JP2017104318A - Reclining chair - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a reclining chair in which the development angle of a back frame relative to a seat frame can be regulated within the use range when the back frame is used as a backrest and in which manufacturing operation is facilitated.SOLUTION: At least one joint 10 connecting a back frame with a seat frame is equipped with a first arm 11 and a second arm 21 that are attached to the seat frame and the back frame respectively. The second arm 21 is attached pivotally to the first arm 11. Further, the joint 10 is equipped with a regulation mechanism 30 in which the development angle θ of the back frame when the back frame is used as the backrest is regulated in the use range θfrom a first angle θto a second angle θ. Also, when the development angle θ is displaced to the use range θfrom a third angle θwhich is deviated from the use range θ, the development angle θ is structured to be regulated to the use range θby the regulation mechanism 30.SELECTED DRAWING: Figure 10B

Description

  The present invention relates to a reclining chair capable of adjusting a deployment angle of a backrest portion with respect to a seat portion.

  The reclining chair having a seat and a backrest is configured to be adjustable stepwise or steplessly so that the angle of deployment of the backrest relative to the seat can be adapted to the preference of the seated person. Is normal.

  Generally, the back frame of the backrest part is connected to the seat frame of the seat part via a pair of left and right joints. Then, in order to make it possible to adjust the deployment angle of the backrest stepwise or steplessly, at least one of the joint devices has a stepwise or stepless step angle of the back frame relative to the seat frame. An adjustable angle adjustment mechanism (eg, ratchet mechanism) is provided (see, for example, Patent Documents 1 to 7).

  Many of the conventional articulators are configured such that the deployment angle of the back frame can be adjusted within a range of about 80 ° to about 180 °.

Japanese Patent Laid-Open No. 9-19339 JP 2006-34709 A JP 2008-80049 A JP 2009-189391 A JP 2010-88682 A JP 2011-167354 A JP 2013-231487 A

  Thus, in the reclining chair, when the seated person uses the backrest as the backrest, the range of the deployment angle of the back frame with respect to the seat frame (this range is referred to as “use range”) is generally determined. It is in the range of 85 ° to about 150 °. Further, in order to reliably prevent the reclining chair from falling backward, it is desirable that the maximum angle of the deployment angle of the back frame is regulated. Therefore, the deployment angle of the back frame should basically be adjustable only within the usage range when the backrest is used as the backrest, and the deployment angle of the back frame is larger than the usage range. It is desirable to be regulated so that it does not become.

  On the other hand, in the manufacturing process of the reclining chair, cushioning members, surface covers, and the like attached to the seat frame and the back frame are generally attached in a state where both frames are connected via both articulators. If the deployment angle of the back frame is restricted to the above-described use range when performing this attachment operation, it is difficult to perform the attachment operation.

  The present invention has been made in view of the above-described technical background, and the purpose thereof is to regulate the deployment angle of the back frame with respect to the seat frame within the use range when the back frame is used as a backrest, It is another object of the present invention to provide a reclining chair that can be easily manufactured.

  The present invention provides the following means.

[1] The back frame of the backrest portion is connected to the seat frame of the seat portion via a pair of left and right joints, and the deployment angle of the back frame relative to the seat frame can be adjusted stepwise or steplessly. ,
The first articulator, which is at least one of the two articulators, is attached to one of the seat frame and the back frame in a fixed state and to the other in a fixed state. A second arm, and the second arm is pivotally attached to the first arm so as to be rotatable relative to the first arm.
Furthermore, the first articulator includes a regulating mechanism that regulates the deployment angle of the back frame when the back frame is used as a backrest within a use range from a first angle to a second angle, and When the deployment angle of the frame is displaced from the third angle out of the use range into the use range, the deployment mechanism restricts the deployment angle of the back frame to the use range. ,
The regulation mechanism is
Two first and second abutting portions that are integrally rotatable with the second arm and spaced apart from each other in the rotational direction of the two arms, and a position deviated from between the two abutting portions. A stopper member that is movable from a stop position to a stop position that is a position between the two abutting portions, and
The first abutting portion abuts against the stopper member when the deployed angle of the back frame is the first angle with the stopper member disposed at the stop position, and the back frame A reclining chair configured to restrict the deployment angle of the back frame to the use range by the second abutment portion striking the stopper member when the deployment angle is the second angle.

[2] The first articulator includes a restriction release mechanism that releases the restriction of the deployment angle of the back frame by the restriction mechanism,
The second arm has a rotating plate portion that can rotate integrally with the second arm, and is pivotally attached to the first arm at a substantially central portion of the rotating plate portion,
The pivot axis of the first arm and the second arm is substantially parallel to the thickness direction of the rotating plate portion of the second arm,
The stopper member is arranged to be movable from the non-stop position to the stop position in a direction substantially parallel to the pivot axis, and is moved in a direction to move from the non-stop position to the stop position by a biasing member. Energized,
The two abutting portions are formed on the rotating plate portion of the second arm so as to be separated from each other in the rotation direction of the rotating plate portion,
The restriction release mechanism restricts the deployment angle of the back frame by the restriction mechanism by the stopper member being moved from the stop position to the non-stop position against the urging force of the urging member. Configured to release,
The regulation mechanism is
When the stopper member is disposed at the non-stop position, the deployment angle of the back frame is displaced from the use range to the third angle side, and the tip of the stopper member is moved to the second arm. The stopper member is held at the non-stop position against the urging force of the urging member by striking against the side surface of the rotating plate part,
When the deployment angle of the back frame is displaced from the third angle within the use range, the abutment of the tip of the stopper member against the side surface of the rotating plate is released, and the stopper member The reclining chair according to claim 1, wherein the recliner is configured to move from the non-stop position to the stop position by a biasing force of the biasing member.

[3] The restriction release mechanism includes:
A release operation pin disposed in a state in which a distal end portion protrudes outward of the first articulator with respect to the seat portion, and the distal end portion of the release operation pin extends along an axial direction of the release operation pin. And the stopper member is moved from the stop position to the non-stop position against the urging force of the urging member by being pushed and moved toward the first articulator. Recliner chair listed.

[4] The release operation pin is disposed at a position that is substantially parallel to the pivot axis of the first arm and the second arm and that does not collide with both the abutting portions of the second arm,
4. The reclining chair according to claim 3, wherein a base end portion of the release operation pin and the stopper member are connected so that the release operation pin and the stopper member can be moved together.

[5] The first arm includes a pair of left and right side plates that are spaced apart from each other and arranged substantially in parallel.
The two abutting portions of the second arm are disposed between the side plate portions of the first arm;
Each of the side plate portions is provided with a holding hole for inserting and holding the stopper member so as to be slidable in the direction of moving from the non-stop position to the stop position.
The regulation mechanism is
Any of the preceding items 1 to 4, wherein the stopper member is configured to be inserted and held in the both holding holes across the holding holes when the stopper member is disposed at the stop position. Recliner chair listed.

[6] Only one of the joints is the first joint,
Of the two articulators, only the other articulator is provided with an angle adjustment mechanism capable of adjusting the deployment angle of the back frame stepwise or steplessly at least within the use range. A reclining chair according to any of the above.

  The present invention has the following effects.

  In the previous item [1], the first articulator is provided with a regulating mechanism that regulates the deployment angle of the back frame when the back frame is used as a backrest within a use range from the first angle to the second angle. The deployment angle of the back frame can be restricted to the use range by the restriction mechanism.

  Further, the first articulator is configured such that when the deployment angle of the back frame is displaced from the third angle outside the use range into the use range, the deployment angle of the back frame is regulated within the use range by the restriction mechanism. ing. Therefore, in the process of manufacturing the chair, when the deployment angle of the back frame is the third angle, a predetermined operation (for example, an operation of attaching a cushion member or the like) can be performed on the seat frame and the back frame. Thereby, the manufacturing operation of the chair can be easily performed.

  Further, in the restricting mechanism, the first and second abutting portions abut against the stopper member when the deployed angle of the back frame is the first and second angles with the stopper member disposed at the stop position, respectively. Thereby, it is comprised so that the expansion | deployment angle of a back frame may be controlled to a use range. Thereby, the expansion | deployment angle of a back frame can be reliably controlled to a use range.

  In the preceding item [2], when the deployment angle of the back frame is displaced from the third angle within the use range, the restricting mechanism releases the contact of the front end portion of the stopper member with the side surface of the rotating plate portion. Is configured to move from the non-stop position to the stop position by the urging force of the urging member, thereby making it possible to easily perform a restricting operation for restricting the deployment angle of the back frame to the use range.

  In the preceding item [3], the restriction release mechanism is configured such that the stopper member is moved from the stop position against the urging force of the urging member when the tip of the release operation pin is pushed and moved along the axial direction of the release operation pin. It is configured to be moved to a non-stop position. Therefore, the restriction release operation for releasing the restriction on the deployment angle of the back frame can be performed by a push operation of pushing the tip of the release operation pin, and thus the restriction release operation can be easily performed.

  In the preceding item [4], the restriction release operation can be performed easily and reliably, and the restriction release mechanism can be simplified.

  In the previous item [5], the restricting mechanism is configured such that the stopper member straddles both holding holes and is held by both holding holes when the stopper member is disposed at the stop position. Accordingly, the impact force applied to the stopper member when the first and second abutting portions abut against the stopper member can be stably received by the two holding holes. Thereby, the expansion | deployment angle of a back frame can be reliably controlled to a 1st and 2nd angle, respectively.

  In the previous item [6], only one of the two articulators is the first articulator, and only the other of the two articulators is provided with the angle adjusting mechanism. Thereby, size reduction can be achieved for both of the articulators.

FIG. 1 is a perspective view of a reclining chair according to an embodiment of the present invention as seen from the diagonally upper left side. FIG. 2 is a left side view of the chair for explaining the operation of the back frame of the chair. FIG. 3 is a perspective view of the chair separated into a leg portion and a seat portion. FIG. 4 is a perspective view of the left joint device (first joint device) of the chair when viewed from the diagonally upper left side when the deployment angle of the back frame is the third angle. FIG. 5 is a perspective view of the left articulator when the back frame is deployed at the third angle, as viewed from the diagonally upper right side. FIG. 6 is a right side view of the left articulator when the deployed angle of the back frame is the third angle. FIG. 7 is a plan view of the left articulator when the deployed angle of the back frame is the third angle. FIG. 8 is an exploded perspective view of the left articulator. 9A is a cross-sectional view taken along line XX in FIG. 9B is a cross-sectional view taken along line YY in FIG. FIG. 10A is a cross-sectional view of the left articulator corresponding to line XX in FIG. 6 when the deployed angle of the back frame is the second angle. FIG. 10B is a cross-sectional view of the left articulator corresponding to line YY in FIG. 7 when the deployment angle of the second arm is the second angle. FIG. 11 is a cross-sectional view of the left articulator corresponding to line YY in FIG. 7 when the deployment angle of the second arm is the first angle. FIG. 12: is the perspective view which looked at the right joint apparatus of the chair from diagonally upper right back. FIG. 13 is an exploded perspective view of the right articulator. FIG. 14 is a cross-sectional view of the right articulator when the deployed angle of the back frame is the third angle and the rotation of the back frame is locked. FIG. 15 is a cross-sectional view of the right articulator when the deployment angle of the back frame is the third angle and the rotation lock of the back frame is released. FIG. 16 is a perspective view of a modification of the left articulator (first articulator) as viewed from the upper left obliquely upper side. FIG. 17: is the perspective view which looked at the left joint device from diagonally upper right front. FIG. 18 is an exploded perspective view of the left articulator.

  Next, an embodiment of the present invention will be described below with reference to the drawings.

  1-3, the code | symbol "1" is the reclining chair which concerns on one Embodiment of this invention. In addition, arrows “F”, “B”, “L”, and “R” indicate the front side, the rear side, the left side, and the right side of the chair 1, respectively.

  As shown in FIG. 1, the chair 1 includes a seat portion 2A, a backrest portion 3A, and leg portions 4A. The leg portion 4A supports the seat portion 2A in a substantially horizontal position at a predetermined height with respect to the floor surface from the lower side, and has a metal leg frame 4. The seat portion 2A is detachably connected to the leg portion 4A by a connecting means such as a connecting bolt 7 in a state of being disposed on the upper side of the leg portion 4A (leg frame 4) (see FIG. 3). Such a connecting operation of the seat 2A and the leg 4A is performed mainly at a store where the chair 1 is displayed and sold, or by a purchaser who has purchased the chair 1 at a site where the chair 1 is installed. Therefore, it can be said that the chair 1 of this embodiment is what is called a knockdown type.

  The seat portion 2A includes a seat frame 2 formed of a metal pipe. The seat frame 2 includes a pair of left and right side frame portions 2a and 2a that are arranged in parallel and spaced apart from each other, a front frame portion 2b that connects the front ends of both side frame portions 2a and 2a, and both side frame portions 2a and 2a. And a rear frame portion 2c connecting the rear ends of the two. The substantially middle portions in the front-rear direction of both side frame portions 2a, 2a are connected by two narrow strip-like connecting plate portions 2d, 2d.

  The backrest 3A includes a back frame 3 formed of a metal pipe. The back frame 3 has a pair of left and right side frame portions 3a and 3a that are spaced apart from each other and arranged in parallel, and an upper frame portion 3b that connects the upper ends of both side frame portions 3a and 3a. Further, a cylindrical metal connection socket 3c is fixed to the lower end portion of each side frame portion 3a in an externally fitted state. The substantially middle portions in the vertical direction of both side frame portions 3a and 3a are connected by a connecting frame portion 3d.

  And both the lower end parts of the left and right side frame parts 3a and 3a as the left and right lower end parts of the back frame 3 are connected to the left and right side frame parts 2a and 2a as both left and right end parts of the seat frame 2 as a pair of left and right joints. It is rotatably connected via the vessels 10 and 40. That is, in detail, a connecting socket 3c as a lower end portion of the left frame portion 3a of the back frame is connected to the rear end portion of the left frame portion 2a of the seat frame 2 via the left joint device 10, and the seat frame 2 A connecting socket 3c serving as a lower end portion of the right frame portion 3a of the back frame 3 is connected to the rear end portion of the right frame portion 2a via the right articulator 40. Both articulators 10 and 40 are each made of metal.

  As shown in FIGS. 1 and 3, the cushion member 5 (indicated by a two-dot chain line) is connected to the seat frame 2 and the back frame 3 in a state where both frames 2 and 3 are connected via both articulators 10 and 40. The frames 2 and 3 and the articulators 10 and 40 are attached so as to cover substantially the whole. The cushion member 5 is made of urethane (eg, urethane foam) having elasticity. The entire surface of the cushion member 5 is covered with a flexible surface cover.

  The right articulator 40 of both the articulators 10 and 40 includes an angle adjustment mechanism 60 that can adjust the deployment angle of the back frame 3 relative to the seat frame 2 in a stepwise manner. The configuration of the right articulator 40 will be described later.

  The left joint device 10 as the first joint device among the two joint devices 10 and 40 is made of metal attached to the rear end portion of the left frame portion 2a of the seat frame 2 in a fixed state as shown in FIGS. The 1st arm 11 and the metal 2nd arm 21 attached to the connection socket 3c as a lower end part of the left side frame part 3a of the back frame 3 were fixed (refer FIG. 1).

  As shown in FIG. 8, the first arm 11 has a cylindrical attachment portion 12 attached to the rear end portion of the left frame portion 2 a of the seat frame 2, and a proximal end side (that is, a rear end side) of the attachment portion 12. A pair of left and right side plate portions 13, 13 formed integrally with the attachment portion 12 is provided. Both side plate portions 13 and 13 are spaced apart from each other and arranged in parallel. The lower ends of the side plate portions 13 and 13 are integrally connected by a bottom plate portion 14 (see FIG. 9B). The upper ends of the side plate portions 13 and 13 are integrally connected by the upper plate portion 18. Then, as shown in FIG. 1, a predetermined fixing means (with a mounting portion 12 of the first arm 11 of the left articulator 10 disposed on the upper surface of the rear end portion of the left frame portion 2a of the seat frame 2). (Example: welding, riveting), the first arm 11 is fixed to the rear end of the left frame 2a of the seat frame 2 so as not to move relative to the seat frame 2. .

  As shown in FIG. 8, the second arm 21 is configured by integrally combining a pair of left and right second arm constituent pieces 21 </ b> A and 21 </ b> A. In a state before the combination of the two component pieces 21A and 21A, the combination surface of each component piece 21A has a plurality of fitting hole portions 21a that can be fitted to each other to prevent displacement between the two component pieces 21A and 21A. And the fitting convex part 21b is provided.

  Further, the second arm 21 includes a cylindrical attachment portion 22 attached to a connection socket 3 c as a lower end portion of the left frame portion 3 a of the back frame 3, and a rotating plate portion 23. As shown in FIG. 1, the connecting socket 3c of the left frame 3a of the back frame 3 is externally fitted to the mounting portion 22, and in this state, the mounting portion 22 is fixed to the connecting socket 3c by a predetermined fixing means (eg, riveting). The second arm 21 is fixed to the lower end portion of the side frame portion 3a of the back frame 3 so as to move (rotate) integrally with the back frame 3. .

  As shown in FIG. 8, the rotary plate portion 23 has a substantially disc shape, and is formed integrally with the attachment portion 22 on the proximal end side (that is, the lower end side) of the attachment portion 22. Thereby, the rotating plate part 23 can rotate integrally with the attachment part 22 (second arm 21).

A pivot hole 25 having a circular cross section is provided in the center of the rotating plate portion 23 so as to penetrate in the thickness direction of the rotating plate portion 23. The rotary plate portion 23 is disposed between the side plate portions 13 and 13 of the first arm 11, and the rotary shaft 19 having a circular cross section made of a rivet in this state is provided on one side plate portion 13. The pivot hole 15 having the shape, the pivot hole 25 of the rotary plate portion 23 and the pivot hole 15 having a circular cross section provided in the other side plate portion 13 are inserted into the first arm 11. The two arms 21 (more specifically, the rotating plate portion 23 of the second arm 21) are pivotally attached to the central portion of the rotating plate portion 23 via the rotating shaft 19. J ₁ (central axis i.e. rotation axis 19) a first arm 11 and Kururugijikusen the second arm 21 is parallel to the thickness direction of the rotary plate 23.

  Here, as shown in FIG. 2, the deployment angle of the second arm 21 with respect to the first arm 11 of the left joint device 10 is defined as θ. This deployment angle θ corresponds to the deployment angle of the back frame 3 with respect to the seat frame 2 of the chair 1. Therefore, hereinafter, the deployment angle θ of the second arm 21 with respect to the first arm 11 of the left joint device 10 will be described as the deployment angle θ of the back frame 3 with respect to the seat frame 2 of the chair 1.

In the chair 1 of the present embodiment, when the back frame 3 is used as the backrest of the chair 1, the back frame 3 (second arm 21 of the left joint device 10) is back to the seat frame 2 (first arm 11). unfolded angle theta of the frame 3 (the second arm 21) is disposed in a range from the first angle theta ₁ to the second angle theta _2. Further, for example, an angle of about 180 ° is defined as a “third angle θ ₃ ” as an angle at which the deployment angle θ of the back frame 3 (second arm 21) is out of the use range θ _1-2 .

  Further, for convenience of explanation, the rotation direction S in which the deployment angle θ of the back frame 3 (second arm 21) decreases is defined as the “forward rotation direction S” of the back frame 3 (second arm 21), and the back frame 3 ( The rotational direction G in which the deployment angle θ of the second arm 21) increases is defined as the “reverse rotational direction G” of the back frame 3 (second arm 21).

The left articulator 10 includes a regulating mechanism 30 that regulates the deployment angle θ of the back frame 3 to a use range θ _1-2 from the first angle θ ₁ to the second angle θ _2, and the deployment of the back frame 3 by the regulating mechanism 30. And a restriction release mechanism 31 for releasing the restriction of the angle θ. Here, in detail, the regulating mechanism 30 regulates the deployment angle θ of the back frame 3 with respect to the seat frame 2 by regulating the deployment angle of the second arm 21 with respect to the first arm 11 of the left joint device 10 within a predetermined range. The range of use is restricted to θ _1-2 .

The second angle θ ₂ is set larger than the first angle θ ₁ (that is, θ ₂ > θ ₁ ). θ ₁ and θ ₂ are each arbitrarily set. Specifically, θ ₁ is set to one angle within a range of about 70 ° to about 100 °, for example, and θ ₂ is set to about 130 ° to about 130 °, for example. One angle is set within a range of about 160 °, and θ _1-2 is set in a range from θ ₁ to θ ₂ .

However, in the present invention, θ ₁ and θ ₂ are not limited to the above-described angles and ranges, but the purpose of use of the chair 1, the installation location, and the leg 4A (leg frame 4) relative to the seat 2A (seat frame 2). ) And the rear lower end position, and the height of the backrest portion 3A (back frame 3) with respect to the seat portion 2A (seat frame 2), and the like. In addition, although it is particularly desirable that θ ₃ is about 180 °, the present invention does not necessarily require θ ₃ to be about 180 °.

  Next, the regulation mechanism 30 will be described below.

  As shown in FIGS. 8 and 9B, a recess 24c extending in the outer circumferential direction is cut out at a predetermined portion of the outer peripheral edge of the rotary plate 23 of the second arm 21 of the left joint device 10. Thus, the first abutting portion 24a and the second abutting portion 24b, which are formed of a pair of opposite side surfaces of the recess 24c, are arranged on the outer peripheral edge portion of the rotating plate portion 23 in the rotation direction of the rotating plate portion 23 (ie, The second arm 21 is formed so as to be able to rotate integrally with the rotating plate portion 23 in a state of being spaced apart from each other in the rotation direction of the second arm 21 and protruding radially outward of the rotating plate portion 23.

  The restriction mechanism 30 includes the first and second abutting portions 24a and 24b described above, and further includes a metal stopper pin 26 having a straight circular cross section as a stopper member.

Here, in the left articulator 10 shown in FIGS. 9A and 9B, the second arm 21 is arranged at a position where the deployed angle θ of the back frame 3 is the third angle θ ₃ (about 180 °). In Figure 10A and 10B, the second arm 21 is unfolded angle theta of the back frame 3 is disposed at a position of the second angle theta _2. In FIG. 11, the second arm 21 is disposed at a position where the deployment angle θ of the back frame 3 is the first angle θ ₁ .

As shown in FIG. 9A, the axis J ₂ of the stopper pin 26 is arranged in parallel with the pivot axis J ₁ between the first arm 11 and the second arm 21. Further, the stopper pin 26 includes a stop position (see FIGS. 10A, 10B and 11) formed inside the recess 24c, which is a position between the two abutting portions 24a and 24b of the rotating plate portion 23, and the both abutting portions 24a. , 24b (ie, the stop position), a non-stop position (see FIGS. 9A and 9B) which is a position deviated to one side in the thickness direction of the rotating plate portion 23 (specifically, the right side of the rotating plate portion 23). during the is movably arranged in a direction parallel to the Kururugijikusen J ₁ with.

As shown in FIGS. 10A, 10B, and 11, in a state where the deployed angle θ of the back frame 3 is within the use range θ _1-2 , the stopper pin 26 is a stop that is a position between the two abutting portions 24a and 24b. Placed in position. Furthermore, in this state, as shown in FIG. 10A, the stopper pin 26 straddles the holding holes 16, 16 having circular cross sections provided in the both side plates 13, 13 of the first arm 11. 26 is inserted and held in both holding holes 16 and 16 so as to be slidable in the direction Q of moving from the non-stop position to the stop position.

When the deployment angle θ of the back frame 3 becomes the second angle θ ₂ by the rotation of the back frame 3 in the reverse rotation direction G in the state where the stopper pin 26 is disposed at the stop position, the rotation is performed as shown in FIG. 10B. The second abutting portion 24 b of the plate portion 23 abuts against the stopper pin 26. Thereby, the rotation of the back frame 3 in the reverse rotation direction G is stopped, and the deployment angle θ of the back frame 3 is restricted to the second angle θ ₂ . On the other hand, when the deployment angle θ of the back frame 3 becomes the first angle θ ₁ due to the rotation of the back frame 3 in the normal rotation direction S, the first abutting portion 24a of the rotating plate portion 23 is as shown in FIG. Hit the stopper pin 26. As a result, the rotation of the back frame 3 in the forward rotation direction S is stopped, and the deployment angle θ of the back frame 3 is restricted to the first angle θ ₁ . Therefore, in a state in which the stopper pin 26 is disposed in the stop position, unfolded angle theta of the back frame 3 is restricted to a use range theta _1-2 from the first angle theta ₁ to the second angle theta _2.

As described above, the restricting mechanism 30 has the first abutting portion 24a as the stopper pin when the deployed angle θ of the back frame 3 is the first angle θ _{1 with} the stopper pin 26 being disposed at the stop position. When the impact angle θ of the back frame 3 strikes and the second angle θ ₂ is the second angle θ ₂ , the second impact portion 24 b strikes against the stopper pin 26, so that the deployment angle θ of the back frame 3 is within the use range θ _1-2. It is configured to regulate.

  Next, the restriction release mechanism 31 will be described below.

  The restriction release mechanism 31 releases the restriction of the deployment angle θ of the back frame 3 by the restriction mechanism 30 when the stopper pin 26 is moved from the stop position shown in FIG. 10A to the non-stop position shown in FIG. 9A. And a metal release operation pin 27 having a straight circular cross section. The release operation pin 27 is composed of a rivet with a head (see FIG. 8).

Unlocking pin 27, as shown in FIGS. 9A and 9B, both butting portions 24a of the first arm 11 and and parallel to the Kururugijikusen _{J 1} and the second arm 21 second arm 21, 24b and impinges At the position where the first arm 11 is not placed, the distal end portion 27a side (that is, the rivet head side) of the release operation pin 27 protrudes to the left side of the left side plate portion 13 of the first arm 11. In addition, the left side of the left side plate portion 13 of the first arm 11 corresponds to the outer side of the left joint device 10 with respect to the seat portion 2A (chair 1).

Furthermore, the release operation pin 27, along the axial line _{J 3} direction of unlocking pin 27 straddling a circular cross section of the two holding holes 17 and 17 respectively provided on both side plate portions 13, 13 of the first arm 11 The two holding holes 17 and 17 are inserted and held so as to be slidable.

  Then, the base end portion 27b of the release operation pin 27 and the base end portion 26b of the stopper pin 26 are connected to each other on the right side of the right side plate portion 13 of the first arm 11 via the connecting piece 28. The release operation pin 27 and the stopper pin 26 are connected so as to be movable together. The right side of the right side plate portion 13 of the first arm 11 corresponds to the inner side of the left joint device 10 with respect to the seat portion 2A (chair 1).

  That is, as shown in FIG. 8, the connecting piece 28 is made of metal having high rigidity and is disposed on the right side of the right side plate portion 13 of the first arm 11. At one end and the other end of the connecting piece 28, mounting holes 28a and 28b having a circular cross section are provided. 9A, when the base end portion 27b of the release operation pin 27 is inserted into the one attachment hole 28a of the connecting piece 28 and is locally crushed into a large diameter, the release operation pin 27 is attached to the connecting piece 28 in a fixed state. Further, when the base end portion 26b of the stopper pin 26 is inserted into the other mounting hole 28b of the connecting piece 28 and is locally crushed into a large diameter, the base end portion 26b of the stopper pin 26 is connected to the connecting piece 28b. 28 is fixedly attached. As a result, the base end portion 27b of the release operation pin 27 and the base end portion 26b of the stopper pin 26 are connected via the connecting piece 28 so that the release operation pin 27 and the stopper pin 26 can move together. .

  A compression coil spring 29 as a first urging member for applying a urging force to the release operation pin 27 and the stopper pin 26 is attached to the release operation pin 27 in an extrapolated state. Further, the compression coil spring 29 is arranged in a state of being sandwiched between a large-diameter portion locally formed at the distal end portion 27 a of the release operation pin 27 and the left side surface of the left side plate portion 13 of the first arm 11. ing. The large-diameter portion of the release operation pin 27 includes a rivet head that forms the release operation pin 27.

  The stopper pin 26 is constantly urged by the compression coil spring 29 in the direction Q that moves from the non-stop position (see FIG. 9A) to the stop position (see FIG. 10A).

Then, as shown in FIG. 10A, the restriction release mechanism 31 pushes the distal end portion 27a of the release operation pin 27 in the direction of the arrow P toward the left joint device 10 (specifically, the first and second arms 11 and 21). by releasing the operation pin 27 is is moved in the axial J ₃ direction of releasing operation pin 27, non stopper pin 26 as shown in FIG. 9A is a stop position against the urging force of the compression coil spring 29 It is configured to be moved to the stop position.

  Next, the configuration of the right articulator 40 will be described below with reference to FIGS.

  As described above, the right articulator 40 includes the angle adjustment mechanism 60 that can adjust the deployment angle θ of the back frame 3 stepwise, and further, the right articulator 40 is seated at the rear end of the right frame 2a of the seat frame 2. The first arm 41 fixedly fixed so as not to move with respect to the frame 2 and the connection socket 3c as the lower end portion of the right frame portion 3a of the back frame 3 move (rotate) integrally with the back frame 3. And a second arm 51 attached in a fixed state (see FIG. 1). A second arm 51 is pivotally attached to the first arm 41 via a rotation shaft 49. Here, in detail, the angle adjustment mechanism 60 adjusts the deployment angle θ of the back frame 3 with respect to the seat frame 2 by gradually adjusting the deployment angle of the second arm 51 with respect to the first arm 41 of the right joint device 40. It adjusts in stages.

  The first arm 41 is formed integrally with the attachment portion 42 on the base end side (that is, the rear end side) of the attachment portion 42 and the cylindrical attachment portion 42 attached to the rear end portion of the right frame portion 2a of the seat frame 2. A pair of left and right side plate portions 43, 43 are provided.

  The second arm 51 includes a cylindrical attachment portion 52 attached to a connection socket 3c as a lower end portion of the right frame portion 3a of the back frame 3, and an attachment portion 52 on the proximal end side (that is, the lower end side) of the attachment portion 52. A substantially disc-shaped rotating plate portion 53 formed integrally is provided.

  As shown in FIG. 13, the second arm 51 is configured by integrally combining a pair of left and right second arm constituting pieces 51 </ b> A and 51 </ b> A like the second arm 21 of the left joint device 10. is there. Both component pieces 51A and 51A are fastened by rivets 51a.

  An engaging hole 55 having a non-circular cross section (a hexagonal cross section in detail) as a shaft hole is provided in the center of the rotary plate 53 of the second arm 51 so as to penetrate in the thickness direction of the rotary plate 53. ing. The rotating plate portion 53 is disposed between the pair of left and right side plate portions 43, 43 of the first arm 41. In this state, the rotating shaft 49 is a pivot hole having a circular cross section provided in the one side plate portion 43. 45 and the engagement hole 55 of the rotary plate portion 53 and the pivot hole 45 having a circular cross section provided in the other side plate portion 43 are inserted into the first arm 41 as described above. The second arm 51 is pivotally attached to the central portion of the rotary plate portion 53 via a rotary shaft 49. Further, the lower ends of both side plate portions 43, 43 are integrally connected by a bottom plate portion 44.

  As shown in FIG. 13, the intermediate portion 49 c in the axial direction of the rotating shaft 49 is locally in a non-circular cross section (specifically, a hexagonal cross section) corresponding to the cross sectional shape of the engagement hole 55 of the rotating plate 53. The distal end portion 49a and the proximal end portion 49b in the axial direction of the rotating shaft 49 are each formed in a circular cross section. The intermediate portion 49 c of the rotating shaft 49 is inserted into the engaging hole 55 of the rotating plate portion 53 in an engaged state. Thereby, the rotating shaft 49 rotates integrally with the second arm 51 in the pivot shaft holes 45 and 45 with the rotating operation of the rotating plate portion 53 of the second arm 51.

  When the rotation shaft 49 is inserted into the pivot hole 45 of one side plate portion 43, the engagement hole 55 of the rotation plate portion 53, and the pivot hole 45 of the other side plate portion 43, the distal end portion of the rotation shaft 49 is inserted. 49a protrudes to the left side of the left side plate portion 43 of the first arm 41, and a locking groove 49d is formed at the distal end portion 49a. And the inner end part 70a of the mainspring spring 70 as one end part of the 2nd energizing member which always energizes the back frame 3 (2nd arm 51) to the normal rotation direction S is latched by the latching groove 49d. .

  A swing shaft 66 having a circular cross section made of rivets is attached to both side plate portions 43 of the first arm 41 so as to protrude to the left side of the left plate portion 43. And the outer end part 70b of the mainspring spring 70 as the other end part of the second urging member is locked to the protruding end part 66a of the swing shaft 66 (see FIG. 12). Accordingly, the back frame 3 (second arm 51) is always urged in the forward rotation direction S by the mainspring spring 70. Reference numerals “47” and “47” in FIG. 13 are mounting holes for the swing shaft 66.

  The angle adjusting mechanism 60 includes a plate-shaped metal claw member 61 and the like. The claw member 61 is configured by integrally combining a pair of left and right claw member constituting pieces 61A and 61A.

  As shown in FIGS. 14 and 15, the claw member 61 is disposed between the side plate portions 43, 43 of the first arm 41. An upper end portion as a base end portion of the claw member 61 is pivotally supported by a swing shaft 66 (more specifically, a base end portion of the swing shaft 66). Reference numeral “63” in FIG. 13 denotes a swing shaft hole. A plurality of gear teeth 54 are formed on the outer peripheral edge portion of the rotating plate portion 53 of the second arm 51 so as to be arranged in an arc shape around the engagement hole 55. A plurality of claw teeth 62 that can mesh with the gear teeth 54 are formed on the side edge of the outer peripheral edge of the claw member 61 facing the gear teeth 54 of the rotating plate 53.

  In FIG. 14, the claw teeth 62 of the claw member 61 are engaged with the gear teeth 54 of the rotating plate portion 53, whereby the back frame 3 (second arm 51) rotates in the normal rotation direction S and the reverse rotation direction G. The rotation of the back frame 3 (second arm 51) is locked so that it does not occur.

  In FIG. 15, the claw teeth 62 of the claw member 61 are separated from the gear teeth 54 of the rotating plate portion 53, and the engagement between the claw teeth 62 and the gear teeth 54 is released, whereby the back frame 3 (second arm) 51) The rotation lock is released.

  Further, the claw member 61 has an operation length that is bent and extended in a substantially square shape toward the gear tooth 54 side of the rotating plate 53 with respect to the direction from the lower end as the free end of the claw member 61 to the upper end. A hole 64 is provided. Both side plate portions 43, 43 of the first arm 41 are provided with guide long holes 46, 46 extending in an arc shape around the rotation shaft 49 (the pivot hole 45). The operation pin 65 is inserted in communication with one guide slot 46, the operation slot 64, and the other guide slot 46, and the base end of the operation pin 65 is connected to the lever-type control rod 67. It is attached in a fixed state (see FIG. 13). Reference numeral “67d” denotes a mounting hole for the operation pin 65.

  The operating rod 67 performs a lock operation for engaging the claw teeth 62 of the claw member 61 with the gear teeth 54 of the rotating plate portion 53 and a lock release operation for releasing the engagement between the claw teeth 62 and the gear teeth 54. . A shaft hole 67a having a circular cross section is provided at the base end portion of the operation rod 67, and the tip end of the operation rod 67 is inserted by inserting the base end portion 49b having a circular cross section of the rotary shaft 49 into the shaft hole 67a. The operating rod 67 is attached to the right joint device 40 (specifically, the first arm 41 of the right joint device 40) so that the portion 67b can swing up and down around the rotation shaft 49.

  Reference numeral “68” in FIG. 13 is a tension coil spring as a third urging member that constantly urges the distal end portion 67b of the operating rod 67 downward. As shown in FIG. 12, one end portion 68a of the tension coil spring 68 is locked to a cylindrical collar 69a attached to a locking pin 69 made of rivets fixed to both side plate portions 43, 43 of the first arm 41. The other end 68 b of the tension coil spring 68 is locked to a locking piece 67 c formed on the operating rod 67. As a result, the operating rod 67 is constantly urged by the tension coil spring 68 so that the tip 67b of the operating rod 67 moves downward.

  In FIG. 14, in the right joint device 40, a grip portion (not shown) attached to the distal end portion 67 b of the operating rod 67 with the hand of a seated person (not shown) seated on the chair 1 (specifically, the right hand of the seated person). 1), the tip 67b of the operating rod 67 is rotated upward from the position shown in FIG. 14 against the biasing force of the tension coil spring 68 as shown in FIG. The operation pin 65 thus moved is moved upward in the guide elongated holes 46 and 46 and the operation elongated hole 64, and the claw member 61 moves away from the rotary plate portion 53 around the swinging shaft 66 in accordance with the moving operation. And the meshing between the claw teeth 62 of the claw member 61 and the gear teeth 54 of the rotating plate 53 is released. As a result, the rotation lock of the back frame 3 (second arm 51) is released. This operation is referred to as a lock release operation for the right joint device 40. Then, the back frame 3 rotates in the forward rotation direction S by the urging force of the mainspring spring 70.

  When the deployment angle θ of the back frame 3 is an angle desired by the seated person, the tip 67b of the operating rod 67 is moved downward from the position shown in FIG. 15 toward the original position as shown in FIG. As a result, the claw member 61 moves in the direction approaching the rotating plate portion 53 around the swing shaft 66, and the claw teeth 62 of the claw member 61 mesh with the gear teeth 54 of the rotating plate portion 53. As a result, the rotation of the back frame 3 (second arm 51) is locked, and the deployment angle θ of the back frame 3 is fixed to a desired angle. This operation is referred to as a lock operation for the right joint device 40.

  In the right articulator 40, the deployment angle θ of the back frame 3 can be adjusted stepwise in accordance with the pitch of the gear teeth 54 of the rotary plate 53 of the second arm 51.

The range of the deployment angle θ of the back frame 3 that can be adjusted by the angle adjustment mechanism 60 in the right joint device 40 is set to be equal to or larger than the range from the first angle θ ₁ to the third angle θ _3. It is particularly desirable. In the present invention, the range of the deployment angle θ of the back frame 3 that can be adjusted by the angle adjustment mechanism 60 is not limited to such a range, and is at least within the use range θ _1-2 (that is, the first angle θ). ₁ may be any second angle θ to _2).

  Further, in the present invention, the angle adjusting mechanism 60 is not limited to one that can adjust the deployment angle θ of the back frame 3 in a stepwise manner as described above, and in addition, JP 2011-167354 A The deployment angle θ of the back frame (second arm) can be adjusted steplessly as disclosed in JP2013-231487A, JP2014-61175A, JP2015-53970A, and the like. It may be a thing.

  Next, operation | movement and the usage method of the chair 1 of this embodiment are demonstrated below.

In the process of manufacturing the chair 1, as shown in FIG. 3, the leg portion 4A (leg frame 4) of the chair 1 is separated from the seat portion 2A (seat frame 2). Seat frame 2 and the back frame 3 are connected to each other via the two joint devices 10, 40, the expansion angle theta of the back frame 3 relative to the seat frame 2 has become approximately 180 ° is the third angle theta _3. At this time, the rotation of the back frame 3 is performed between the claw teeth 62 of the claw member 61 of the angle adjustment mechanism 60 of the right joint device 40 and the rotation plate portion 53 so that the back frame 3 does not rotate in the forward rotation direction S and the reverse rotation direction G. It is locked by meshing with the gear teeth 54.

In the state of the third angle θ ₃ , the cushion member 5 and the like are attached to the seat frame 2 and the back frame 3. Thereby, this attachment work can be performed easily.

When the chair 1 is transported for the purpose of shipping the chair 1 from the manufacturing factory after the installation work is completed, the seat portion 2A and the backrest portion 3A develop the back frame 3 relative to the seat frame 2. The packaging is performed in the packaging box while maintaining the angle θ at the third angle θ ₃ (that is, about 180 °). Therefore, the packing size is small, and the cost for transporting the chair 1 can be reduced. In addition, the leg part 4A (leg frame 4) is normally packed and conveyed separately from the seat part 2A and the backrest part 3A.

  Then, the connecting operation between the leg portion 4A and the seat portion 2A is performed at the transport destination. As a delivery destination, the shop front which displays and sells the chair 1 is illustrated. Moreover, the connection operation | work with 4 A of leg parts and 2 A of seat parts may be performed in the installation place of the chair 1, etc. by the purchaser who purchased the chair 1. FIG.

In a state where the deployed angle θ of the back frame 3 with respect to the seat frame 2 is the third angle θ ₃ (ie, about 180 °), the second arm 21 of the left joint device 10 is moved to the first arm 11 as shown in FIG. 9B. It strikes against the rear end portion 14a of the bottom plate portion 14 as the provided stopper portion, thereby restricting the rotation of the back frame 3 in the reverse rotation direction G, that is, the unfolding angle θ of the back frame 3 is The third angle θ ₃ is restricted so as not to increase more than the third angle θ ₃ .

  Further, as shown in FIGS. 9A and 9B, the distal end portion of the stopper pin 26 (more specifically, the distal end surface of the stopper pin 26) 26 a of the restriction mechanism 30 of the left joint device 10 is the side surface of the rotating plate portion 23 of the second arm 21. The stopper pin 26 is held against the urging force of the compression coil spring 29 in the non-stop position. At this time, as shown in FIG. 9A, the stopper pin 26 is disposed in the holding hole 16 of the right side plate portion 13 of the first arm 11, and the compression coil spring 29 is in a close contact state, and the restriction releasing mechanism The pushing movement of the release operation pin 31 of 31 is restricted by the compression coil spring 29 in a close contact state. In the present invention, the restriction of the pushing movement of the release operation pin 27 is not limited to being performed when the compression coil spring 29 is brought into a close contact state. The step portion 27 c (see FIG. 8) formed in an outwardly bulging shape may be configured to abut on the left side surface of the left side plate portion 13 of the first arm 11.

Also in the right articulator 40, when the deployment angle θ of the back frame 3 is the third angle θ ₃ (ie, about 180 °), the second arm 51 of the right articulator 40 is the first arm as shown in FIG. The rear end portion 44a of the bottom plate portion 44 serving as a stopper portion provided in 41 is abutted, and thereby the rotation of the back frame 3 in the reverse rotation direction G is restricted, that is, the deployment angle of the back frame 3 theta is restricted to the third angle theta ₃ so as not to increase than the third angle theta _3.

  Further, the claw teeth 62 of the claw member 61 of the angle adjusting mechanism 60 are engaged with the gear teeth 54 of the rotating plate portion 53 of the second arm 51, so that the back frame 3 is moved in the positive rotation direction S and The rotation of the back frame 3 is locked so as not to rotate in the reverse rotation direction G. In this locked state, the cushioning member 5 and the like are attached to the seat frame 2 and the back frame 3, or the seat frame 2 and the back frame 3 are packed.

After connecting the leg 4A and the seat 2A, the deployment angle θ of the back frame 3 is reduced from the third angle θ ₃ (about 180 °) in order to use the back frame 3 (backrest 3A) as a backrest. In other words, when the back frame 3 is rotated in the forward rotation direction S, as shown in FIG. 15, the unlocking operator (for example, the operator connecting the leg 4A and the seat 2A, the chair 1) The seated person) performs the above-described unlocking operation on the right joint device 40.

Then, the back frame 3 is rotated in the normal rotation direction S by the urging force of the mainspring spring 70, and the deployment angle θ of the back frame 3 is reduced. That is, in the left articulator 10, the rotating plate portion 23 rotates so that the deployed angle θ of the back frame 3 is displaced from the third angle θ ₃ (about 180 °) shown in FIG. 9B to the second angle θ ₂ side. . As the rotating plate portion 23 rotates, the distal end portion 26a of the stopper pin 26 is relatively moved on the side surface 23a of the rotating plate portion 23 between the first and second abutting portions 24a and 24b (that is, the recess 24c). Sliding.

When the unfolded angle theta of the back frame 3 is displaced to the second angle theta _2, as shown in FIGS. 10A and 10B, the stopper pin 26 of the regulating mechanism 30 of the tip portion 26a, the side surface 23a of the rotating plate 23 ( The stopper pin 26 is automatically moved from the non-stop position to the stop position side by the biasing force of the compression coil spring 29. When the stopper pin 26 moves to the stop position, the deployment angle θ of the back frame 3 is restricted to the use range θ _1-2 , and the connecting piece 28 is connected to the right side plate of the first arm 11 as shown in FIG. 10A. It strikes against the right side surface of the portion 13, thereby restricting the stopper pin 26 to be disposed at the stop position. In this state, the stopper pin 26 is disposed in both the holding holes 16, 16 across the both holding holes 16, 16. After being in this state, the back frame 3 (backrest portion 3A) is used as the backrest of the chair 1.

In a state where the deployment angle θ of the back frame 3 is within the use range θ _1-2 , when the seated person on the chair 1 adjusts the deployment angle θ of the back frame 3, the back frame 3 is placed on the back of the seated person. The seated person performs the above-described unlocking operation on the right joint device 40 in the received state. Thereby, the deployment angle θ of the back frame 3 can be adjusted stepwise within the use range θ _1-2 . Then, the back of the seat occupant is moved back and forth so that the deployment angle θ of the back frame 3 becomes the angle desired by the seat occupant, and when the deployment angle θ of the back frame 3 is the desired angle, the seat occupant moves to the right joint device 40. By performing the above-described locking operation, the deployment angle θ of the back frame 3 is locked at a desired angle.

In such an adjustment operation of the deployment angle θ of the back frame 3, if the deployment angle θ of the back frame 3 is displaced from, for example, a substantially intermediate angle within the use range θ _1-2 to the first angle θ ₁ , FIG. As shown, in the left joint device 10, the first abutting portion 24 a of the rotating plate portion 23 of the second arm 21 abuts against the stopper pin 26, thereby restricting the rotation of the back frame 3 in the positive rotation direction S. unfolded angle theta of the back frame 3 is restricted to a first angle theta ₁ to not smaller than the first angle theta _1. At this time, in the left joint device 10, the second arm 21 strikes the rear end portion 18 a of the upper plate portion 18 as a stopper portion provided on the first arm 11, and thereby the forward rotation direction S of the back frame 3. The rotation to the is surely regulated. In the present invention, the left articulator 10 prevents the second arm 21 from hitting the rear end portion 18a of the upper plate portion 18 of the first arm 11 when the first hitting portion 24a hits the stopper pin 26. It is not excluded that it is configured.

If the unfolding angle θ of the back frame 3 is displaced from, for example, a substantially intermediate angle to the second angle θ ₂ within the use range θ _1-2 , as shown in FIG. butting portion 24a is strike the stopper pin 26, the result, as unfolded angle theta of rotation in the reverse rotation direction G of the back frame 3 is restricted i.e. back frame 3 does not increase than the second angle theta ₂ It is restricted to the second angle θ _2.

On the other hand, when the deployment angle θ of the back frame 3 is displaced from the use range θ to the third angle θ ₃ (that is, about 180 °), the unlocking operator performs the above-described unlocking operation on the right joint device 40. 10A, the distal end portion 27a of the release operation pin 27 of the restriction release mechanism 31 of the left joint device 10 is moved from the left side with respect to the seat portion 2A with the fingers of the lock release operator as shown in FIG. 10A. J ₃ (in detail the first and second arms 11 and 21) left joint 10 along the direction to the side moves pushed in the direction of the arrow P. Thereby, the stopper pin 26 is moved from the stop position to the non-stop position side against the urging force of the compression coil spring 29, and the compression coil spring 29 is compressed when the stopper pin 26 is arranged at the non-stop position. Thus, the pushing movement of the release operation pin 27 is stopped (restricted) (see FIG. 9A).

The back frame 3 is rotated in the reverse rotation direction G while the stopper pin 26 is arranged in the non-stop position as described above (that is, with the distal end portion 27a of the release operation pin 27 pressed with a finger). By moving the deployment angle θ of the back frame 3 from the use range θ _1-2 to the third angle θ ₃ side, the distal end portion 26a of the stopper pin 26 is moved to the second arm as shown in FIGS. 9A and 9B. 21 abuts against the side surface 23a of the rotating plate portion 23. Accordingly, the stopper pin 26 is held at the non-stop position against the urging force of the compression coil spring 29. Therefore, even if the finger is released from the distal end portion 27a of the release operation pin 27, the stopper pin 26 does not move to the stop position but is maintained at the non-stop position.

In this state, the back frame 3 is further rotated in the reverse rotation direction G so that the deployed angle θ of the back frame ₃ is displaced to the third angle θ ₃ . Then, as shown in FIG. 9B, in the left joint device 10, the second arm 21 strikes the rear end portion 14a of the bottom plate portion 14 of the first arm 11, and the rotation of the back frame 3 in the reverse rotation direction G is restricted. that unfolded angle theta of the back frame 3 is restricted to the third angle theta ₃ so as not to increase than the third angle theta _3. Further, at this time, as shown in FIG. 15, also in the right joint device 40, the second arm 51 hits the rear end portion 44 a of the bottom plate portion 44 of the first arm 41, and the back frame 3 rotates in the reverse rotation direction G. Be regulated. Then, the deployment angle θ of the back frame ₃ is locked to the third angle θ ₃ by performing the above-described locking operation on the right articulator 40.

According to the chair 1 of the present embodiment, the restriction mechanism 30 of the left articulator 10 has the first and second angles θ of the back frame 3 with the stopper pin 26 disposed at the stop position. _1, first and second butting portions 24a each time the theta _2, 24b is by impinging the stopper pin 26, is configured to regulate the use range theta _1-2 deployment angle theta of the back frame 3 ing. As a result, the deployment angle θ of the back frame 3 can be reliably restricted to the use range θ _1-2 .

Further, in the restricting mechanism 30, when the stopper pin 26 is in the non-stop position, the deployment angle θ of the back frame 3 is displaced from the use range θ _1-2 to the third angle θ ₃ side, so that the stopper pin The stopper pin 26 is configured to be held at the non-stop position against the urging force of the compression coil spring 29 by the front end portion 26 a of the second arm 21 abutting against the side surface 23 a of the rotary plate portion 23 of the second arm 21. Therefore, the restriction release operation for releasing the restriction on the deployment angle θ of the back frame 3 can be easily performed.

Furthermore, when the unfolding angle θ of the back frame 3 is displaced from the third angle θ ₃ into the use range θ _1-2 , the regulating mechanism 30 moves to the side surface 23a of the rotating plate portion 23 of the tip end portion 26a of the stopper pin 26. The stopper pin 26 is configured to move from the non-stop position to the stop position by the urging force of the compression coil spring 29, so that the unfolding angle θ of the back frame 3 is used within the use range θ _1-2. It is also possible to easily perform the restricting operation for restricting to the above.

In the restriction release mechanism 31 of the left joint device 10, the stopper pin 26 is compressed through the connecting piece 28 when the distal end portion 27 a of the release operation pin 27 is pushed and moved along the axis J ₃ direction of the release operation pin 27. The coil spring 29 is configured to be moved from the stop position to the non-stop position against the urging force of the coil spring 29. Therefore, the restriction release operation for releasing the restriction of the deployment angle θ of the back frame 3 can be performed by a pressing operation of pressing the distal end portion 27a of the release operation pin 27. Therefore, the restriction release operation can be performed more easily than when the restriction release operation is performed by pulling a predetermined release operation member such as the release operation pin 27.

Furthermore, the release operation pin 27, the first arm 11 and the first and second butting portion 24a of Kururugijikusen _{J 1} and parallel to and the second arm 21 and the second arm 21, a position not 24b and impinges The base end portion 27b of the release operation pin 27 and the base end portion 26b of the stopper pin 26 are connected via a connecting piece 28 so that the release operation pin 27 and the stopper pin 26 can move together. By doing so, the restriction release operation can be performed easily and reliably, and the restriction release mechanism 31 can be simplified.

Further, as shown in FIG. 9A, the regulating mechanism 30 is configured so that when the stopper pin 26 is disposed at the stop position, the stopper pin 26 straddles both the holding holes 16, 16 and the inside of both holding holes 16, 16. It is comprised so that it may be arrange | positioned and hold | maintained. Therefore, the impact force applied to the stopper pin 26 when the first and second abutting portions 24a and 24b abut against the stopper pin 26 disposed at the stop position can be stably received by both the holding holes 16 and 16. it can. As a result, the deployment angle θ of the back frame 3 can be reliably regulated to the first and second angles θ ₁ and θ ₂ , respectively.

Further, the release operation pin 27 is disposed and held in the holding holes 17 and 17 across the holding holes 17 and 17. From this, since the distal end portion 27a pushes the release operation pin 27 of the release operation pin 27 is reliably moved along its axis J ₃ direction, it can be reliably regulated release operation.

  Here, in the present invention, not only the left joint device 10 but also the right joint device 40 may be provided with the restriction mechanism 30 and the restriction release mechanism 31. However, as in this embodiment, only the left joint device 10 that is one of the two joint devices includes the restriction mechanism 30 and the restriction release mechanism 31, and only the right joint device 40 that is the other joint device. It is particularly desirable to have an angle adjustment mechanism 60. The reason is as follows.

  That is, if one of the articulators includes the restriction mechanism 30, the restriction release mechanism 31, and the angle adjustment mechanism 60, the size of the one articulator becomes large. On the other hand, only one articulator (left articulator 10) includes the restriction mechanism 30 and the restriction release mechanism 31 as in the present embodiment, and only the other articulator (right articulator 40) adjusts the angle. By providing the mechanism 60, both the articulators 10 and 40 can be reduced in size.

  The right articulator 40 includes a mainspring spring 70 as a second urging member that urges the back frame 3 in the positive rotation direction S, which is the rotation direction in which the deployment angle θ of the back frame 3 decreases. The seated person can easily adjust the deployment angle θ of the back frame 3.

  Here, in the present invention, not only the right joint device 40 but also the left joint device 10 may include a second biasing member that biases the back frame 3 in the forward rotation direction S. An example of the left articulator 110 when the left articulator is provided with the second biasing member is shown in FIGS. In these drawings, the same reference numerals are given to elements having the same functions as the elements shown in the above embodiment, and the description thereof is omitted.

  Furthermore, the present invention does not exclude the case where only the left articulator 10 includes a second urging member that urges the back frame 3 in the forward rotation direction S.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

  In the present invention, it is particularly desirable that the first arm 11 of the left joint device 10 and the second arm 21 are fixedly attached to the seat frame 2 and the back frame 3, respectively, as in the above embodiment. For example, the case where the first arm 11 of the left joint device 10 is fixedly attached to the back frame 3 and the second arm 21 is fixed to the seat frame 3 is not excluded.

  INDUSTRIAL APPLICABILITY The present invention can be used for a reclining chair that can adjust the deployment angle of the backrest with respect to the seat.

1: Reclining chair 2: Seat frame 3: Back frame 10: Left joint device (first joint device)
11: first arm 13: side plate portion 16: holding hole 21: second arm 23: rotating plate portion 24a: first abutting portion 24b: second abutting portion 24c: recess (first abutting portion and second abutting portion Between the club)
26: Stopper pin (stopper member) 27: Release operation pin 30: Restriction mechanism 31: Restriction release mechanism 40: Right articulator 60: Angle adjustment mechanism θ: Deployment angle of the back frame θ ₁ : First angle θ ₂ : Second Angle θ ₃ : Third angle θ _1-2 : Use range

Claims (6)

The back frame of the backrest part is connected to the seat frame of the seat part via a pair of left and right joints, and the deployment angle of the back frame relative to the seat frame can be adjusted stepwise or steplessly,
The first articulator, which is at least one of the two articulators, is attached to one of the seat frame and the back frame in a fixed state and to the other in a fixed state. A second arm, and the second arm is pivotally attached to the first arm so as to be rotatable relative to the first arm.
Furthermore, the first articulator includes a regulating mechanism that regulates the deployment angle of the back frame when the back frame is used as a backrest within a use range from a first angle to a second angle, and When the deployment angle of the frame is displaced from the third angle out of the use range into the use range, the deployment mechanism restricts the deployment angle of the back frame to the use range. ,
The regulation mechanism is
Two first and second abutting portions that are integrally rotatable with the second arm and spaced apart from each other in the rotational direction of the two arms, and a position deviated from between the two abutting portions. A stopper member that is movable from a stop position to a stop position that is a position between the two abutting portions, and
The first abutting portion abuts against the stopper member when the deployed angle of the back frame is the first angle with the stopper member disposed at the stop position, and the back frame A reclining chair configured to restrict the deployment angle of the back frame to the use range by the second abutment portion striking the stopper member when the deployment angle is the second angle. The first articulator includes a restriction release mechanism for releasing the restriction of the deployment angle of the back frame by the restriction mechanism,
The second arm has a rotating plate portion that can rotate integrally with the second arm, and is pivotally attached to the first arm at a substantially central portion of the rotating plate portion,
The pivot axis of the first arm and the second arm is substantially parallel to the thickness direction of the rotating plate portion of the second arm,
The stopper member is arranged to be movable from the non-stop position to the stop position in a direction substantially parallel to the pivot axis, and is moved in a direction to move from the non-stop position to the stop position by a biasing member. Energized,
The two abutting portions are formed on the rotating plate portion of the second arm so as to be separated from each other in the rotation direction of the rotating plate portion,
The restriction release mechanism restricts the deployment angle of the back frame by the restriction mechanism by the stopper member being moved from the stop position to the non-stop position against the urging force of the urging member. Configured to release,
The regulation mechanism is
When the stopper member is disposed at the non-stop position, the deployment angle of the back frame is displaced from the use range to the third angle side, and the tip of the stopper member is moved to the second arm. The stopper member is held at the non-stop position against the urging force of the urging member by striking against the side surface of the rotating plate part,
When the deployment angle of the back frame is displaced from the third angle within the use range, the abutment of the tip of the stopper member against the side surface of the rotating plate is released, and the stopper member The reclining chair according to claim 1, wherein the reclining chair is configured to move from the non-stop position to the stop position by a biasing force of the biasing member. The restriction release mechanism is
A release operation pin disposed in a state in which a distal end portion protrudes outward of the first articulator with respect to the seat portion, and the distal end portion of the release operation pin extends along an axial direction of the release operation pin. The stopper member is configured to be moved from the stop position to the non-stop position against the urging force of the urging member by being pushed and moved toward the first articulator. The reclining chair according to 2. The release operation pin is disposed substantially parallel to the pivot axis of the first arm and the second arm and at a position where it does not collide with both the abutting portions of the second arm,
The reclining chair according to claim 3, wherein a base end portion of the release operation pin and the stopper member are connected so that the release operation pin and the stopper member can move together. The first arm includes a pair of left and right side plates that are spaced apart from each other and arranged substantially in parallel.
The two abutting portions of the second arm are disposed between the side plate portions of the first arm;
Each of the side plate portions is provided with a holding hole for inserting and holding the stopper member so as to be slidable in the direction of moving from the non-stop position to the stop position.
The regulation mechanism is
5. The structure according to claim 1, wherein when the stopper member is disposed at the stop position, the stopper member is inserted and held in both the holding holes across the both holding holes. Reclining chair as described in Only one of the joints is the first joint,
Only the other articulator of the two articulators includes an angle adjustment mechanism capable of adjusting the deployment angle of the back frame stepwise or steplessly at least within the use range. A reclining chair according to any of the above.

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