R portion) between the flange 62g of the external gear 62 and the guide projection 62h.

The housing 36 includes a bottom surface 88b of the second housing portion 88 facing the second guide 72 while facing the axial direction of the rotation axis Ax2, and a corresponding second housing portion 88b protruding from the bottom surface 88b of the second housing portion 88. and a projecting portion 95 capable of supporting the guide 72 . The projecting portion 95 is spaced apart from the projecting edge portion 64d. As a result, the stopper plate 64 is supported by the protruding portion 95, and interference of the protruding edge portion 64d with the housing 36 is suppressed.

The center of the projecting portion 95 is positioned at the center of the bottom surface 88b of the second accommodating portion 88 in the third direction D3. The protruding portion 95 is located at the end closer to the first accommodating portion 87 among both ends of the bottom surface 88b in the second direction D2, and is farther from the first accommodating portion 87 among both ends of the bottom surface 88b in the second direction D2. away from the edge. This prevents the protruding edge 64d from interfering with the housing 36, and allows the protruding portion 95 to support the second guide 72 movably in the second direction D2.

(Second embodiment)
A second embodiment will be described below with reference to FIG. In the following description of the embodiments, constituent elements having functions similar to those already explained may be assigned the same reference numerals as the constituent elements already explained, and further explanation may be omitted. In addition, a plurality of components with the same reference numerals may not all have common functions and properties, and may have different functions and properties according to each embodiment.

FIG. 11 is an exemplary cross-sectional view schematically showing the speed reduction gear 32 according to the second embodiment. As shown in FIG. 11, the washer 38 of the second embodiment is a disc spring. The washer 38 of the second embodiment also elastically pushes a portion of the output shaft 43, the worm wheel 52, the eccentric shaft 61, and the internal gear 65 toward the cover 37, as in the first embodiment.

As in the second embodiment, the washer 38 is not limited to the wave washer of the first embodiment. The washer 38 may be the disc spring of the second embodiment, or may be another washer such as a spring washer.

The shapes, materials, positions, functions, and relationships of each part and portion in the above multiple embodiments are not limited to what has been described and shown in the drawings. For example, the worm wheel 52 and the eccentric shaft 61 may be separate parts. Also, the output shaft 43 and the internal gear 65 may be separate parts.

Although the embodiments of the present invention have been illustrated above, the above-described embodiments and modifications are merely examples, and are not intended to limit the scope of the invention. The above embodiments and modifications can be implemented in various other forms, and various omissions, replacements, combinations, and modifications can be made without departing from the scope of the invention. Also, the configuration and shape of each embodiment and each modification can be partially exchanged.

DESCRIPTION OF SYMBOLS 1... Vehicle 11... Seat 31... Motor 32... Reduction gear 35... Rotation transmission mechanism 36... Housing 37... Cover 38... Washer 38a... First peak 38b... Second peak 38c Inner edge 43 Output shaft 52 Worm wheel 61 Eccentric shaft 61a Peripheral surface 61aa First portion 61ab Second portion 62 External gear 62a Insertion hole 62b First plane 62c Second plane 62d Concave surface 62e Convex surface 62f External tooth 62i Inner peripheral surface 63 Bush 63a Cylindrical portion 63b First flange 63c Second flange 64 stopper plate 64a sagging surface 64b burr surface 64c drooping edge 64d protruding edge 65 internal gear 65b plane 65d internal tooth 71 First guide 72, 72A, 72B Second guide 72a First side edge 72b Second side edge 82 Mechanism holding portion 82a Outer surface 85 Accommodating opening 87 Third 1 accommodation part 87a... inner surface 87b... bottom surface 88... second accommodation part 88a... inner surface 88b... bottom surface 91... first support part 92... second support part 93... rib 95 Projection portion 101 Engaging wall 101a Opening 101b First wall 101c Second wall 101d Third wall 101e Fourth wall 102 Engaging projection 121 Coupling portion 122 Engaged claw 123 Engaged portion 123a Opening Ax1, Ax2, Ax3 Rotation axis D1 First direction D2 Second direction D3 Third direction direction.

Claims (6)

a driven gear that is rotated about a rotation axis by the driving force of a drive mechanism; a first gear that is moved in a circumferential direction of the rotation axis by the driven gear; and a restricting member that restricts rotation of the first gear. , a second gear rotated around the rotation axis by the first gear; and
a housing having an outer surface facing in the axial direction of the rotating shaft, and provided with an accommodation opening that opens to the outer surface and accommodates the rotation transmission mechanism;
a cover attached to the housing and covering the receiving opening;
and
The restricting member includes a first guide that allows the first gear to move in a first direction perpendicular to the axial direction and restricts relative rotation between the restricting member and the first gear. , a second guide projecting from the first guide in a second direction orthogonal to the axial direction and different from the first direction;
The accommodation opening includes a first accommodation portion in which the driven gear, the first gear, the second gear, and the first guide are accommodated, and a direction extending from the first accommodation portion in the second direction. a second accommodating portion that extends in the second direction and accommodates the second guide so that the restricting member can move in the second direction;
The housing has an inner surface of the second accommodation portion that restricts relative rotation of the housing and the restricting member, and the second guide perpendicular to the axial direction and perpendicular to the second direction. and a first engaging portion located on one side of the third direction,
The cover is located on the one side in the third direction with respect to the second guide, is spaced apart from the housing, and has a coupling portion connectable to a vehicle seat. positioned on the one side of the third direction and engaged with the first engaging portion to limit deformation of the housing such that the first engaging portion moves away from the rotation axis; a second engaging portion;
reducer. An opening is provided in one of the first engaging portion and the second engaging portion,
The other of the first engaging portion and the second engaging portion has a projection that is fitted into the opening,
2. The speed reducer of claim 1. The first engaging portion has a first wall,
The second engaging portion has a claw positioned radially outward of the rotating shaft relative to the first wall and extending along the first wall,
2. The speed reducer of claim 1. 4. The reduction gear transmission according to claim 3, wherein said first engaging portion has a second wall located between said pawl and said second guide in said circumferential direction and facing said pawl. the first engaging portion has a third wall facing the pawl;
the pawl is positioned between the second wall and the third wall in the circumferential direction;
5. The speed reducer according to claim 4. 3. The first engaging portion has a fourth wall positioned radially outward of the rotating shaft relative to the pawl and connected to the second wall and the third wall. 5 reduction gear.

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