JP5731228B2 - Reclining device - Google Patents

Description

  The present invention has a cylindrical shape with one end portion being an open surface, and has a first member in which internal teeth are formed along the circumferential direction of the internal peripheral surface, and external teeth that can mesh with the internal teeth. And a lock position where the outer teeth mesh with the inner teeth, the outer teeth are arranged on the open surface side of the first member, and are provided to be rotatable relative to the first member in the circumferential direction. On the axis of relative rotation between the second member formed with guide means for guiding each pole between unlocked positions away from the internal teeth, and the first member and the second member And a cam that moves the pole in a direction in which the outer teeth mesh with the inner teeth when rotated in one direction, and the outer teeth of the pole are the inner teeth of the first member. A reclining device in which relative rotation between the first member and the second member is prohibited by meshing with About.

  A description will be given with reference to FIG. 6 which is an exploded perspective view of a conventional reclining device.

  A fitting hole 101 that rotatably supports the cylindrical portion 121 of the rotating shaft 120 is formed in the central portion of the base arm (second member) 100. Further, around the fitting hole 101, The two support portions 102 and 103 having the same cross-section projecting toward the ratchet 130 are coaxially formed with the fitting hole 101 so as to face each other.

  In the fitting hole 131 in the center of the cylindrical ratchet (first member) 130 whose one end is an open surface, cross-section arcuate supports 102 and 103 are rotatably fitted. Therefore, the ratchet 130 can tilt with respect to the base arm 100. And the outer peripheral part of the base arm 100 and the outer peripheral part of the ratchet 130 are joined by the attachment metal fitting 205 so that relative rotation is possible. Internal teeth are engraved on the inner peripheral surface of the ratchet 130.

  Guide protrusions 105 and 106 protrude toward the ratchet 130 on the upper surface of the base arm 100 facing the ratchet 130, and guide protrusions 107 and 108 protrude toward the ratchet 130 at the lower part. ing.

  The pole 140 is sandwiched between the guide surfaces 105a and 106a of the guide protrusions 105 and 106, and is slidably guided in a direction orthogonal to the central axis of the tilt, so that the outer teeth 141 at the front end can mesh with the inner teeth of the ratchet 130. It is configured as follows. Similarly, the pole 150 is sandwiched between the guide surfaces 107 a and 108 a of the guide protrusions 107 and 108, and is slidably guided in a direction perpendicular to the central axis of the tilt. The outer teeth 151 at the front end portion are the inner teeth of the ratchet 130. 134 is configured to be able to mesh.

  An oval hole 171 of the cam 170 is fitted in the second oval section 123 of the rotating shaft 120. The cam 170 is formed with arc-shaped elongated holes 172 and 173 into which the arc-shaped support portions 102 and 103 of the base arm 100 are loosely fitted, and the cam 170 rotates within a certain range with respect to the base arm 100. It can be done.

  That is, the cam 170 rotates together with the rotating shaft 120 and pushes the back surfaces 142 and 152 of the poles 140 and 150 in the direction of the external teeth 141 and 151 with the pressing portions 174 and 175, thereby external teeth 141 of the poles 140 and 150. , 151 is engaged with the internal teeth 133, 134 of the ratchet 130.

  The cam 170 has protrusions 176 and 177 protruding toward the ratchet 130, and the protrusions 176 and 177 are fitted in the holes 181 and 182 of the release plate 180. For this reason, the cam 170 and the release plate 180 rotate in conjunction with each other. The release plate 180 is formed with elongated hole-like cam holes 183 and 184 that fit into the projections 143 and 153 in the plate thickness direction of the poles 140 and 150. The shape of the cam holes 183 and 184 is the rotation. When the moving shaft 120 is rotated in the unlocking direction, the cam surfaces of the cam holes 183 and 184 press the projections 143 and 153, the poles 140 and 150 are moved backward, and the external teeth 141 and 151 at the front end are moved. The inner teeth 133 and 134 of the ratchet 130 are formed so as to be detached.

  In the reclining device having such a configuration, the cross-section arc-shaped support portions 102 and 103 of the base arm 100 are inserted through the cam 170 and the release plate 180 and are fitted into the fitting holes 131 of the ratchet 130. The axial length of rotation is longer. Therefore, the base arm 100 is manufactured by forging.

  The operation of the reclining device having the above configuration will be described. Usually, the cam 170 pushes the back surface of the poles 140 and 150 by the biasing force of the biasing means (not shown), the outer teeth 141 and 151 of the poles 140 and 150 mesh with the inner teeth 133 and 134 of the ratchet 130, and the ratchet ( The rotation of the seat back 130 is prohibited (locked state).

  The rotating shaft 120, the cam 170, and the release plate 180 are rotated clockwise in FIG. 1 against the urging force of the urging means.

  Then, the pressing of the cam 170 to the back surface of the poles 140 and 150 is released, and the cam surfaces of the cam holes 183 and 184 of the release plate 180 press the projections 143 and 153 of the poles 140 and 150, thereby the poles 140 and 150. Move back to the back side. Therefore, the poles 140 and 150 are guided by the guide surfaces 105a to 108a of the guide protrusions 105 to 108 and move to the back side, and the external teeth 141 and 151 of the poles 140 and 150 and the internal teeth 133 and 134 of the ratchet 130 The ratchet (seat back) 130 can be tilted (unlocked).

  When the operating force on the rotating shaft 120 is released, the biasing force of the biasing means causes the cam 170 to push the back surfaces of the poles 140 and 150, and the external teeth 141 and 151 of the poles 140 and 150 are the internal teeth 133 of the ratchet 130. 134 is engaged again, and the ratchet (seat back) 130 returns to the state where the rotation is prohibited (see, for example, Patent Document 1).

JP 2002-282078 A

  However, in the reclining device configured as shown in FIG. 6, the fitting hole 131 of the ratchet 130 has two cross-section arcuate support portions 102 formed around the fitting hole 101 formed in the center portion of the base arm 100. The ratchet 130 can be tilted with respect to the base arm 100 by being rotatably fitted to 103. However, since the diameters of the two cross-section arcuate support portions 102 and 103 are small, there is a problem that it is difficult to accurately align the base arm (second member) 100 and the ratchet (first member) 130.

  The cam 170 is provided on the shaft 120 that is rotatably supported by the fitting hole 101 of the base arm 100. However, since the diameter of the fitting hole 101 is small, there is a problem that it is difficult to accurately align the base arm (second member) 100 and the cam 170.

  The present invention has been made in view of the above problems, and an object thereof is to provide a reclining device capable of accurately aligning the first member and the second member, and the second member and the cam.

The invention according to claim 1, which solves the problem, has a cylindrical shape with one end portion being an open surface, and a first member in which internal teeth are formed along the circumferential direction of the internal peripheral surface, and the internal teeth A pole having external teeth that can mesh with the first member, and is laminated on the open surface side of the first member, and is provided to be rotatable relative to the first member in the circumferential direction, and the external teeth mesh with the internal teeth Between the first member and the second member, and a second member in which guide means for guiding each pole is formed between the locking position to be engaged and the unlocking position in which the outer teeth are separated from the inner teeth. A cam that is rotatably provided on the axis of relative rotation and moves the pole in a direction in which the external teeth mesh with the internal teeth when rotated in one direction, and the external teeth of the pole By meshing with the internal teeth of the first member, relative rotation between the first member and the second member is prohibited. In the reclining device, a guide protrusion is provided on a surface of the second member facing the bottom of the first member, and an outer peripheral surface of the cam is received on the shaft side of the relative rotation of the guide protrusion, and the cam A first member that rotatably supports the first member by receiving a circumferential surface of the first member on a side opposite to the axis of relative rotation of the guide protrusion. A reclining mechanism having a rotation support portion and a plurality of the guide projections .

  The invention according to claim 2 is characterized in that the cam rotation support portion of the guide projection and the first member rotation support portion are wrapped in the axial direction of the relative rotation. It is.

  The invention according to claim 3 is characterized in that the second member is located inside the first member, and the first member rotation support portion of the guide projection receives an inner peripheral surface of the first member. A reclining device according to claim 1 or 2.

  According to a fourth aspect of the present invention, there are a plurality of the poles, and the guide projections are arranged between the plurality of poles in a circular arc shape along a concentric circle centered on the axis of relative rotation. A reclining device according to any one of claims 1 to 3.

  The invention according to claim 5 is formed on the inner peripheral surface on the bottom surface side of the inner teeth of the first member, a first guide along the circumferential direction, a second guide having a smaller diameter than the first guide, Provided on the pole and capable of contacting the first guide and the second guide, and having an unlocking holding mechanism comprising a protrusion that holds the pole in the unlocked position when contacting the second guide. The reclining device according to any one of claims 1 to 4, wherein the first member rotation support portion of the guide protrusion receives the first guide.

  According to the first aspect of the present invention, the guide protrusion is provided on the surface of the second member facing the bottom of the first member, and the outer peripheral surface of the cam is provided on the shaft side of the relative rotation of the guide protrusion. A cam rotation support portion that rotatably supports the cam receives the circumferential surface of the first member on the opposite side of the relative rotation axis of the guide protrusion, and rotatably supports the first member. Since the first member rotation support portion is formed, the distance between the cam rotation support portion of the guide protrusion and the relative rotation shaft is the distance between the outer peripheral surface of the cam and the relative rotation shaft. Accurate axial alignment between the first member and the second member is possible.

  Further, the distance between the first member rotation support portion of the guide projection and the relative rotation axis is the distance between the peripheral surface of the first member and the relative rotation axis. Axis alignment is complete.

  According to the second aspect of the present invention, the cam rotation support portion of the guide protrusion and the first member rotation support portion wrap in the axial direction of the relative rotation, thereby shortening the protrusion amount of the guide protrusion. The second member can be manufactured with a press, and the cost can be reduced.

  Moreover, the axial thickness of the relative rotation of the reclining device can be reduced.

  According to the invention of claim 3, the second member is located inside the first member, and the first member rotation support portion of the guide protrusion receives the inner peripheral surface of the first member. The length in the radial direction around the axis of relative rotation of the reclining device can be shortened. Moreover, the axial thickness of the relative rotation of the reclining device can be reduced.

  According to a fourth aspect of the present invention, there are a plurality of the poles, and the guide protrusions are arranged between the plurality of poles in an arc shape along a concentric circle centered on the axis of relative rotation. Thus, since the distance between the guide protrusion and the axis of relative rotation can be set long, accurate axial alignment between the first member and the second member, and the second member and the cam can be performed.

  According to the fifth aspect of the present invention, the first member rotation support portion of the guide projection can receive the first guide of the unlocking holding mechanism, thereby reducing the thickness of the relative rotation of the ratchet in the axial direction, and the reclining device. The thickness in the axial direction of the relative rotation can be reduced.

It is a disassembled perspective view of the reclining apparatus of this embodiment. It is the front view seen from the arrow C direction at the time of attaching the reclining apparatus of FIG. FIG. 3 is a cross-sectional view taken along a cutting line AA in FIG. 2. FIG. 3 is a cross-sectional view taken along a cutting line BB in FIG. 2. It is a figure explaining the action | operation of the reclining apparatus shown in FIG. It is a disassembled perspective view of the conventional reclining apparatus.

  Next, embodiments of the present invention will be described with reference to the drawings.

  The reclining apparatus of this embodiment is demonstrated using FIGS. 1-4. 1 is an exploded perspective view of the reclining device of the present embodiment, FIG. 2 is a front view seen from the direction of arrow C when the reclining device of FIG. 1 is assembled, and FIG. 3 is a cross section taken along the section line AA of FIG. 4 and 4 are cross-sectional views taken along the cutting line BB in FIG.

  1 to 4, a ratchet (first member) 21 provided on the seat back side is a bottomed cylinder formed by pressing a disk-shaped plate material, and a circular recess 21a is formed. The circular recess 21a is formed with a small diameter portion 21b and a large diameter portion 21c from the bottom surface side. Inner teeth 23 are formed in the entire circumferential direction on the inner peripheral surface of the large diameter portion 21c. As shown in FIG. 2, three concave portions are formed in the circumferential surface of the small diameter portion 21b along the circumferential direction. The concave portion is the first guide 21e, and the peripheral surface other than the concave portion is the second guide 21f having a smaller diameter than the first guide 21e. A through hole 21d is formed in the center of the circular recess 21a.

  The base plate (second member) 25 provided on the seat cushion side is also formed by pressing a disk-shaped plate material. The outer diameter of the base plate 25 is the inner diameter of the large-diameter portion 21c of the ratchet 21 (the teeth of the inner teeth 23). It is set slightly smaller than the diameter of the tip circle. A through hole 25 a is formed at the center of the base plate 25.

  On the surface of the base plate 25 facing the ratchet 21, three guide grooves 25b extending radially from the center of the hole 25a are formed at equal pitch intervals in the circumferential direction. A pawl 27 is engaged with each guide groove 25b so as to be movable in the radial direction. Outer teeth 27 a that can mesh with the inner teeth 23 are formed on the surface of the pawl 27 that faces the large-diameter portion 21 c of the circular recess 21 a of the ratchet 21.

  In addition, arc-shaped guide protrusions 26 are formed between the guide grooves 25b along a concentric circle centered on the center of the hole 25a. The outer peripheral surface of the guide projection 26 receives the inner peripheral surface of the small diameter portion 21b (the first guide 21e and the second guide 21f) of the circular recess 21a of the ratchet 21, and the ratchet rotation support portion 26a that rotatably supports the ratchet 21. It has become. Therefore, the base plate 25 and the ratchet 21 can be rotated relative to each other. The relative rotation axis (indicated by a line segment O in FIG. 1) passes through the center of the hole 21d of the ratchet 21 and the center of the hole 25a of the base plate 25.

  On the back surface of each pole 27 (surface opposite to the surface on which the external teeth 27a are formed), a recess 27c having an inclined surface 27b that intersects the moving direction of the pole 27 is formed. A second cam 29 having a surface 29a that can contact the inclined surface 27b is disposed in the recess 27c. When the second cam 29 is pushed in the outer circumferential direction of the base plate 25, the inclined surface 27b generates a force in a direction in which the outer teeth 27a mesh with the inner teeth 23 and a force that presses the pole 27 against the side surface of the guide groove 25b. It is set to the correct side.

  A first cam (cam) 31 is disposed between the ratchet 21 and the base plate 25 on the axis of relative rotation. Three guide protrusion sliding contact portions 31 a that can slide in contact with the inner peripheral surface of the guide protrusion 26 of the base plate 25 are formed on the outer peripheral portion of the first cam 31 at equal pitch intervals in the circumferential direction. Therefore, the inner peripheral surface of the guide protrusion 26 is a first cam rotation support portion 26b that receives the guide protrusion sliding contact portion 31a of the first cam 31 and supports the first cam 31 rotatably. In the present embodiment, the first cam rotation support portion 26b of the guide protrusion 26 and the ratchet rotation support portion 26a wrap in the axial direction of relative rotation.

  Further, on the outer peripheral portion of the first cam 31, when the first cam 31 rotates in one direction, a pressing portion that pushes the second cam 29 and moves the pole 27 in a direction in which the outer teeth 27 a mesh with the inner teeth 23. 31b are formed at equal pitch intervals in the circumferential direction.

  Further, on the outer periphery of the first cam 31, a columnar protrusion 31c that engages with a cam groove 27d formed on a surface of the pole 27 facing the first cam 31 (bottom of the ratchet 21) is provided in the circumferential direction, etc. It is formed at pitch intervals. The cam groove 27d of the pole 27 is formed in such a shape that when the first cam 31 rotates in the other direction, the outer teeth 27a move the pole 27 in a direction away from the inner teeth 23.

  On the surface of the pole 27 that faces the first cam 31, a protrusion 27 e that can contact the small diameter portion 21 b (the first guide 21 e and the second guide 21 f) of the circular recess 21 a of the ratchet 21 is formed.

  When the pole 27 is positioned at a position where the protrusion 27e can contact the first guide 21e of the small diameter portion 21b, when the first cam 31 rotates in one direction, the second cam 29 is pushed, and the pole 27 The outer teeth 27a and the inner teeth 23 of the ratchet 21 can mesh with each other.

  However, when the pole 27 is located at a position where the protrusion 27e can contact the second guide 21f of the small diameter portion 21b, if the first cam 31 rotates in one direction, the external teeth 27a of the pole 27 and the ratchet Before the inner teeth 23 of 21 are engaged with each other, the protrusion 27e of the pole 27 comes into contact with the second guide 21f of the small diameter portion 21b, and further movement of the pole 27 is prohibited.

  At the center of the first cam 31, a hole 31d having a substantially oval cross-sectional shape is formed. A cylindrical shaft 33 having a substantially oval cross-sectional shape is fitted in the hole 31d. The shaft 33 and the first cam 31 are integrally rotatable by fitting with a substantially oval (non-circular) cross-sectional shape. One end side of the shaft 33 is inserted through the hole 25a of the base plate 25 and protrudes to the outside.

  The inner end of the spiral spring 35 disposed outside the base plate 25 engages with the shaft 33, the outer end engages with the base plate 25, and the first cam 31 is moved in one direction (the outer teeth 27a of the pole 27 are The direction of engagement with the inner teeth 23 of the ratchet 21 is biased.

  Therefore, the second guide 21f of the small diameter portion 21b of the circular recess 21a of the ratchet 21 and the protrusion 27e of the pole 27 form an unlock release holding mechanism that holds the pole 27 in the unlocked position.

  The outer peripheral portion of the ratchet 21 and the outer peripheral portion of the base plate 25 are sandwiched by a ring-shaped outer peripheral ring 37, and the ratchet 21 and the base plate 25 are separated in the direction of the axis of relative rotation (O in FIG. 1). Without being relatively rotatable.

Here, the operation of the reclining device having the above-described configuration will be described with reference to FIGS. FIG. 5 is a diagram for explaining the operation of the reclining device shown in FIG.
<When the pole 27 is located at a position where the protrusion 27e can contact the first guide 21e of the small diameter portion 21b of the ratchet 21>
Usually, the pole 27 provided on the base plate 25 is in a locked position where the outer teeth 27a mesh with the inner teeth 23 of the ratchet 21 by the urging force of the spiral spring 35, and the ratchet (first member) 21 and the base plate (second Relative rotation with the member 25 is prohibited, and the seat back is in a state where it cannot rotate relative to the seat cushion (locked state).

  When the first cam 31 is operated against the urging force of the spiral spring 35 and rotated in the other direction, the pawl 27 is unscrewed when the outer teeth 27a are disengaged from the inner teeth 23 of the ratchet 21. It moves to the lock position (see FIG. 5), the ratchet (first member) 21 and the base plate (second member) 25 can be rotated relative to each other, and the seat back can rotate with respect to the seat cushion.

When the operating force on the first cam 31 is released, the external force 27a of the pole 27 meshes with the internal tooth 23 of the ratchet 21 by the biasing force of the spiral spring 35, and the ratchet (first member) 21 and the base plate (first Relative rotation with the (two members) 25 is prohibited, and the locked state is established again.
<When the pole 27 is located at a position where the protrusion 27e can contact the second guide 21f of the 7 small diameter portion 21b of the ratchet 21>
Due to the urging force of the spiral spring 35, the protrusion 27e of the pole 27 provided on the base plate 25 comes into contact with the second guide 21f of the 7 small diameter portion 21b of the ratchet 21, and the pole 27 is held in the unlocked position.

  Therefore, the seat back can be rotated with respect to the seat cushion without rotating the first cam 31 in the other direction. At this time, the protrusion 27 d of the pole 27 slides on the second guide 21 f of the seven small diameter portions 21 b of the ratchet 21. Then, when the protrusion 27d of the pole 27 moves to a position where it can contact the first guide 21e of the 7 small diameter portion 21b of the ratchet 21, the external teeth 27a of the pole 27 are ratchet by the urging force of the spiral spring 35. 21 is engaged with the internal teeth 23, and the relative rotation between the ratchet (first member) 21 and the base plate (second member) 25 is prohibited, and the locked state is established again.

  According to such a configuration, the following effects can be obtained.

 (1) Since the distance between the first cam rotation support portion 26b of the guide protrusion 26 and the relative rotation axis O is the distance between the outer peripheral surface of the first cam (cam) 31 and the relative rotation axis O, the ratchet Accurate axial alignment between the (first member) 21 and the base plate (second member) 25 is possible.

  Further, the distance between the ratchet (first member) rotation support portion 26 a of the guide protrusion 26 and the relative rotation axis O is the distance between the inner peripheral surface of the small diameter portion 21 b of the ratchet 21 and the relative rotation axis O. Thus, accurate axis alignment between the base plate 25 and the first cam 31 is completed.

 (2) Since the first cam rotation support portion 26b and the ratchet rotation support portion 26a of the guide protrusion 26 wrap in the direction of the relative rotation axis O, the protrusion amount of the guide protrusion 26 can be shortened, and the base plate 25 Can be manufactured with a press, reducing costs.

  Further, the thickness of the reclining device in the direction of the relative rotation axis O can be reduced.

 (3) The base plate 25 is located inside the ratchet 21, and the ratchet rotation support portion 26 a of the guide protrusion 26 receives the inner peripheral surface of the small diameter portion 21 b of the ratchet 21, thereby centering the relative rotation axis O of the reclining device. The length in the radial direction can be shortened. Further, the thickness of the reclining device in the direction of the relative rotation axis O can be reduced.

 (4) There are a plurality of poles 27, and the guide protrusion 26 has an arc shape along a concentric circle with the axis O of relative rotation as the center, and is disposed between the plurality of poles 27. Since the distance from the axis O of relative rotation can be set long, accurate axis alignment of the ratchet 21 and the base plate 25 and the base plate 25 and the first cam 31 can be performed.

 (5) The ratchet rotation support portion 26a of the guide projection 26 receives the first guide 21e of the lock release holding mechanism, thereby reducing the thickness of the relative rotation axis O direction of the ratchet 21, and the relative rotation axis of the reclining device. The thickness in the O direction can be reduced.

21 Ratchet (first member)
25 Base plate (second member)
26 Guide projection 26a Ratchet (first member) rotation support portion 26b First cam rotation support portion 27 Pole 31 First cam

Claims (5)

A first member in which one end is an open surface and the inner teeth are formed along the circumferential direction of the inner peripheral surface;
A pole having external teeth that can mesh with the internal teeth;
It is laminated on the open surface side of the first member, is provided so as to be rotatable relative to the first member in the circumferential direction, and a lock position where the external teeth mesh with the internal teeth, and the external teeth from the internal teeth A second member formed with guide means for guiding each of the poles between the disengaged unlock positions;
Between the first member and the second member, it is rotatably provided on the axis of relative rotation, and when rotated in one direction, the pole moves in a direction in which the external teeth mesh with the internal teeth. With cam,
Have
In the reclining device in which relative rotation between the first member and the second member is prohibited by engaging the outer teeth of the pole with the inner teeth of the first member,
A guide protrusion is provided on a surface of the second member facing the bottom of the first member;
On the shaft side of the relative rotation of the guide protrusion, there is a cam rotation support portion that receives the outer peripheral surface of the cam and supports the cam rotatably.
A first member rotation support portion that receives the circumferential surface of the first member and rotatably supports the first member is formed on the opposite side of the guide protrusion from the axis of relative rotation .
A reclining mechanism comprising a plurality of the guide protrusions .   The reclining device according to claim 1, wherein the cam rotation support portion of the guide protrusion and the first member rotation support portion are wrapped in the axial direction of the relative rotation. The second member is located inside the first member;
The reclining device according to claim 1, wherein the first member rotation support portion of the guide protrusion receives an inner peripheral surface of the first member. There are multiple poles,
The guide protrusion is
The reclining device according to any one of claims 1 to 3, wherein the reclining device is arranged between the plurality of poles in an arc shape along a concentric circle centered on the axis of relative rotation. The first member is formed on the inner peripheral surface on the bottom surface side from the inner teeth, and is provided on the pole, a first guide along the circumferential direction, a second guide having a smaller diameter than the first guide, and the pole. 1 guide, having a lock release holding mechanism comprising a projection that holds the pawl in the unlocked position when it can contact the second guide and contact the second guide;
The reclining device according to claim 1, wherein the first member rotation support portion of the guide protrusion receives the first guide.

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