JP6684660B2 - Armrests and chairs - Google Patents

Description

  TECHNICAL FIELD The present invention relates to an armrest on which an occupant seated on a chair places an elbow or an arm, and a chair including the armrest.

  As an armrest for a chair, there is known one in which an upper layer member that receives a seated occupant's armrest load is supported by a lower layer member therebelow so as to be slidable in the chair width direction (see, for example, Patent Documents 1 and 2). ).

In the armrests described in Patent Documents 1 and 2, the lower layer member and the upper layer member of the armrest body can be slidably displaced in the chair width direction by a pair of front and rear guide mechanisms including guide protrusions and guide grooves. The guide groove of the guide mechanism is formed along one of the lower layer member and the upper layer member along the chair width direction, and the guide protrusion of the guide mechanism is fixed to the other of the lower layer member and the upper layer member. It is slidably fitted to.
In the armrest described in Patent Document 2, the guide protrusions of the front and rear guide mechanisms are connected to each other via a retainer plate.

Japanese Patent No. 5653601 U.S. Pat. No. 7,815,259

  However, in the armrests described in Patent Documents 1 and 2, since the pair of guide mechanisms are arranged at two positions in the front and rear that are separated from each other in the longitudinal direction of the lower layer member and the upper layer member, the upper layer member of the seated person's elbow or arm is When the operation load in the chair width direction is input to the front and rear biased positions, the load is biasedly input to the front and rear guide mechanisms at different timings, so that bending and biased pressing force may be generated in the guide mechanism. Then, when a bending force or a biased pressing force is generated in the guide mechanism, there is a concern that smooth sliding operation of the upper layer member with respect to the lower layer member may be hindered.

  Therefore, the present invention is an armrest capable of smoothly displacing the upper layer member in a direction substantially orthogonal to the longitudinal direction with respect to the lower layer member, even when an operation load is input to a portion deviated in the longitudinal direction of the upper layer member, And to provide a chair equipped with the armrest.

The armrest according to the present invention adopts the following configuration in order to solve the above problems.
One armrest according to the present invention is an upper layer member that is long in one direction, a lower layer member that is disposed below the upper layer member and supports the upper layer member, and the lower layer member that is separated in the longitudinal direction of the upper layer member. And a plurality of first guide mechanisms arranged at a plurality of positions between the upper layer member and guiding displacement of the upper layer member in a direction substantially orthogonal to the longitudinal direction with respect to the lower layer member, and one first guide mechanism. A rotation transmission element for transmitting the input operation load in a direction substantially orthogonal to the longitudinal direction of the upper layer member in synchronization with the other first guide mechanism, and the first guide mechanism is provided. A holding member fixed to one of the lower layer member and the upper layer member, a pulley rotatably held by the holding member, and a pulley fixed to the other of the lower layer member and the upper layer member. A contact member that contacts the outer peripheral surface of the lead and rotates the pulley according to relative displacement of the lower layer member and the upper layer member in a direction substantially orthogonal to the longitudinal direction, and the synchronization transmission mechanism. , A rotary shaft that connects the pulleys of each of the first guide mechanisms such that they can rotate synchronously .

  In the case of the present invention, the plurality of first guide mechanisms arranged apart from each other in the longitudinal direction are capable of synchronously transmitting the operating loads to each other via the synchronization transmission mechanism of the rotation transmission element. Therefore, when the operation load is first input to any one of the first guide mechanisms that are separated in the longitudinal direction, the operation load is input to the remaining first guide mechanism at the same timing via the synchronization transmission mechanism. Become. Since the synchronization transmission mechanism is a synchronization transmission mechanism that uses a rotation transmission element, it is difficult for bending and biased pressing force to occur inside the synchronization transmission mechanism and the first guide mechanism.

Further, in this case, when an operation load is input to the upper layer member, the pulley of one of the first guide mechanisms is held by the holding member and relatively displaced with respect to the other of the lower layer member and the upper layer member, the relative displacement is determined. The amount of rotation is applied to the pulley through the corresponding contact member. In this way, when the pulley of the first first guide mechanism rotates, the rotation is transmitted as rotation in synchronization with the remaining pulleys of the first guide mechanism through the rotation shaft. When the rotation is transmitted to the remaining pulley of the first guide mechanism, the rotation of the pulley displaces the abutting contact member in a direction substantially orthogonal to the longitudinal direction of the upper layer member. As a result, the operating load is input to the contact portions of all the first guide mechanisms at the same timing.

The rotating shaft may be formed integrally with the shaft of each pulley.
In this case, the plurality of pulleys of the first mechanism and the rotary shaft that constitutes the synchronization transmission mechanism can be configured as simple parts. Therefore, by adopting this configuration, it is possible to reduce the product cost.

The pulley may be a pinion gear having meshing teeth on the outer peripheral surface thereof, and the contact member may be a rack gear meshing with the pinion gear.
In this case, the pulley and the abutting member are always meshed with the meshing teeth of the pinion gear and the rack gear, so that slippage between the pulley and the abutting member can be eliminated and tilting of the pulley with respect to the abutting member can be suppressed. can do. Therefore, by adopting this configuration, it is possible to reliably synchronize all the first guide mechanisms and to prevent rattling of each of the first guide mechanisms.

The holding member has a guide protrusion, and the other one of the lower layer member and the upper layer member has a guide groove slidably abutting the guide protrusion, and the guide protrusion and the guide groove are You may make it comprise the 2nd guide mechanism which guides the displacement of the said upper layer member with respect to the lower layer member in the direction substantially orthogonal to the longitudinal direction.
In this case, since the holding member of the first guide mechanism is also guided by the second guide mechanism having the guide projection of the holding member and the guide groove slidably abutting the guide projection, the holding member holds the pulley. It becomes possible to stably guide the holding member in the direction substantially orthogonal to the longitudinal direction of the upper layer member.

The other of the lower layer member and the upper layer member has a plurality of holding portions that elastically hold the rotation shaft at an arbitrary relative position in a direction substantially orthogonal to the longitudinal direction of the lower layer member and the upper layer member. You can do it.
In this case, when the upper layer member is displaced in a direction substantially orthogonal to the longitudinal direction, one of the plurality of holding portions elastically holds the rotation shaft, so that the operator can feel a moderation. it can.

Another armrest according to the present invention is an upper layer member that is long in one direction, a lower layer member that is arranged below the upper layer member and supports the upper layer member, and the lower layer member that is separated in the longitudinal direction of the upper layer member. And a plurality of first guide mechanisms arranged at a plurality of positions between the upper layer member and guiding displacement of the upper layer member in a direction substantially orthogonal to the longitudinal direction with respect to the lower layer member, and one first guide mechanism. A rotation transmission element for transmitting the input operation load in a direction substantially orthogonal to the longitudinal direction of the upper layer member in synchronization with the other first guide mechanism, and the first guide mechanism is provided. A holding member fixed to one of the lower layer member and the upper layer member, a pulley rotatably held by the holding member, and a pulley fixed to the other of the lower layer member and the upper layer member. A contact member that contacts the outer peripheral surface of the Lee and rotates the pulley according to relative displacement in a direction substantially orthogonal to the longitudinal direction of the lower layer member and the upper layer member, and the synchronization transmission mechanism, the pulleys of each said first guide mechanism you characterized by having an interlocking belt rotatably coupled synchronously in the same direction.
In this case, when an operation load is input to the upper layer member, the pulley of one of the first guide mechanisms is held by the holding member and relatively displaced with respect to the other of the lower layer member and the upper layer member, and rotation according to the relative displacement occurs. A quantity is applied to the pulley through a corresponding abutment member. Thus, when the pulley of the first first guide mechanism rotates, the rotation is transmitted to the remaining pulleys of the first guide mechanism as synchronized rotation in the same direction through the interlocking belt. When the rotation is transmitted to the remaining pulley of the first guide mechanism, the rotation of the pulley displaces the abutting contact member in a direction substantially orthogonal to the longitudinal direction of the upper layer member. As a result, the operating load is input to the contact portions of all the first guide mechanisms at the same timing.
The pulley may be a pinion gear having meshing teeth on the outer peripheral surface thereof, and the contact member may be a rack gear meshing with the pinion gear.

  A chair according to the present invention is configured to include any one of the above armrests.

  According to the present invention, the synchronization transmission mechanism by the rotation transmission element that transmits the operation load input to one first guide mechanism in the direction substantially orthogonal to the longitudinal direction of the upper layer member in synchronization with the other first guide mechanism. Therefore, even if the operation load is input to any of the first guide mechanisms arranged apart from each other in the longitudinal direction, the operation load is applied to the remaining first guide mechanism at the same timing. You can Therefore, according to the present invention, the upper layer member can be smoothly displaced with respect to the lower layer member in a direction substantially orthogonal to the longitudinal direction even when an operation load is input to a portion of the upper layer member that is deviated in the longitudinal direction. it can.

It is a perspective view of the chair concerning one embodiment of the present invention. It is a perspective view of the chair concerning one embodiment of the present invention. It is a perspective view of the armrest which concerns on one Embodiment of this invention. It is sectional drawing which follows the IV-IV line of FIG. 3 of the armrest which concerns on one Embodiment of this invention. It is sectional drawing which follows the VV line of FIG. 4 of the armrest which concerns on one Embodiment of this invention. It is a disassembled side view of the armrest which concerns on one Embodiment of this invention. It is a perspective view of the support structure concerning one embodiment of the present invention. It is sectional drawing which follows the VIII-VIII line of FIG. 3 of the armrest which concerns on one Embodiment of this invention. It is the perspective view which removed some components of the armrest concerning one embodiment of the present invention. It is the perspective view which removed some components of the armrest concerning one embodiment of the present invention. It is sectional drawing which follows the XI-XI line of FIG. 8 of the armrest which concerns on one Embodiment of this invention. It is the perspective view which removed some components of the armrest concerning one embodiment of the present invention. It is a schematic plan view showing a synchronization transmission mechanism of an armrest according to another embodiment of the present invention.

Hereinafter, a chair according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a view of a chair 100 according to an embodiment of the present invention seen from above a side portion, and FIG. 2 is a view of a chair 100 according to one embodiment of the present invention seen from above a rear portion (back side). It is a figure.

As shown in FIGS. 1 and 2, the chair 100 includes a leg 1 installed on the floor surface F, a box-shaped support base 2 installed on the upper part of the leg 1, and an upper part of the support base 2. The mounted seat receiving member 3, a seat body 4 supported by the seat receiving member 3 so as to be slidable back and forth, on which a seated person sits, and a seated person who extends from the support base 2 to the upper rear portion of the seat body 4 and seated on the seat body 4. A backrest 7 that supports the back of the backrest, and a pair of armrests 8 that are attached near the extension of the backrest 7 from the support base 2 and that extend upward from the left and right sides of the seat body 4. There is.
In the following description, for convenience, the direction in which the seated person sitting on the seat body 4 faces forward is referred to as “front”, and the opposite direction is referred to as “rear”. Further, a direction connecting the floor surface F side on which the chair 100 is installed and the opposite side is referred to as “vertical direction”. Further, the width direction of the chair 100, that is, the horizontal direction orthogonal to the front-rear direction is referred to as the “width direction”. Further, in the figure, the front side is indicated by an arrow FR, the upper side is indicated by an arrow UP, and the left side in the width direction is indicated by an arrow LH.

The leg portion 1 has a multi-legged leg 11 with casters 11A, and a pedestal 12 which stands up from the central portion of the multi-legged leg 11 and has a gas spring (not shown) as an elevating mechanism built therein.
The outer cylinder 13 that constitutes the lower part of the pedestal 12 is non-rotatably fitted to and supported by the multi-leg 11. The inner cylinder 14 that constitutes the upper part of the pedestal 12 has the support base 2 fixed to the upper end to support the support base 2, and the lower part is supported by the outer cylinder 13 so as to be rotatable in the horizontal direction.
The support base 2 has a built-in lift adjustment mechanism for the pedestal 12 and a tilt adjustment mechanism for the backrest 7.

The seat receiving member 3 has four link arms (not shown) attached to the upper part of the support base 2 and a pair of left and right fixed frames (not shown) that connect the link arms.
The seat body 4 includes a seat frame 40 and a tension material 41 stretched around the seat frame 40. The upper surface of the upholstery member 41 is a load supporting surface that receives the load of the seated person.

The backrest 7 includes a back frame 70 and a tension material 71 stretched around the back frame 70. The front surface of the upholstery material 71 is a load supporting surface that receives the load of the seated person.
The back frame 70 has a back frame 70B whose lower end is connected to the support base 2 and a back front frame 80F provided in front of the back frame 70B.

The rear frame 70B has a pair of left and right lower side portions 72 and side side portions 73, and an upper side portion 74 connecting the left and right side side portions 73 to each other. The lower side portion 72, the side side portion 73, and the upper side portion 74 are integrally formed of, for example, a metal such as an aluminum alloy or a resin having a predetermined strength.
The left and right lower side portions 72 are connected to the tilt adjusting mechanism in the support base 2 and extend from the left and right sides of the rear portion of the support base 2 toward the rear side. The lower side 72 gradually inclines upward toward the rear. Further, armrests 8 to be described later, which are arranged laterally of the seat body 4, are attached to the side surfaces of the lower side portions 72 on the outer side in the chair width direction.
A side edge 73 is continuously formed at the rear end of each lower edge 72. The left and right side portions 73 are inclined outward in the chair width direction so that the width of separation between the side portions 73 gradually increases with increasing height.

  The armrests 8 are provided on the left and right sides of the chair 100 in the width direction, respectively. The armrests 8 that are installed on the left side of the chair 100 and those installed on the right side of the chair 100 are formed symmetrically. Therefore, hereinafter, the armrest 8 installed on the right side of the chair 100 will be described with reference to the drawings, and the description of the armrest 8 installed on the left side of the chair 100 will be omitted.

FIG. 3 is a view of the right armrest 8 as viewed from above inside the chair width direction, and FIG. 4 is a cross-sectional view of the right armrest 8 taken along the line IV-IV in FIG. . 5 is a view showing the right armrest 8 in a section along the line VV in FIG. 4, and FIG. 6 is a view of the right armrest 8 disassembled and seen from the inside in the chair width direction. Is.
The armrest 8 includes an L-shaped armrest support body 15 (support structure) in a front view that extends from the lower side portion 72 of the rear frame 70B to the outside in the chair width direction and then curves upward and an upper end portion of the armrest support body 15. And an armrest main body 16 supported by and extending in the front-rear direction.

  The armrest support 15 has a lower support 15A whose lower end is coupled to the lower side 72 of the rear frame 70B, and an elevating cylinder 15B which is externally slidably fitted in an upper region of the lower support 15A in a substantially vertical direction. Is equipped with. The elevating cylinder 15B is adjustable up and down with respect to the lower support column 15A fixed to the lower side portion 72 of the backrest 7.

  The armrest main body 16 is a member on which the seated person's elbows and arms are placed, and the upper part of the armrest support 15 is allowed to move back and forth, to the left and right, and to oscillate (rotate) in a substantially horizontal direction. It is installed in the condition

  The lower strut 15A is fixed to the strut base material 15A-1 that extends outward from the lower side portion 72 of the rear frame 70B in the chair width direction and then curves upward, and the upper end portion of the strut base material 15A-1 in a fitted state. And a support pipe 15A-2. The support base 15A-1 is formed of, for example, a solid metal member made of an aluminum alloy. The support pipe 15A-2 is formed of a metal pipe having a substantially elliptical cross section that is long in the front-rear direction. An inner sleeve 19 made of resin is attached to the inner surface of the column pipe 15A-2. The inner sleeve 19 is fixed to the support pipe 15A-2 by, for example, a snap fit.

  An upper portion of the elevating cylinder 15B is enlarged in a stepped shape, and a region below the enlarged portion is formed in a tubular shape having a substantially elliptical cross section. The elevating cylinder 15B is integrally formed of resin, for example. A support pipe 15A-2 is slidably fitted along the longitudinal direction inside the elliptical inner peripheral portion of the elevating cylinder 15B. An inner pipe 18 made of metal and having a substantially elliptical cross section is slidably fitted inside the inner sleeve 19 inside the elevating cylinder 15B. The upper end of the inner pipe 18 is fixed to the top plate 10, and the top plate 10 is fixed in a recess 15B-a provided on the upper surface of the elevating cylinder 15B. Therefore, the inner pipe 18 is fixedly installed in the elevating cylinder 15B via the top plate 10.

  The height adjustment slits 20 are formed on the left and right side walls of the inner sleeve 19 fixed in the support pipe 15A-2. The height adjusting slit 20 has an elevating guide slit 20a extending in the axial direction (generally vertical direction) of the inner sleeve 19 and a plurality of locking slits 20b extending forward from the elevating guide slit 20a. The plurality of locking slits 20b are formed at substantially equal intervals in the axial direction (substantially vertical direction) of the inner sleeve 19.

  In the regions near the lower ends of the left and right side walls of the inner pipe 18, there are formed pin moving holes 22 each having a long hole extending in the front-rear direction. The left and right pin moving holes 22 hold a locking pin 21 that can be locked in one of the locking slits 20b of the height adjusting slit 20 of the inner sleeve 19. Both ends of the locking pin 21 project laterally from the left and right pin moving holes 22 of the inner pipe 18, and the left and right ends projecting from the pin moving hole 22 are locking slits of one of the height adjusting slits 20. It can be locked with 20b. Both sides of the locking pin 21 are held in the left and right pin moving holes 22 so as to be movable back and forth.

When the locking pin 21 moves to the front end side of the pin moving hole 22, both ends are locked in one of the locking slits 20 b of the height adjusting slit 20. At this time, the elevating cylinder 15B and the inner pipe 18 which are integrated with the armrest main body 16 side are locked to one of the locking slits 20b of the height adjusting slit 20 via the locking pin 21, so that the armrest The lifting and lowering of the main body 16 is locked. In this armrest 8, the fixing height of the armrest main body 16 can be adjusted in multiple stages by changing any of the locking slits 20b that lock the locking pin 21.
Further, when the locking pin 21 moves to the rear end side of the pin moving hole 22, the locking by the locking slit 20b is released and reaches the inside of the elevating guide slit 20a. At this time, the lifting lock of the armrest body 16 is released, and the armrest body 16 can be freely raised and lowered.

  Support shafts 17 extending substantially along the chair width direction are held in regions of the left and right side walls of the inner pipe 18 near the upper portions. A swing lever 23 arranged in the inner pipe 18 is rotatably supported on the support shaft 17. The swing lever 23 has an upper extending portion 23u extending upward from the shaft supporting portion of the support shaft 17 and a lower extending portion 23l extending below the shaft supporting portion. An engagement pin 26 that slidably engages with a rear lower engagement groove 25 of an elevating operation lever 24, which will be described later, is held at an upper end portion of the upper extension portion 23u. A pin holding portion 27 that holds the locking pin 21 is provided at the lower edge portion of the downward extending portion 23l. Below the pin holding portion 27 of the downward extending portion 23l, a spring piece 28 that extends downward from the pin holding portion 27 and then curves upward in an arc shape from the rear portion of the lower end is provided.

  The top plate 10 fixed to the upper end portion of the inner pipe 18 projects largely around the inner pipe 18 in plan view, particularly in the front-back direction. Below the projecting portion on the front side of the top plate 10, a pivot shaft 24 a of an elevating operation lever 24 for operating the swing lever 23 is arranged. A pivot 24a of the lifting operation lever 24 is rotatably supported on a side wall on the upper side of the lifting cylinder 15B. The elevating operation lever 24 has the above-mentioned pivot 24a, a front extension 24f extending forward of the pivot 24a, and a rear extension 24b extending rearward of the pivot 24a. An operation portion 24c is provided at a lower front portion of the front extension portion 24f so as to project to the outside of the upper end portion of the elevating cylinder 15B so that the user can push it upward. The rear lower engaging groove 25 that engages with the engaging pin 26 at the upper end of the swing lever 23 is provided on the lower side of the rear end of the rear extending portion 24b.

  The swing lever 23 has a lower end portion when the rear upper end of the spring piece 28 comes into contact with the inner wall of the inner pipe 18 from the front (including the case where the spring piece 28 comes into contact with the inner cable 18 through the operation cable 34). It is biased to move forward. At this time, the locking pin 21 moves to the front end of the pin moving hole 22 and engages with one of the locking slits 20 b of the height adjusting slit 20. When the lower end portion of the swing lever 23 is biased forward, the upper end portion of the swing lever 23 is displaced rearward, and the rear end portion of the rear extension portion 24b of the elevating operation lever 24 is displaced upward, The operating portion 24c is projected to the outside of the upper end portion of the elevating cylinder 15B. When the operating portion 24c is pushed upward by the operator, the rear end portion of the elevating operation lever 24 displaces the upper end portion of the swing lever 23 forward, and the lower end portion of the swing lever 23 is biased by the spring piece 28. Displace backwards against. Then, the locking pin 21 moves to the rear end of the pin moving hole 22, releases the engagement with the locking slit 20b of the height adjusting slit 20 and reaches the inside of the elevating guide slit 20a, and the armrest main body 16 moves freely. Enables easy lifting and lowering operations.

  An end plate 29 is attached to the upper surface of the lifting cylinder 15B so as to form the upper end surface of the lifting cylinder 15B. A part of the lower surface side of the end plate 29 is inserted into the concave portion 15B-a, and is fixed together with the elevating cylinder 15B in a state of being overlapped with the upper surface of the top plate 10.

7: is the figure which looked at the raising / lowering cylinder 15B which the end plate 29 was attached to the upper part from the diagonally upper direction inside the chair width direction, and FIG. 8 shows the armrest main body 16 along the VIII-VIII line of FIG. It is the figure shown in section.
As shown in FIG. 7, a bulging portion 30 having a short-axis columnar shape and a small-diameter portion 31 having a smaller outer diameter than the bulging portion 30 and having a short-axis columnar shape are projected substantially at the center of the end plate 29 in a plan view. It is set up. The small diameter portion 31 is provided on the upper surface of the bulging portion 30 so as to project in a stepped manner, and the bulging portion 30 and the small diameter portion 31 are formed so that the axes o of both of them coincide. In this embodiment, the bulging portion 30 and the small diameter portion 31 form a pivot portion. The armrest body 16 is rotatably supported on the small diameter portion 31 of the end plate 29 and the bulging portion 30. As shown in FIG. 8, the armrest main body 16 includes a lower unit 16L mounted on the end plate 29, and an upper unit 16U mounted on the lower unit 16L.

FIG. 9 is a view of the armrest 8 from which the cover member 37 of the lower unit 16L has been removed, as viewed from diagonally above the inside in the chair width direction.
The lower unit 16L forms a storage space s whose upper side is open, and a base member 32 placed on the end plate 29 with the small diameter portion 31 protruding into the storage space s and the storage space s in the storage space s. The base member 32 is engaged with the base member 32 in a relatively non-rotatable manner and relatively movable (slidingly) in only one direction, and rotatable with the small diameter portion 31 and the bulging portion 30 via a bearing portion 33a. Before the winding block 33 supported by the operation lever, the operation lever 35 for remotely operating the mechanism in the support base 2 via the operation cable 34, and the inner cable 34i of the operation cable 34 are wound in the lower unit 16L. A pulley 36f, a rear pulley 36r, and a cover member 37 that closes the upper opening of the accommodation space s are provided.

  The base member 32 has side walls 32s extending substantially along the front-rear direction on the left and right of a substantially rectangular bottom wall long in the front-rear direction. A front step portion 32a that rotatably supports the operation lever 35 is formed on the front side of the base member 32 so as to bulge upward. The bottom wall of the base member 32 is formed with an elongated hole-like insertion hole 38 through which the bulging portion 30 and the small diameter portion 31 of the end plate 29 are inserted upward.

The sandwiching block 33 is formed in a flat rectangular parallelepiped shape that suppresses the height in the vertical direction (the direction along the axis o of the small diameter portion 31 and the bulging portion 30). In the holding block 33, the bearing portion 33a is rotatably fitted to the small diameter portion 31 and the bulging portion 30 of the end plate 29 penetrating upward through the insertion hole 38 of the base member 32, and in that state the washer 63 and It is secured to the end plate 29 via a bolt 62. In this state, the holding block 33 has its left and right end surfaces slidingly contacting the inner surfaces of the left and right side walls 32s of the base member 32 automatically.
In the present embodiment, the left and right end surfaces of the holding block 33 and the inner surface of the side wall 32s of the base member 32 constitute a guide mechanism that allows only a substantially horizontal relative displacement between the holding block 33 and the base member 32. ing. Further, the small-diameter portion 31 and the bulge portion 30 of the end plate 29 and the bearing portion 33a of the sandwiching block 33 enable the armrest main body 16 to rotate in a substantially horizontal direction with respect to the armrest support body 15 (support structure). Constitutes a rotating mechanism connected to the.

FIG. 10 is a perspective view showing a state where only the holding block 33 on the armrest main body 16 side is assembled on the upper part of the armrest support 15, and FIG. 11 is a cross-sectional view of the armrest 8 taken along the line XI-XI of FIG. FIG.
A cable is inserted through the end plate 29 from the inside of the armrest support 15 (support structure) below the axis o of the small diameter portion 31 to guide the operation cable 34 from the vicinity of the small diameter portion 31 into the inside of the armrest main body 16. It has a part 57. The cable insertion portion 57 is a continuation extending from the lower surface on the rear side of the axis o of the small diameter portion 31 of the end plate 29 to the upper surface on the front side of the axis o of the small diameter portion 31 of the end plate 29 and the front surface of the bulging portion 30. It is composed of holes. The front portion of the bulging portion 30 is flatly cut out in a part of the arc surface, and the opening 57a of the cable insertion portion 57 facing the inside of the armrest body 16 is flat on the front side of the bulging portion 30. It is formed straddling the surface and the upper surface of the end plate 29 on the front side thereof.

Further, the end plate 29, and the sandwiching block 33 that is rotatably connected to the small diameter part 31 of the end plate 29 and the upper part of the bulging part 30 are provided with a rotation restricting mechanism that restricts a relative rotation angle between the two. Has been. This rotation restricting mechanism is a substantially fan-shaped rotation allowance formed on the rear side of the bulging portion 30 of the end plate 29 (the side opposite to the opening 57a of the cable insertion portion 57 with the axis o of the small diameter portion 31 interposed therebetween). It has side walls 58 s on the left and right of the hole 58, and a substantially fan-shaped displacement regulation projection 59 that projects downward from the holding block 33 and is inserted into the rotation allowance hole 58.
In the present embodiment, the left and right side walls 58s of the rotation allowance hole 58 formed in the end plate 29 constitute a rotation restricting element on the support structure side of the rotation restricting mechanism, and the displacement protruding from the sandwiching block 33 is provided. The restriction protrusion 59 constitutes a rotation restriction element on the armrest body 16 side of the rotation restriction mechanism. The left and right side walls 58s of the rotation allowance hole 58 that constitutes the rotation restricting element on the support structure side, and the displacement regulating projections 59 that configure the rotation restricting element on the armrest body 16 side are the armrest support body 15 that is the support structure. Is located inside.

  Here, the displacement regulating projection 59 provided on the sandwiching block 33 penetrates through the insertion hole 38 of the bottom wall of the base member 32 arranged between the sandwiching block 33 and the end plate 29 from above to below, and in that state. It projects into the rotation allowance hole 58 on the end plate 29. The insertion hole 38 in the bottom wall of the base member 32 is a long hole-shaped hole that allows the bulging portion 30 and the small diameter portion 31 of the end plate 29 to project above the base member 32, but in the present embodiment, the same insertion hole. The hole 38 is also used as a hole for allowing the displacement regulating projection 59 to project below the base member 32.

  The operation lever 35 is formed in an L shape in a side view. The operating lever 35 extends in the left-right direction and is rotatably supported on the front step portion 32a of the base member 32, a downward extending portion 35l extending downward from the supporting shaft 35a, and a downward extending portion. And a front extension portion 35f extending forward from the lower end of the extension portion 35l. The operation lever 35 is swingable around a support shaft 35a in a swing space inside the front step portion 32a. The front portion of the front extension portion 35f is an operation portion 35c that projects forward from the lower portion of the front step portion 32a. The operation portion 35c is located below the front portion of the upper unit 16U of the armrest body 16. The operation unit 35c is operable by a user who put his / her arm on the upper unit 16U so as to pull it up with his / her fingertip.

A front pulley 36f is rotatably supported at the lower end of the downward extension portion 35l of the operation lever 35 via a support shaft 39 extending in the left-right direction. The front pulley 36f moves forward and upward with the rotation of the downward extension portion 35l when the downward extension portion 35l rotates forward and upward due to the pulling up operation of the operation portion 35c of the operation lever 35.
The rear pulley 36r is rotatably supported by the rear end portion of the bottom wall of the base member 32 via a support shaft 42 extending in the vertical direction.

The operation cable 34 includes an outer cable 34o and an inner cable 34i. The operation cable 34 extends from the support base 2 through the inside of the armrest support 15 and reaches inside the lower unit 16L of the armrest main body 16. The outer cable 34o of the operation cable 34 has a tip end locked to an outer cable locking portion 33b formed in the holding block 33. The inner cable 34i of the operation cable 34 extends forward from the tip of the outer cable 34o, is then wound around the front pulley 36f from below to above, and is folded back to the rear. The inner cable 34i is folded back from the front pulley 36f and wound around the rear pulley 36r from one side in the width direction to the other side (in the drawing, from the inside to the outside in the width direction) and is folded back to the front side. The inner cable 34i is folded back to the front side by the rear pulley 36r, and then the front end thereof is locked to the widthwise outer side of the rear end of the sandwiching block 33.
In the above configuration, when the operation portion 35c of the operation lever 35 is pulled up, the front pulley 36f moves forward and upward, pulls out the inner cable 34i, and operates the mechanism in the support base 2.

  Here, the front pulley 34f also moves in the front-rear direction when the armrest main body 16 is moved in the front-rear direction, but at this time, the front pulley 34f also moves in the front-rear direction in front of the tip end portion of the outer cable 34o. Then, the rear pulley 36r moves back and forth behind the tip of the inner cable 34i. Therefore, even if the length of the inner cable 34i in front of the tip of the outer cable 34o increases or decreases, the length of the inner cable 34i in the rear of the tip of the inner cable 34i decreases or increases by the same amount. For this reason, the change in the pull-out length of the inner cable 34i is suppressed, and it is prevented that the inner cable 34i is pulled when the armrest main body 16 moves forward and the inner cable 34i loosens when the armrest main body 16 moves rearward.

  A front support block 43F and a rear support block 43R are provided so as to project upward in the front region and the upper region of the cover member 37 of the lower unit 16L. The upper portions of the front support block 43F and the rear support block 43R respectively project into the upper unit 16U of the armrest body 16.

  The upper unit 16U covers the upper base member 44 arranged on the cover member 37 of the lower unit 16L, the upper cover member 45 overlapping the upper base member 44 with the accommodation space su open, and the upper cover member 45 from above. The pad member 46 and a cushion member 65 made of urethane or the like are provided between the upper cover member 45 and the pad member 46. The upper unit 16U has a gentle curved shape that is convex upward in a side view, the front portion inclines downward to the front, and the rear portion inclines downward to the rear.

FIG. 12 is a view of the armrest 8 viewed from above inside the chair width direction with the upper cover member 45, the cushion member 65, and the pad member 46 of the upper unit 16U removed.
As shown in FIGS. 8 and 12, the accommodation space su of the upper unit 16U is provided with a synchronization transmission mechanism 47, which will be described in detail later, for moving the upper unit 16U of the armrest main body 16 which is long in the front-rear direction in parallel. There is.
When the upper unit 16U, which is long in the front-rear direction, is moved in the left-right direction, an operation performed by gripping one of the front and rear end portions of the upper unit 16U causes an inclination in the plan view of the upper unit 16U, which hinders smooth horizontal movement. In some cases, the armrest body 16 may unintentionally rotate around the small diameter portion 31. On the other hand, by equalizing the left and right movement of the front and rear end portions of the upper unit 16U by the synchronization transmission mechanism 47, the horizontal movement of the upper unit 16U can be assisted.

Insertion holes 48F and 48R extending in the left-right direction are formed in the front side region and the rear side region of the bottom wall of the upper base member 44. As shown in FIG. 8, a front support block 43F and a rear support block 43R projecting from the lower unit 16L are inserted through the insertion holes 48F and 48R from below. Bearing blocks 49F and 49R (holding members) are fixed to the front support block 43F and the rear support block 43R that protrude upward through the insertion holes 48F and 48R, respectively.
As shown in FIG. 9, the front support block 43F is integrally formed with each of the rear portions of the left and right bearing portions 32a-1 that support the support shaft 35a of the operation lever 35. Screw holes 32a-2 are formed on the upper surfaces of the left and right front support blocks 43F. The front bearing blocks 49F are superposed on the upper surfaces of the left and right front support blocks 43F and screwed into the screw holes 32a-2 of the left and right front support blocks 43.
The front and rear end portions of a rotary shaft 50 extending in the front-rear direction (along the longitudinal direction of the upper base member 44) are rotatably held by the front and rear bearing blocks 49F, 49R. In the vicinity of the bearing block 49F on the front side of the rotary shaft 50, a pinion gear 51F, which is a form of a pulley, is integrally provided. Similarly, in the vicinity of the bearing block 49R on the rear side of the rotary shaft 50, a similar pinion gear 51R, which is a form of a pulley, is integrally provided.

On the other hand, rack gears 52F and 52R meshing with the pinion gears 51F and 51R are fixedly installed at positions corresponding to the front and rear pinion gears 51F and 51R on the upper base member 44. The tooth surfaces of the front and rear rack gears 52F, 52R are formed along the front-rear direction, and the tooth surfaces of the corresponding pinion gears 51F, 51R are also formed along the front-rear direction. The number of teeth and the pitch of the front pinion gear 51F are set to be the same as the number of teeth and the pitch of the rear pinion gear 51R.
In the case of the present embodiment, the pair of front and rear pinion gears 51F and 51R and rack gears 52F and 52R mesh with each other to be substantially orthogonal to the longitudinal direction of the upper unit 16U (upper layer member) with respect to the lower unit 16L (lower layer member). It constitutes a first guide mechanism for guiding the displacement in the direction.

Here, when an operation load in the left-right direction is biased to either the front or the rear of the upper unit 16U, the corresponding pinion gear 51F or 51R is rotated in the direction corresponding to the operation direction through the front or rear rack gear 52F or 52R. The force is transmitted, and the rotational force is transmitted to the other pinion gear 51R or 51F through the rotation shaft 50 that is a rotation transmission element. Then, the rack gear 52R or 52F meshing with the other pinion gear 51R or 51F is displaced by the same amount in the same direction in synchronization with the displacement of the one rack gear 52F or 52R. Therefore, the upper unit 16U is displaced by the same amount in the same direction in the front-rear direction with respect to the lower unit 16L.
In the case of the present embodiment, the rotary shaft 50 interlocks the operation of the pair of front and rear pinion gears 51F and 51R and the rack gears 52F and 52R, and is substantially orthogonal to the longitudinal direction input to one of the front and rear rack gears 52F or 52R. A rotation transmission element of the synchronization transmission mechanism 47 that transmits the operation load in the direction in synchronization with the other rack gear 52R or 52F is configured.

  In addition, in the case of the present embodiment, upwardly protruding protrusions 53F and 53R are provided on the front side of the front insertion hole 48F of the upper base member 44 and on the rear side of the rear insertion hole 48R, and the protrusions thereof are provided. Guide grooves 53F-a and 53R-a that open upward are formed in 53F and 53R. The guide grooves 53F-a and 53R-a are formed along the left-right direction (along the direction substantially orthogonal to the longitudinal direction of the upper base member 44). On the other hand, the front bearing block 49F and the rear bearing block 49R are provided with guide protrusions 54F and 54R that are slidably inserted into the front and rear guide grooves 53F-a and 53R-a. In the case of the present embodiment, the lower unit 16L is provided not only by the first guide mechanism by the pinion gears 51F, 51R and the rack gears 52F, 52R but also by the second guide mechanism by the guide protrusions 54F, 54R and the guide grooves 53F-a, 53R-a. It guides the relative displacement of the upper unit 16U in the left-right direction.

A large-diameter portion 55 having an outer diameter larger than that of other front and rear portions is integrally provided at a substantially intermediate position in the axial direction of the rotary shaft 50. On the other hand, at the approximately middle position in the longitudinal direction of the upper surface of the upper base member 44, the rotary shaft 50 is located at an arbitrary relative position in the left-right direction (in a direction substantially orthogonal to the longitudinal direction) between the lower unit 16L and the upper unit 16U. A plurality of recesses 56 (holding portions) capable of elastically holding the large diameter portion 55 are formed. By fitting the concave portion 56 into the large-diameter portion 55 of the rotary shaft 50, it is possible to impart a holding resistance to the rotary shaft 50 and thus give a feeling of moderation to the operator of the upper unit 16U. In addition, in the present embodiment, the plurality of recesses 56 are formed of a resin member having elasticity.
Further, in the present embodiment, a plurality of recesses 56 (holding portions) capable of elastically holding the large diameter portion 55 of the rotating shaft 50 are formed on the upper surface of the upper base member 44. As indicated by the line, a holding member 60 is provided on the lower surface of the upper cover member 45, and the holding member 60 is provided with a plurality of holding grooves 60a capable of elastically holding the large diameter portion 55 of the rotating shaft 50. You can

In this embodiment, the pinion gears 51F and 51R and the rack gears 52F and 52R are used as the abutment members and the pulleys that form the first guide mechanism, but the pulleys and the abutment members have tooth surfaces that mesh with each other. It is also possible to use a frictional resistance-only abutting member so as to be able to transmit power without having a gear.
Further, in the present embodiment, the front and rear end portions of the rotary shaft 50 are held by the front and rear bearing blocks 49F and 49R, and the pinion gears 51F and 51R are provided on the outer peripheral surface of the rotary shaft 50 near the front and the outer peripheral surface of the rear. Although the (pulley) is integrally formed, the front and rear pinion gears (pulleys) are individually supported by the corresponding bearing blocks, and the front and rear pinion gears (pulleys) are linked so that they can be interlocked by separate rotating shafts. May be.

  In the armrest 8 according to the present embodiment, when the upper unit 16U of the armrest main body 16 is gripped by a seated person and an operation load in the front-rear direction, the left-right direction, and the swinging direction (rotating direction) is applied to the upper unit 16U. The parts inside the armrest 8 operate as follows.

  When an operation load in the front-rear direction is applied to the upper unit 16U, the lower unit 16L of the armrest main body 16 moves in the front-rear direction together with the upper unit 16U with respect to the holding block 33 supported by the small diameter portion 31 on the armrest support 15 side. Is displaced to. At this time, the left and right side walls 32s of the base member 32 of the lower unit 16L slide on the left and right end surfaces of the holding block 33, so that the displacement of the lower unit 16L in the front-rear direction is guided.

  When an operation load in the left-right direction is applied to the upper unit 16U, the upper unit 16L is supported by the upper portion of the small diameter portion 31 of the armrest support 15 and the bulging portion 30 via the sandwiching block 33. 16U is displaced left and right. At this time, the upper unit 16U is guided in the left-right direction by the guide mechanism described above with respect to the lower unit 16L, and the front-side and rear-side movements of the upper unit 16U are equalized via the synchronization transmission mechanism 47. It

When an operation load in the horizontal rotation direction is applied to the upper unit 16U, the holding block 33 rotates with the bearing portion 33a with respect to the small diameter portion 31 and the bulging portion 30 on the armrest support 15 side, and Along with this, the base member 32 of the lower unit 16L, which is non-rotatably engaged with the sandwiching block 33, rotates integrally with the sandwiching block 33. As a result, the upper unit 16U supported by the lower unit 16L also rotates in the same direction.
Further, when the lower unit 16L is rotated by a predetermined angle or more, the displacement regulating projection 59 protruding from the holding block 33 into the rotation allowance hole 58 of the end plate 29 is provided on one of the side walls 58s in the rotation allowance hole 58. The armrest body 16 is brought into contact with the armrest body 16, and thereby the rotation of the armrest body 16 is restricted.

As described above, the armrest 8 according to the present embodiment applies the operation load in the direction substantially orthogonal to the longitudinal direction of the upper unit 16U, which is input to one of the front and rear first guide mechanisms (pinion gear and rack gear), to the other first guide mechanism. A 1-guide mechanism (a pinion gear and a rack gear) is provided with a synchronization transmission mechanism 47 by a rotation transmission element that transmits in synchronization. Therefore, even when the operation load is input to any of the first guide mechanisms before and after the upper unit 16U, the operation load in the same direction can be applied to the remaining first guide mechanism at the same timing.
Therefore, in the armrest 8 according to the present embodiment, the upper unit 16U can be smoothly displaced in the left-right direction even when the operation load in the left-right direction is biased to either the front or the rear of the upper unit 16U. .
Further, in the armrest 8 according to the present embodiment, since the synchronization transmission mechanism 47 by the rotation transmission element using the rotation shaft 50 is adopted, the bending force or the biasing force biased inside the synchronization transmission mechanism 47 or the first guide mechanism is applied. Is less likely to occur.

  Further, in the armrest 8 according to the present embodiment, the first guide mechanism includes the bearing blocks 49F and 49R which are holding members fixed to the lower unit 16L and the pulleys rotatably held by the bearing blocks 49F and 49R. It has certain pinion gears 51F and 51R and rack gears 52F and 52R that are fixed to the upper unit 16U and are abutting members that come into contact with the outer peripheral surfaces of the pinion gears 51F and 51R. The front and rear rack gears 52F and 52R are rotated by the rotary shaft 50. It is linked so that it can be linked. Therefore, even with a simple configuration, the operation load in the left-right direction input to the upper unit 16U can be transmitted back and forth at the same timing.

  Further, in the armrest 8 according to the present embodiment, the rotation shaft 50 that constitutes the rotation transmission element of the synchronization transmission mechanism 47 is formed integrally with the shafts of the front and rear pulleys (pinion gears 51F and 51R). Therefore, the pulleys of the front and rear first guide mechanisms and the synchronization transmission mechanism 47 can be made into a simple structure with a small number of parts, and the product cost can be reduced.

  Further, when the pulley and the contact member of the first guide mechanism are configured by the pinion gears 51F and 51R and the rack gears 52F and 52R as in the present embodiment, slippage between the pulley and the contact member is eliminated. In addition, the tilting of the pulley with respect to the contact member can be suppressed. Therefore, in the armrest 8 according to the present embodiment, the front and rear first guide mechanisms can be reliably synchronized without rattling.

  Further, in the armrest 8 according to the present embodiment, between the lower unit 16L and the upper unit 16U, apart from the first guide mechanism, the guide protrusions 54F projectingly provided on the front and rear bearing blocks 49F, 49R (holding members). , 54R and guide grooves 53F-a, 53R-a that abut the guide protrusions 54F, 54R. Therefore, the front and rear bearing blocks 49F and 49R holding the pinion gears 51F and 51R can be stably guided in the direction substantially orthogonal to the longitudinal direction.

  Further, in the armrest 8 according to the present embodiment, the rotation shaft 50 of the lower unit 16L and the upper unit 16U is disposed at an arbitrary relative position in the direction substantially orthogonal to the longitudinal direction of the lower unit 16L and the upper unit 16U. A plurality of recesses 56 that elastically retain the large diameter portion 55 are provided. Therefore, when the upper unit 16U is displaced in the direction substantially orthogonal to the longitudinal direction, the holding resistance of the concave portion 56 can give the operator a sense of moderation. Further, the same effect can be obtained when a plurality of holding grooves 60a that elastically holds the large diameter portion 55 of the rotating shaft 50 are formed on the upper cover member 45 side of the upper unit 16U.

Next, another embodiment of the present invention shown in FIG. 13 will be described.
FIG. 13 is a diagram when the armrest 108 is viewed from above with the upper cover member and the pad member removed.
Insertion holes 61F and 61R extending in the left-right direction are formed in the front region and the rear region of the upper base member 44 on the upper unit 116U side. Shafts 62F and 62R protruding upward are fixed to the lower unit (not shown), and the shafts 62F and 62R project above the upper base member 44 through front and rear insertion holes 61F and 61R. ing.

Pinion gears 151F and 151R, which are one form of pulleys, are fixed to the shaft portions 62F and 62R protruding above the upper base member 44. Rack gears 152F and 152R meshing with the front and rear pinion gears 151F and 151R are fixed to the front side region of the insertion hole 61F and the rear side region of the insertion hole 61R on the upper surface of the upper base member 44.
On the upper portions of the front and rear pinion gears 151F and 151R, annular belt engaging portions 151F-a and 151R-a are integrally provided. The interlocking belt 64 that is half-twisted so as to intersect at the center is wound around the belt engaging portions 151F-a and 151R-a of the front and rear pinion gears 151F and 151R.
In the present embodiment, the pair of the front pinion gear 151F and the rack gear 152F and the pair of the rear pinion gear 151R and the rack gear 152R configure the first guide mechanism, and the interlocking belt 64 configures the rotation transmission element of the synchronization transmission mechanism 147. I am configuring.

In the case of the armrest 108 of the present embodiment, when an operating load in the left-right direction is biased to one side in the front-rear direction of the upper unit 116, the pinion gear 151F or 151R on the same side according to the left-right displacement of one rack gear 152F or 152R. Rotates, and the rotation is transmitted to the other pinion gear 151R or 151F as rotation in the opposite direction via the interlocking belt 64. Thus, when the other pinion gear 151R or 151F rotates in the opposite direction, the other rack gear 152R or 152F meshing with the other pinion gear 151R or 151F is displaced by the same amount in the same direction as the one rack gear 152F or 152R.
Also in the case of the armrest 108 of the present embodiment, it is possible to obtain substantially the same basic effect as that of the above embodiment.

  The present invention is not limited to the above-described embodiment, and various design changes can be made without departing from the scope of the invention. For example, in the other embodiment described above, the pinion gear and the rack gear that mesh with each other constitute the first guide mechanism, but these are pulleys without tooth surfaces that are engaged so that power can be transmitted only by engaging friction. And a contact member.

8,108 Armrest 16L Lower unit (lower layer member)
16U upper unit (upper layer member)
47,147 Synchronous transmission mechanism 49F, 49R Bearing block (holding member)
50 rotating shaft 51F, 51R, 151F, 151R pinion gear (pulley, first guide mechanism)
52F, 52R, 152F, 152R Rack gear (contact member, first guide mechanism)
53F-a, 53R-a guide groove (second guide mechanism)
54F, 54R guide protrusion (second guide mechanism)
56 Recessed part (holding part)
64 interlocking belt 100 chair

Claims (8)

An upper layer member elongated in one direction,
A lower layer member that is disposed below the upper layer member and supports the upper layer member,
A plurality of first members arranged at a plurality of locations between the lower layer member and the upper layer member that are separated from each other in the longitudinal direction of the upper layer member, and that guide displacement of the upper layer member in a direction substantially orthogonal to the longitudinal direction with respect to the lower layer member. A guide mechanism,
A synchronous transmission mechanism by a rotation transmission element that transmits the operation load, which is input to one of the first guide mechanisms, in a direction substantially orthogonal to the longitudinal direction of the upper layer member, in synchronization with the other first guide mechanism. Prepare ,
The first guide mechanism,
A holding member fixed to any one of the lower layer member and the upper layer member,
A pulley rotatably held by the holding member,
The pulley is fixed to the other of the lower layer member and the upper layer member, contacts the outer peripheral surface of the pulley, and moves the pulley in accordance with relative displacement in a direction substantially orthogonal to the longitudinal direction of the lower layer member and the upper layer member. A contact member for rotating,
The armrest characterized in that the synchronization transmission mechanism has a rotation shaft that connects the pulleys of each of the first guide mechanisms so as to be rotatable in synchronization . The armrest according to claim 1 , wherein the rotating shaft is formed integrally with a shaft of each of the pulleys. The pulley is a pinion gear having meshing teeth on the outer peripheral surface,
The armrest according to claim 1 or 2 , wherein the contact member is a rack gear that meshes with the pinion gear. The holding member has a guide protrusion,
The other of the lower layer member and the upper layer member has a guide groove that slidably contacts the guide protrusion,
The guide and the protrusion and the guide groove, of claims 1 to 3, characterized in that it constitutes the second guide mechanism for guiding the longitudinal direction substantially the direction of displacement perpendicular to the upper member with respect to the lower member The armrest described in any one of items. The other of the lower layer member and the upper layer member has a plurality of holding portions that elastically hold the rotation shaft at an arbitrary relative position in a direction substantially orthogonal to the longitudinal direction of the lower layer member and the upper layer member. The armrest according to any one of claims 1 to 4 , characterized in that the armrest is provided. An upper layer member elongated in one direction,
A lower layer member that is disposed below the upper layer member and supports the upper layer member,
A plurality of first members arranged at a plurality of locations between the lower layer member and the upper layer member that are separated from each other in the longitudinal direction of the upper layer member, and that guide displacement of the upper layer member in a direction substantially orthogonal to the longitudinal direction with respect to the lower layer member. A guide mechanism,
A synchronous transmission mechanism by a rotation transmission element that transmits the operation load, which is input to one of the first guide mechanisms, in a direction substantially orthogonal to the longitudinal direction of the upper layer member, in synchronization with the other first guide mechanism. Prepare,
The first guide mechanism,
A holding member fixed to any one of the lower layer member and the upper layer member,
A pulley rotatably held by the holding member,
The pulley is fixed to the other of the lower layer member and the upper layer member, contacts the outer peripheral surface of the pulley, and moves the pulley in accordance with relative displacement in a direction substantially orthogonal to the longitudinal direction of the lower layer member and the upper layer member. A contact member for rotating,
The synchronous transmission mechanism, elbow hook you characterized by having an interlocking belt the pulley rotatably coupled synchronously in the same direction of each of said first guide mechanism. The pulley is a pinion gear having meshing teeth on the outer peripheral surface,
The armrest according to claim 6 , wherein the contact member is a rack gear that meshes with the pinion gear. Chair characterized in that it comprises a armrest according to any one of claims 1-7.

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