JP3974355B2 - Reclining device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes a base arm, a ratchet provided so as to be tiltable with respect to the base arm, and an inner tooth centered on the tilt center formed on a surface facing the base arm, the base arm and the ratchet And a pole formed with outer teeth that can mesh with the inner teeth of the ratchet on the front end side, and the base arm is provided so as to sandwich both sides of the pole. A first guide means for guiding in a direction orthogonal to the tilting central axis; and a second guide means provided between the pole and the base arm for guiding the pole in a direction orthogonal to the tilting central axis. A guide means is provided between the base arm and the ratchet, and pushes one place on the rear end side of the pole toward the external teeth of the pole so that the external teeth of the pole become the internal teeth of the ratchet. It relates reclining device having a cam engaged.
[0002]
[Prior art]
A configuration of a conventional reclining device will be described with reference to FIGS. 13 and 14.
In these drawings, a hinge pin 5 is fixed to a lower arm (base arm) 1 on the seat cushion side, and an operation handle 2 is rotatably attached thereto. The ratchet 7 on the seat back side is formed with a hole 9 through which the hinge pin 5 is inserted. The hole 9 can be tilted with respect to the lower arm 1, and an internal tooth 11 centered on the hole 9 (center of tilting) is formed. Yes.
[0003]
Between the lower arm 1 and the ratchet 7, there is provided a pole 15 in which outer teeth 13 that can mesh with the inner teeth 11 of the ratchet 7 are formed. A cam 17 that presses one place (X in FIG. 13) of the pole 15 to engage the outer teeth 13 of the pole 15 with the inner teeth 11 of the ratchet 7 is rotatably attached to the hinge pin 5.
[0004]
The hinge pin 5 is rotatably provided with a connecting pipe 23 that transmits the movement of the cam 17 to a reclining mechanism provided on the other side of the seat.
[0005]
Also, the lower arm 1 is provided with a guide projection 20 (first guide means) that is provided so as to sandwich the pole 15 and guides the pole 15 in a direction orthogonal to the hinge pin (tilting center axis) 5.
[0006]
A pin 21 is attached to the cam 17, and one end portion side of the pin 21 is connected to the operation handle 2 through an arc-shaped long hole 25 formed in the ratchet 7. One end of the spring 19 is hooked to the lower arm 1, and the other end is hooked to the operation handle 2. Due to the urging force of the spring 19, the pole 15 passes through the operation handle 2 and the cam 17 and the external teeth 13. Is biased in the direction of meshing with the internal teeth 11 of the ratchet 7.
[0007]
The other end side of the pin 21 attached to the cam 17 is attached to an arm 29 fixed to the connecting pipe 23 through an arc-shaped long hole 27 formed in the lower arm 1. A back frame 31 that is a seat back frame is fixed to the ratchet 7.
[0008]
Further, a convex portion 15 a that protrudes in the direction of the lower arm 1 is formed on the surface of the pole 15 that faces the lower arm 1, and this convex portion 15 a is formed on the lower arm 1, and the pole 15 is orthogonal to the hinge pin (tilting center axis) 5. Is engaged with a groove 1a (second guide means) for guiding in the direction of movement.
[0009]
The operation of the reclining device will be described. Normally, the urging force of the spring 19 causes the cam 17 to push the back surface of the pole 15, the outer teeth 13 of the pole 15 mesh with the inner teeth 11 of the ratchet 7, and the rotation of the ratchet (seat back) 7 is prohibited. (Locked state).
[0010]
When the operation handle 2 is operated upward against the urging force of the spring 19, the cam 17 rotates via the pin 21. Then, the pressing of the cam 17 on the back surface of the pole 15 is released, and the pole 15 is guided to the guide projection 20 (first guide means) and the groove 1a (second guide means) of the lower arm 1, and the pole 15 The outer teeth 13 and the inner teeth 11 of the ratchet 7 are disengaged, and the ratchet (seat back) 7 can tilt (unlocked).
[0011]
The movement of the cam 17 is transmitted to the cam (corresponding to the cam 17) of the reclining mechanism provided on the other side portion of the seat via the pin 21, the arm 29, and the connecting pipe 23.
[0012]
When the operating force for operating the operating handle 2 upward is released, the operating handle 2 is rotated downward by the biasing force of the spring 19, the cam 17 is also rotated downward via the pin 21, and the cam 17 is 15, the pawl 15 is guided by the guide projection 20 and the groove 1 a of the lower arm 1, and the external teeth 13 of the pawl 15 mesh with the internal teeth 11 of the ratchet 7 again to return to the locked state.
[0013]
[Problems to be solved by the invention]
However, in the reclining device having the above configuration, the gap between both sides of the pole 15 and the guide projection 20 as the first guide means, and the gap between the convex portion 15a of the pole 15 and the groove 1a as the second guide means are generally The gap is minimized so as not to be loose, and the gaps are substantially the same.
[0014]
When a rotational load in the direction of the arrow Y acts on the ratchet 7, the pole 15 abuts the guide protrusion 20 as the first guide means and the groove 1a as the second guide means almost simultaneously, and the guide protrusion as the first guide means. 20 and the load acting on the groove 1a serving as the second guide means are dispersed, and the guide projection 20 serving as the first guide means and the groove 1a serving as the second guide means are hardly deformed.
[0015]
Therefore, since the pole 15 itself hardly tilts, the rotational load is transmitted to the cam 17 through one place on the back surface of the pole 15 (X in FIG. 14).
On the other hand, when the cam 17 is bent, the meshing between the external teeth 13 of the pole 15 and the internal teeth 11 of the latch 7 becomes shallow, and the lock strength becomes weak.
In the case of the above configuration, since the rotational load is concentrated on one portion of the cam 17, the strength of the cam 17 must be set large in order to prevent the cam 17 from withstanding the load and bending. There is a problem that becomes high.
[0016]
This invention is made | formed in view of the said problem, The subject is providing the reclining apparatus which can reduce cost.
[0017]
[Means for Solving the Problems]
The present invention that solves the above-described problems is provided with a base arm, a ratchet that is provided so as to be tiltable with respect to the base arm, and has an inner tooth centered on the tilting center on a surface facing the base arm, A pole provided between the base arm and the ratchet, with a front end formed with external teeth capable of meshing with the internal teeth of the ratchet, and provided with the base arm sandwiching both sides of the pole A first guide means for guiding the pole in a direction orthogonal to the central axis of the tilt, and provided between the pole and the base arm, the pole in a direction orthogonal to the central axis of the tilt. Second guiding means for guiding, provided between the base arm and the ratchet, and pushing one place on the rear end side of the pole in the direction of the external teeth of the pole, thereby pushing the external teeth of the pole A reclining device having a cam that meshes with the inner teeth of the chet, wherein a gap between the guide surface of the second guide means and the pole is larger than a gap between the guide surface of the first guide means and the pole. When the pole is tilted, the pole abuts on the guide surface of the second guide means, the pawl and the cam abut at a plurality of locations, and part of the external teeth of the pole A reclining device characterized in that it is configured to engage deeply with the inner teeth of a ratchet.
[0018]
The gap between the guide surface of the second guide means and the pole is set larger than the gap between the guide surface of the first guide means and the pole, and when the pole is tilted, the pole and the cam Since a part of the external teeth of the pole is in deep engagement with the internal teeth of the ratchet, the pole first hits the first guide means when a large load is applied to the ratchet. The load is applied to the first guide means. Therefore, the first guide means is deformed by the load, and the pole is inclined.
[0019]
When the pole is tilted, the pole comes into contact with the second guide means. As a result, the pole is supported by the first guide means and the second guide means, and further tilting of the pole is prohibited.
[0020]
And since the said pole and the said cam contact | abutted in the some location, a load is transmitted to a cam via a some location from a pole.
Further, when the pole is tilted, a part of the external teeth of the pole is configured to engage deeply with the internal teeth of the ratchet. A greater meshing force is generated, and the overall mesh strength does not decrease.
[0021]
Therefore, unlike the conventional example, the load is not concentrated on one portion of the cam, so that the strength of the cam can be made lower than that of the conventional example, and the cost can be reduced.
According to a second aspect of the present invention, when the pawl and the cam abut at a plurality of locations, the direction of the force transmitted from the pawl to the cam is directed to the rotation center of the cam. The reclining device according to claim 1, wherein the ratchet is configured.
[0022]
By configuring the pawl and the ratchet so that the direction of the force transmitted from the pawl to the cam is directed to the rotation center of the cam when the pawl and the cam abut at a plurality of locations, The cam can be prevented from rotating by being pushed by the pole.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
The overall configuration of the reclining device according to the embodiment of the present invention will be described with reference to FIGS.
[0024]
In the reclining device of this embodiment, the base arm 100 is attached as a lower arm to the frame 201 on the seat cushion side, and the ratchet 130 is attached to the back frame 202 on the seat back side (see FIGS. 6 to 8).
[0025]
In particular, as shown in FIGS. 6 to 9 and 12, the base arm 100 is formed with a fitting hole 101 in the central portion for rotatably supporting the cylindrical portion 121 of the rotating shaft 120. Around the hole 101, two identical cross-section arcuate support portions 102 and 103 protruding toward the ratchet 130 are formed so as to face each other coaxially with the fitting hole 101.
[0026]
Supporting portions 102 and 103 having an arcuate cross section are rotatably fitted in the fitting hole 131 (see FIG. 10) in the center of the ratchet 130, so that the ratchet 130 can tilt with respect to the base arm 100. It has become. 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. As shown in FIG. 10, a substantially circular recess 132 centered on the tilting center of the ratchet 130 is formed on the surface of the ratchet 130 facing the base arm 100, and the inner teeth 133, 134 are formed on the inner peripheral surface of the recess. Is engraved.
[0027]
A recess 104 (see FIG. 9) is also formed on the surface of the base arm 100 facing the recess 132 of the ratchet 130, and the upper part of the bottom surface of the recess 104 is a first guide means toward the ratchet 130. Guide protrusions 105 and 106 are projected, and guide protrusions 107 and 108 that are first guide means project toward the ratchet 130 at the bottom of the bottom surface.
[0028]
As shown in FIGS. 4, 9 and 12, 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 perpendicular to the central axis of the tilting. The external teeth 141 of the portion are configured to be able to mesh with the internal teeth 133 of the ratchet 130. 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.
[0029]
As shown in FIGS. 4 and 6, substantially rectangular convex portions 140a and 150a projecting toward the base arm 100 are formed on the surfaces of the poles 140 and 150 facing the base arm 100, and the convex portions 140a. , 150a are formed on the base arm 100 and engage with grooves 100a, 100b (second guide means) for guiding the poles 140, 150 in a direction orthogonal to the central axis of tilting.
[0030]
Here, as shown in FIG. 1, the gap between the guide surfaces of the guide projections 107 and 108 as the first guide means and the pole 150 is w, and the guide surface of the groove 100b as the second guide means and the pole 150 When the gap with the convex portion 150b is W,
W> w
It set so that it might become.
[0031]
An oval hole of a release lever 160 as a release operation portion is fitted into the first oval portion 122 of the rotating shaft 120, and a cam 170 is inserted into the second oval portion 123 of the rotating shaft 120. The oval hole 171 is fitted. For this reason, the release lever 160 and the cam 170 are fitted to the rotation shaft 120 in a state in which relative rotation is impossible. 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.
[0032]
That is, the cam 170 rotates together with the rotating shaft 120, and the pressing portions 174 and 175 push the pressed portions 142 a and 152 a of the back surfaces 142 and 152 of the poles 140 and 150 in the direction of the external teeth 141 and 151. The external teeth 141 and 151 of 140 and 150 are engaged with the internal teeth 133 and 134 of the ratchet 130.
[0033]
In addition to the pressing portion 174 of the cam 170 and the pressed portion 142a of the back surface 142 of the pole 140, the cam 170 and the pole 140 have one side of the pressing portion 174 of the cam 170 when the pole 140 is tilted. The contact portion 142b of the pole 140 can be brought into contact with the contact portion 174a formed in the contact portion 174a, and the contact portion 142c of the pole 140 can be brought into contact with the contact portion 174b formed on the other side of the pressing portion 174 of the cam 170. ing.
[0034]
Similarly, the cam 170 and the pole 150 include one of the pressing portions 175 of the cam 170 when the pole 150 is tilted, in addition to the pressing portion 175 of the cam 170 and the pressed portion 152a of the back surface 152 of the pole 150. The contact portion 152b of the pole 150 can contact the contact portion 175a formed on the side, and the contact portion 152c of the pole 150 can contact the contact portion 175b formed on the other side of the pressing portion 175 of the cam 170. It has become.
[0035]
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.
[0036]
The release plate 180 is formed with elongated hole-shaped cam holes 183 and 184 that fit into the projections 143 and 153 in the plate thickness direction of the poles 140 and 150, and the shape of the cam holes 183 and 184 is the release hole 180. When the lever 160 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 ratcheted. It is formed so as to be detached from the 130 internal teeth 133 and 134.
[0037]
The spiral springs 191 and 195 as urging means have inner ends hooked to the hooks 111 and 112 of the base arm 100, outer ends hooked to the step portions 178 and 179 of the cam 170, and the cam 170 is connected to the poles 140 and The cam 170 is urged to rotate so as to push the back surface of 150.
[0038]
The third cross-sectional oval portion 124 of the pivot shaft 120 has a connecting pipe (not shown) for transmitting the rotation of the pivot shaft 120 to the pivot shaft of the reclining mechanism provided on the other seat side. Are connected.
[0039]
In this embodiment, serrations are cut in the arcuate fitting portion between the second cross-sectional oval portion 123 of the rotating shaft 120 and the oval hole 171 of the cam 170. Further, a retaining ring 207 is fitted to the rotating shaft 120 to prevent the rotating shaft 120 from coming off.
[0040]
The operation of the reclining device having the above configuration will be described. Normally, due to the biasing force of the spiral springs 191 and 195, the cam 170 pushes the back surfaces of the poles 140 and 150, the external teeth 141 and 151 of the poles 140 and 150 mesh with the internal teeth 133 and 134 of the ratchet 130, and the ratchet ( The rotation of the seat back 130 is prohibited (locked state).
[0041]
When the release lever 160 is lifted upward in FIG. 5, the rotating shaft 120, the cam 170, and the release plate 180 rotate in the clockwise direction in FIG. 4 against the urging force of the spiral springs 191 and 195.
[0042]
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).
[0043]
The movement of the rotation shaft 120 is transmitted to the rotation shaft of the reclining mechanism provided on the other seat side through the connecting pipe.
When the seat back is tilted to a desired angle and the operation force to the release lever 160 is released, the cam 170 pushes the back surface of the poles 140 and 150 by the biasing force of the spiral springs 191 and 195, and the external teeth of the poles 140 and 150 141 and 151 mesh with the inner teeth 133 and 134 of the ratchet 130 again, and the ratchet (seat back) 130 returns to a state in which the rotation is prohibited.
[0044]
In the present embodiment, as shown in FIG. 1, the gap between the guide protrusions 107 and 108 as the first guide means and the pole 150 is w, and the groove 100b as the second guide means and the convexity of the pole 150 are provided. When the gap with the portion 150b is W,
W> w
By setting as described above, the following effects can be obtained.
(1) As shown in FIG. 2, when a rotational load in the direction of arrow C acts on the ratchet 130, the pole 150 first comes into contact with the guide projection 107 as the first guide means, and the load is applied to the first guide projection 107. Act on. Therefore, the guide protrusion 107 is deformed by the load, and the pole 150 is inclined.
[0045]
When the pole 150 is tilted, the convex portion 150b of the pole 150 comes into contact with the groove 100b of the base arm 100 which is the second guide means, and as a result, the guide protrusion 107 which is the first guide means and the second guide means. Since the pole 150 is supported by a certain groove 100b, further tilting of the pole 150 is prohibited.
[0046]
When the pole 150 is tilted, the contact portion 152c of the pole 150 contacts the contact portion 175b formed on one side of the pressing portion 175 of the cam 170, and the load is applied from the pole 150 to two locations ( The pressure is transmitted to the cam 170 via the pressed portion 152a of the pole 150 → the pressing portion 175 of the cam 170, the contact portion 152c of the pole 150 → the contact portion 175b of the cam 170).
[0047]
Therefore, unlike the conventional example, the load is not concentrated on one portion of the cam, so that the strength of the cam can be made lower than that of the conventional example, and the cost can be reduced.
Further, when the pole 150 is tilted, the engagement on the guide protrusion 107 side becomes shallower, but the engagement on the guide protrusion 108 side becomes deeper, among the engagement positions of the outer teeth 151 of the pole 150 and the inner teeth 134 of the ratchet 130.
[0048]
And in the location where meshing becomes deep, the wedge effect of an internal tooth and an external tooth generate | occur | produces a meshing force larger than usual, and meshing strength does not fall as a whole.
The direction of the force F1 transmitted from the pressed portion 152a of the pole 150 to the pressing portion 175 of the cam 170 and the direction of the force F2 transmitted from the contact portion 152c of the pole 150 to the contact portion 175b of the cam 170 are as follows. Since both face the rotation shaft 120 (the center of the cam 170), the cam 170 does not rotate.
[0049]
As shown in FIG. 3, when a rotational load in the direction of the arrow CC acts on the ratchet 130, the pole 150 first comes into contact with the guide protrusion 108 which is the first guide means, and the load is applied to the first guide protrusion 108. Works. Therefore, the guide protrusion 108 is deformed by the load, and the pole 150 is inclined.
[0050]
When the pole 150 is tilted, the convex portion 150b of the pole 150 comes into contact with the groove 100b of the base arm 100 which is the second guide means, and as a result, the guide protrusion 108 which is the first guide means and the second guide means. Since the pole 150 is supported by a certain groove 100b, further tilting of the pole 150 is prohibited.
[0051]
When the pole 150 is tilted, the abutting portion 152b of the pole 150 abuts on the abutting portion 175a formed on one side of the pressing portion 175 of the cam 170. It is transmitted to the cam 170 via the pressed portion 152a of the pole 150 → the pressing portion 175 of the cam 170, the contact portion 152b of the pole 150 → the contact portion 175a of the cam 170).
[0052]
Therefore, unlike the conventional example, the load is not concentrated on one portion of the cam, so that the strength of the cam can be made lower than that of the conventional example, and the cost can be reduced.
Further, when the pole 150 is tilted, the engagement on the guide protrusion 108 side becomes shallower, but the engagement on the guide protrusion 107 side becomes deeper, among the engagement positions of the outer teeth 151 of the pole 150 and the inner teeth 134 of the ratchet 130.
[0053]
And in the location where meshing becomes deep, the wedge effect of an internal tooth and an external tooth generate | occur | produces a meshing force larger than usual, and meshing strength does not fall as a whole.
Further, the direction of the force F1 transmitted from the pressed portion 152a of the pole 150 to the pressing portion 175 of the cam 170 and the direction of the force F2 'transmitted to the contacting portion 152b of the pole 150 → the contact portion 175a of the cam 170. Since both face the rotation shaft 120 (the center of the cam 170), the cam 170 does not rotate.
[0054]
Although the above description has been made on the pole 150, the same can be said for the pole 140.
In addition, in this embodiment, the base arm 100 is provided with a fitting hole 101 for rotatably supporting the rotating shaft 120 and two cross-sectional arc-shaped support portions 102 and 103 protruding toward the ratchet 130 side, and the cam 170 is provided with an oblong hole 171 that fits into the rotation shaft 120 in a relatively non-rotatable state and arc-shaped elongated holes 172 and 173 into which the cross-section arc-shaped support portions 102 and 103 fit loosely. Since the fitting holes 131 are provided in the outer peripheral surfaces of the arcuate support portions 102 and 103 so as to be freely rotatable, the linkage mechanism of the base arm 100, the rotating shaft 120, the ratchet 130, and the cam 170 can be simplified, and Manufacturing costs can be reduced by simplification.
[0055]
The present invention is not limited to the above embodiment. For example, the ratchet 130 may be attached as a lower arm to the frame 201 on the seat cushion side, and the base arm 100 may be attached to the back frame 202 on the seat back side. The number of poles (140, 150) may be one or more, and the biasing of the cam 170 is not limited to the method using the spiral springs 191, 195.
[0056]
【The invention's effect】
As described above, according to the present invention, the gap between the guide surface of the second guide means and the pole is larger than the gap between the guide surface of the first guide means and the pole. When the pole is tilted, the pawl and the cam come into contact with each other at a plurality of locations, and a part of the outer teeth of the pole engages with the inner teeth of the ratchet. When a large load is applied, the pole first comes into contact with the first guide means, and the load acts on the first guide means. Therefore, the first guide means is deformed by the load, and the pole is inclined.
[0057]
When the pole is tilted, the pole comes into contact with the second guide means. As a result, the pole is supported by the first guide means and the second guide means, and further tilting of the pole is prohibited.
[0058]
And since the said pole and the said cam contact | abutted in the some location, a load is transmitted to a cam via a some location from a pole.
In addition, when the pole is tilted, a part of the external teeth of the pole is configured to engage deeply with the internal teeth of the ratchet. A greater meshing force is generated, and the overall mesh strength does not decrease.
[0059]
Therefore, unlike the conventional example, the load is not concentrated on one portion of the cam, so that the strength of the cam can be made lower than that of the conventional example, and the cost can be reduced. According to the invention of claim 2, when the pawl and the cam abut at a plurality of locations, the direction of the force transmitted from the pawl to the cam is directed to the rotation center of the cam. By configuring the pawl and the ratchet, it is possible to prevent the cam from rotating by being pushed by the pawl.
[Brief description of the drawings]
FIG. 1 is an enlarged view of an inventive part of an embodiment of the present invention.
FIG. 2 is a diagram for explaining operational effects of the embodiment.
FIG. 3 is a diagram for explaining operational effects of the embodiment.
4 is a front view in which a base arm is removed from FIG. 5 showing an embodiment of the present invention. FIG.
FIG. 5 is a front view showing an appearance of an embodiment of the present invention.
6 is a cross-sectional view taken along a cutting line CC in FIGS. 4 and 5. FIG.
7 is a cross-sectional view taken along a cutting line DD in FIGS. 4 and 5. FIG.
8 is a cross-sectional view taken along a cutting line EE in FIGS. 4 and 5. FIG.
FIG. 9 is a rear view of the base arm in the embodiment of the present invention.
FIG. 10 is a front view of a ratchet in an embodiment of the present invention.
FIG. 11 is a rear view of the cam in the embodiment of the present invention.
FIG. 12 is a schematic exploded perspective view of a main part in an embodiment of the present invention.
FIG. 13 is a partially cutaway front view of a conventional reclining device.
14 is an enlarged cross-sectional view taken along a cutting line BB in FIG.
[Explanation of symbols]
100 Base arm 100b Groove 130 Ratchet 134 Inner tooth 150 Pole 151 Outer tooth 150b Protrusion 170 Cam

Claims (2)

A base arm,
A ratchet provided so as to be tiltable with respect to the base arm, and an inner tooth centered on the tilting center is formed on the surface facing the base arm;
A pole provided between the base arm and the ratchet, on the front end side, formed with external teeth that can mesh with the internal teeth of the ratchet;
First guide means provided on the base arm so as to sandwich both sides of the pole, and guiding the pole in a direction perpendicular to the central axis of the tilt;
A second guide means provided between the pole and the base arm, for guiding the pole in a direction perpendicular to the central axis of the tilt;
A cam that is provided between the base arm and the ratchet, and presses one place on the rear end side of the pole in the direction of the external teeth of the pole to mesh the external teeth of the pole with the internal teeth of the ratchet;
In a reclining device having
A gap between the guide surface of the second guide means and the pole is set larger than a gap between the guide surface of the first guide means and the pole;
When the pole is tilted, the pole comes into contact with the guide surface of the second guide means, the pole and the cam come into contact at a plurality of locations, and part of the external teeth of the pole is inside the ratchet. A reclining device configured to be deeply engaged with teeth. The pawl and the ratchet are configured so that the direction of the force transmitted from the pawl to the cam is directed to the rotation center of the cam when the pawl and the cam abut at a plurality of locations. The reclining device according to claim 1.

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