JP2013103067A - Chair - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lever device for a chair which can be simply assembled and easily finely adjusted.SOLUTION: The lever device 23 for locking is provided with a seat outer shell 10 as well. The lever device 23 for locking has a turning type lever 25, and the lever 25 has a bag-like part 31 opened toward the seat outer shell 10. The bag-like part 31 is disposed with a lever member 29, and one end of a cable 28 is locked with the lever member 29 through a ball 28a. The bag-like part 31 and the lever member 29 are fitted to each other, and are integrally turned. The lever 25 is supported by the seat outer shell 10 so that it is turned by using a turning supporting part 32 as a supporting point. In addition, the lever 25 is provided with a regulating part 33 which is concentric with the turning supporting part 32, and the regulating part is covered by a dislocation stopping member 26 from the upper part. The dislocation stopping member 26 is mounted on the seat outer shell 10 by an engaging nail 49.

Description

  The present invention relates to a chair provided with a lever device for operating an adjusting member such as a gas cylinder, such as a lever device used in a locking adjusting device, and more particularly, a cable by rotating the lever. The present invention relates to a chair having a lever device of a method of pulling (wire).

  As a lever device of a chair, there is a method of pulling a cable by rotating the lever. In this type of lever device, the lever is generally connected to a support with a pin as shown in Patent Document 1, for example. However, this not only takes time to insert the pin, but it may be difficult to form the pin hole depending on the location, so the design may be troublesome. On the other hand, Patent Document 2, which is an application of the present applicant, discloses that a support shaft is provided integrally with a lever, and the support shaft is pressed and held by a pressing member.

JP 2008-229206 A JP 2010-125061 A

  In Patent Document 2, there is no need to insert a pin, and it is only necessary to attach the pressing portion after setting the lever on the support (seat outer shell), so that there is an advantage that the design freedom can be improved. On the other hand, since the pressing member is fixed with screws, there is still room for improvement in terms of assembly workability and member management.

  The present invention has been made to improve such a current situation, and an object thereof is to provide a chair having an improved lever device. Further, the present invention can also provide an object including many improved configurations.

  The present invention specifies the configuration in each claim. Of these, the invention according to claim 1 is a configuration in which one end of a cable for operating a gas cylinder or another member is pulled by a turning operation of a lever rotatably held by a support body. Has a rotation support part that fits freely in a receiving part provided in the support body, and a finger-hanging part that is operated by a person to apply a finger.

  Further, the supporting member is attached with a retaining member that covers the rotation supporting portion of the lever or the regulating portion formed concentrically therewith from the side opposite to the receiving portion, and the retaining member and One of the supports is provided with an engaging claw that elastically deforms and then returns when the retaining member is pressed against the support, and the other is engaged with the engaging claw. Thus, an engagement portion is provided that holds the retaining member from the support so as not to be detached.

  According to a second aspect of the present invention, in the first aspect, the lever includes a bag-shaped portion that opens toward the support, and the lever that can rotate integrally with the lever is provided inside the bag-shaped portion. A member is disposed, and one end of the cable is locked to the lever member.

  Further, the invention of claim 3 is the invention according to claim 1 or 2, wherein the retaining member has a gate shape having a pair of feet so as to straddle the cable, and the engaging claw is provided on the left and right feet. And an engaging portion is provided on the support.

  In the present invention, since the retaining member is attached to the support body by being caught by the engaging claw and the engaging portion, the retaining member can be attached with one touch, and a fastener such as a screw is unnecessary, so that the member management is performed. Can be reduced.

  Now, the cable is inserted through the tube, and one end of the tube must be held on the support so that it cannot be displaced. For this reason, if one end of the cable is locked to the lever, the one end of the tube is set to the support while the lever is set to the support while maintaining the state where the one end of the cable is locked to the lever. Therefore, in some cases, it may be troublesome to install the lever.

  On the other hand, when the cable is locked to the lever member as in claim 2 of the present application, the lever device is assembled by locking one end of the cable to the lever member in advance and setting this on the lever. Attach a lever with a member to the support, and then attach a retaining member to the support, or set the lever member to the support with one end of the cable locked, then set the lever Then, a procedure of attaching the retaining member to the support can be taken. The lever can be set on the support without having to hold one end of the cable by hand, making assembly easy. In addition, since the amount of protrusion at the end of the cable can be adjusted before the lever is attached, the adjustment is also easy.

  The engaging claw can be formed on the support body. However, if the engaging claw is formed on the retaining member as in claim 3, for example, when the engaging claw is broken, it is sufficient to replace only the retaining member. There are benefits that can be prevented. Further, since the retaining member has a gate shape straddling the cable, it can be miniaturized without being in the way of the cable.

It is an external view of the chair which concerns on embodiment, (A) is a front view, (B) is a side view. (A) is a plan view and (B) is a rear view. (A) is a perspective view with the base and the back frame separated, and (B) is a perspective view with the rear back frame separated and turned over. It is a separation perspective view of a seat outer shell and a seat. It is a separation perspective view of a support mechanism part. It is a perspective view of the principal part. It is a separate perspective view of the principal part. (A) is a separated perspective view of a lever device and a seat outer shell, (B) is a separated perspective view of a lever and a retaining member, and (B) is a perspective view of an end portion of a cable conduit. (A) is the perspective view which looked at the lever from the bottom, (B) is the perspective view of a lever member, (C) is the isolation | separation perspective view of a lever apparatus. (A) (B) is the isolation | separation perspective view of the principal part. (A) is a separated perspective view, (B) is a partial perspective view with a lever attached, and (C) is a side sectional view at an end portion of the lever device. It is a vertical side view in the center part of a lever apparatus. It is a separation side view of a base, an intermediate metal fitting, and a front back frame. It is a side view which shows the relationship between a spring unit and a front part back frame. (A) is the bottom view of a support mechanism part, (B) is the isolation | separation perspective view which looked at the base and the front part back frame from the downward direction. (A) is a perspective view of a base and a back frame, (B) is a perspective view in the state which has arrange | positioned intermediate metal fittings. It is a separation perspective view of a support mechanism part. It is a separation perspective view of a support mechanism part. (A) is a separated perspective view showing the relationship between the slider and the intermediate metal fitting, (B) is a perspective view of the slider receiver, and (C) is a partially separated front view showing the relationship between the slider and the slider receiver. It is a separation perspective view of a reaction force adjustment unit and a base. (A) is the isolation | separation perspective view of a reaction force adjustment unit, (B) is the perspective view which looked at the reaction force adjustment unit from the downward direction. (A) is a perspective view which shows the relationship between a spring unit and a front part back frame, (B) is a side view in the state which turned the spring unit upside down. (A) is a perspective view of an intermediate fitting with a locking gas cylinder attached thereto, (B) is a perspective view of the locking gas cylinder, and (C) is a separated perspective view of the locking gas cylinder and the intermediate fitting. . (A) is a partially separated perspective view centering on the lock gas cylinder, (B) is a perspective view of a support member of the lock gas cylinder, and (C) is a portion of the lock gas cylinder viewed from below. It is a perspective view.

  Next, an embodiment of the present invention will be described with reference to the drawings. In the following description, the words “front and rear” and “left and right” are used to specify the direction, but the words on the front and rear and right and left are based on the person who is seated. The front view direction is the direction facing the seated person, and therefore the left and right in the front view are opposite to the left and right viewed from the seated person.

(1). Outline of chair First, an outline of the chair will be described mainly with reference to FIGS. This embodiment is applied to a swivel chair frequently used for office work or the like. The chair includes a leg device 2 having a leg column 1 and a cutter, a base 3 fixed to the upper end of the leg column 1, and a base 3. It has a seat 4 arranged above and a backrest 5 on which a seated person can rest. The base 3 is formed in a box shape opened upward.

  For example, as shown in FIG. 3, an intermediate metal fitting 6 made of a metal plate is arranged on the base 3, and a resin seat outer shell (seat receiving member) 7 shown in FIG. It has been. The seat outer shell 7 can be connected to the base 2 without using the intermediate metal fitting 6.

  As shown in FIG. 4, the seat 4 has a resin seat inner shell (seat plate) 8 and a seat cushion material 9 disposed on the upper surface thereof. The seat cushion material 9 is a skin material such as a cloth. (Not shown) covered from above. The seat outer shell 7 is composed of two members, a fixed outer shell 10 fixed to the intermediate metal fitting 5 and a sliding outer shell 11 protruding in front thereof. The sliding outer shell 11 is connected to the fixed outer shell 10. It is attached to move back and forth. A large number of ribs are formed on the upper surface of the fixed outer shell 10.

  As shown in FIGS. 1 and 2, a back frame 12 is connected to the base 3 so as to be able to tilt backward, and a backrest 5 is attached to the back frame 12. The back frame 12 is configured to be separated into a front back frame 13 connected to the base 3 and a rear back frame 14 to which two backrests 5 are attached, both of which are fitted together and fixed with screws 15. . The front back frame 13 has a forward arm portion 13 a that extends forward at an outer position of the base 2, and the front end portions of the left and right arm portions 13 a are connected to the base 3 by a left and right laterally long first support shaft 16. Accordingly, the backrest 5 tilts around the axis of the first support shaft 16.

  The chair of the present embodiment is a synchro-type chair in which the seat 4 is retracted in conjunction with the backward tilt of the backrest 5, and the front portion of the intermediate bracket 6 is connected to the base 3 so as to be movable back and forth. At the same time, the rear portion of the intermediate metal fitting 6 is connected to a bracket portion 17 projecting upward from the front back frame 13 by a horizontally elongated second shaft 18.

  As a means for connecting the front portion of the intermediate fitting 6 to the base 3, a pair of left and right sliders 19 are attached to the intermediate fitting 6, while a left and right slider receiver 21 is fixed to the base 3 via a support fitting 20. The slider receiver 21 is mounted so that it can be moved back and forth but not vertically. Inside the base 3 are arranged a group of members such as a reaction force adjusting device that elastically supports the back tilt of the back 5 and a lock gas cylinder 22 for adjusting the back tilt angle of the back 5. These will be described later.

(2) Lever device As shown in FIG. 4, a lifting operation lever 22 is attached to a portion of the right outer portion of the fixed outer shell 10 near the rear end, and the lifting operation lever of the fixed outer shell 10. A locking lever device 23 for turning the locking gas cylinder 22 on and off is provided at a position behind the locking lever 22. The embodiment of the present invention will be described taking the locking lever device 23 as an example. In addition, in this embodiment, the fixed outer shell 10 is an example of the support body described in the claim.

  For example, as shown in FIG. 8, the locking lever device 23 includes a lock switching lever 25 that a seated person applies a finger to rotate, and a retaining member 26 that holds and holds the lock switching lever 25 on the fixed outer shell 10. , And a lever member 29 to which one end of a cable 28 slidably inserted into the tube 27 is locked. These members are resin molded products. A cable conduit is constituted by the cable 28 and the tube 27, and balls 28 a are fixed to both ends of the cable 28.

  The lock switching lever 25 includes a flat finger hooking portion 30 on which a seated person applies a finger, and a bag-like portion 31 connected to the front end of the finger hooking portion 30. The finger hook 30 protrudes backward from the rear end of the fixed outer shell 10. Accordingly, the lock switching lever 25 rotates around the horizontally long axis.

  The bag-like portion 31 has a mountain shape when viewed from the side, and protrudes upward from the finger rest portion 30. The bag-shaped portion 31 includes a left and right side plate 31a and a front plate 31b. The front end portion of the left and right side plate 31a and the lower end form a semicircular rotation support portion 32, and On the side plate 31a, a restricting portion 33 concentric with the rotation support portion 32 is provided so as to protrude leftward and rightward. Although the restricting portion 33 is basically circular, the lower surface is cut obliquely downward. Therefore, the restricting portion 33 is formed with an inclined surface 34 that goes down toward the root.

  The rear end portion of the fixed outer shell 10 is a curved wall 10a that warps upward, and a land portion 35 having a mountain shape in side view is formed on the front side of the curved wall 10a so as to cover the bag-shaped portion 31 of the lock switching lever 25. (The land portion 35 can also be called a lever support portion). For example, as shown in FIG. 8, the curved portion 10 a of the fixed outer shell 10 has a window hole 36 for exposing the finger hooking portion 30 of the lock switching lever 25 backward. As shown by an arrow 37 in FIG. 8A, the lock switching lever 25 is set so as to be fitted into the window hole 36 from above with the finger-hanging portion 30 facing down and to cover the land portion 35. For example, as shown in FIG. 11A, a lever mounting portion 10b provided with a land portion 35 is formed on the lower surface portion of the fixed outer shell 10 so as to protrude downward.

  As shown in FIGS. 7 and 10, a receiving hole 38 into which the rotation support portion 32 of the lock switching lever 25 is fitted in a portion of the fixed outer shell 10 positioned at the lower end of the left and right outer surfaces of the land portion 35. Is formed. The receiving hole 38 is an example of the receiving portion described in the claims, and the lock switching lever 25 rotates around the axis of the rotating support portion 32 by fitting the rotating support portion 32 into the receiving hole 38. Move. Side step portions 39 for restricting the downward turning posture of the lock switching lever 25 are formed on the left and right side surfaces of the land portion 35 and behind the receiving hole 38.

  A pair of left and right connecting claws 42 protrude from the fixed outer shell 10 in front of the land portion 35. A narrow tube receiver 44 into which a fitting groove 43 provided at one end of the tube 27 is fitted is formed at the bottom between the left and right connecting claws 42. The connecting claw 42 is for connecting the rear portion of the good inner shell 8.

  For example, as shown in FIG. 10, the fixed outer shell 10 is integrally formed with left and right partition walls 45 in a state of being continuous with the connecting claws 42, and the surrounding wall 46 is also formed on the left and right outer sides of the land portion 35. Is formed. Further, as shown in FIG. 9A, a center wall 47 is integrally connected to the front surface of the land portion 35 and the connection claw 42, but the front surface of the land portion 35 and the outer surface of the reinforcing wall 47 are connected to the front stage. A portion 48 is formed.

  For example, as shown in FIG. 10, the retaining member 26 is formed in a frontal portal shape having left and right feet 26 a, but the left and right feet 26 a are divided by a partition wall 45, a center wall 47, and a surrounding wall 46. It fits into the enclosed space from above. The foot part 26a is held by the front step part 48 so as not to move backward. At the lower end of the front surface of the left and right foot portions 26a of the retaining member 26, an engaging claw 49 having a flange portion 49a protruding forward is projected upward. Since the upper end of the engaging claw 49 is a free end, the collar portion 49 a moves in the front-rear direction due to the elastic deformation of the engaging claw 49. And the engagement hole 50 in which the collar part 49a of the engagement nail | claw 49 fits in the partition wall 45 is formed.

  Needless to say, the retaining member 26 is held so that it cannot be removed and cannot be displaced from front to back and from side to side by inserting the foot 26a into the fixed outer shell 10 from above. As can be understood from FIG. 8B, a stopper portion 51 is formed on the rear surface of the foot portion of the retaining member 26 so as to cover the restriction portion 33 of the lock switching lever 25 from above. As a result, the lock switching lever 25 is held on the fixed outer shell 10 so as not to be detached in a state in which the rotation is allowed.

  The lever member 29 is disposed in a state where the land portion 35 is sandwiched between the lock switching lever 25 and has left and right downward arms 52 and has a portal shape in front. On the other hand, the rear surfaces of the left and right side plates 35 ′ constituting the land portion 35 are guide surfaces that are convexly curved upward and obliquely upward in a side view, and this guide surface 35 a has an inner side of the downward arm 52 of the lever member 29. A slide portion 29a is slidably mounted. Accordingly, the downward arm 52 of the lever member 29 is located on the left and right outer sides of the land portion 35. A rib 53 having a circular arc when viewed from the side is provided between the left and right side plates 35 ′ of the land portion 35, and the center portion of the lever member 29 is set so as to approach or abut against the rib 53.

  The guide surface 35a of the land portion 25 is formed in a stepped state, and the slide portion 29a of the lever member 35 is held immovably forward by the upper engagement portion 35b at the upper end of the guide surface 35a. Further, a lower engaging portion 35c that is recessed toward the front side is formed at the lower end portion of the guide surface 35a. When the slide portion 29a of the lever member 29 is fitted into the lower engaging portion 35c, the lever member 29 and the lock The switching lever 25 is held in a posture rotated downward. That is, since the cable 28 is pulled by the push output of the locking gas cylinder 21, if the slide portion 29a of the lever member 29 is fitted in the lower engagement portion 35c, the lever member 29 is subjected to a certain amount of force. If it is not applied, it cannot be raised upward, and therefore, it is held in a posture rotated downward.

  As shown in FIG. 8 (A), a protrusion 29a is provided at the upper front end of the central portion of the lever member 29. On the other hand, as shown in FIG. Is formed with a positioning groove 25a into which the protrusion 29a of the lever member 29 is fitted.

  As shown in FIGS. 9C and 11C, a fitting portion 54 into which the upper portion of the lever member 29 is fitted is formed inside the bag-shaped portion 31 of the lock switching lever 25 (the lever member). 29, the downward arm portion 52 is positioned outside the side plate 35 'of the lock switching lever 25. In FIG. 11C, the side plate 35' shows the inner and outer portions of the side plate 35 'in cross section. .) The lever member 29 can be held so as not to fall by the tensioning action of the projection 29a and the positioning hole 25a because the projection 29a is fitted in the positioning groove 25a while the downward arm portion 52 is fitted in the fitting portion 54. Of course, it is also possible to prevent the fall more accurately by forming an engaging means such as an adder cut portion in which the protrusion 25a is caught in the positioning groove 25a of the lock switching lever 25.

  A ball hole 55 into which a ball 28a fixed to one end of the cable 28 is fitted is provided in the left and right center portion of the upper surface of the lever member 29, and the lever member 29 has a slit 56 through which the cable 28 passes. Is forming. Further, as shown in FIGS. 10 and 8, an upward opening groove 57 through which the cable 28 passes is formed in the left and right intermediate portion of the land portion 35.

  In the above configuration, when assembling the locking lever device 23, for example, the ball 28a is fitted into the lever member 29, and this is fitted in the bag-like portion 31 of the lock switching lever 25 in advance, and then The lock switching lever 25 to which the member 29 is attached is inserted into the window hole 36 from above and the bag-like portion 31 is put on the land portion 35, and the lever member 29 is fitted into the land portion 41. Next, the retaining member 26 is inserted and attached from above.

  On the contrary, the lever member 29 can be set on the land 31 first. That is, the ball 28a is fitted in the lever member 29 and set in the land portion 35, and then the lock switching lever 25 is inserted into the window hole 36 from above to cover the bag-like portion 31 over the land portion 35. The fitting portion 54 of the lock switching lever 25 is fitted into the head of the lever member 29, and then the retaining member 26 is inserted and attached from above.

  In any case, since the ball 28a is held on the lever member 29 so as not to drop, the lock switching lever 25 can be set without holding the tube 27 and the cable 28 one by one. Further, the lever member 29 and the retaining member 26 can be set on the fixed outer shell 10 very easily. Therefore, the lock lever device 23 can be easily assembled as a whole.

  For example, when it is necessary to adjust the length of the protrusion of the ball 28a from one end of the tube 27, the optimum length can be obtained by rotating the lever member 29 before the lock switching lever 25 is attached. Can be set. For this reason, it is easy to adjust the protruding amount of the ball 28a.

  In this embodiment, the rotation support portion 32 is formed in a semicircular shape, but it can be formed in a round bar shape. In this case, the retaining member can be pressed and held by the round bar-shaped rotation support portion. The specific form of the lever can be arbitrarily set as required. The object is not limited to the operation of the lock gas cylinder 21, but can be applied to various lever devices in a chair such as a lever device for raising and lowering a seat. The attachment position of the lever device can be arbitrarily set. For example, it can be attached to a seat inner shell constituting the seat, attached to a back frame, or attached to an armrest device.

(3). Relationship between the back frame and the base The present invention discloses a number of new and meaningful configurations for the chair. This point will be supplementarily explained below. First, the relationship between the back frame 12 and the base 3 will be described.

  As described above, the back frame 12 includes the front back frame 13 and the rear back frame 14. For example, as shown in FIG. 3, the front back frame 13 includes left and right side arms 60 and front and rear joint portions 61 and 62 that connect the left and right side arms 60 at the rear. A bearing tube portion 63 that protrudes inward is provided at the front end, and the first support shaft 16 is inserted through the bearing tube portion 63, and the left and right bearing tube portions 63 have a crank-like load action protruding downward. The part 64 is connected (of course, the 1st spindle 16 has penetrated the side plate of the base 3). Therefore, the front back frame 13 has a frame-like shape that is opened up and down as a whole, and the leg support 1 is located inside the frame.

  Now, in most rocking chairs with the backrest tilted backward, the back frame to which the backrest is attached is connected to the base with a pin. In that case, for example, as disclosed in Japanese Patent Application Laid-Open No. 2011-24752, the front end of the back frame is often arranged on the left and right outer sides of the base. This is based on the request that the base frame should be made as compact as possible while the back frame needs a certain amount of lateral width to ensure strength (particularly strength against torsion).

  However, in the configuration in which the front end portion of the back frame 12 is simply disposed outside the base, the front portions of the left and right back frames become free ends, and there is a problem that the strength of the entire back frame is reduced. The back frame 12 and the base 3 included in the present embodiment are improved with the object of solving such a problem.

  In other words, in the present embodiment, the front back frame 13 is a molded product such as die-cast, and is a frame-like integrated structure that opens upward and downward as a whole, and thus has high strength. Further, since the bearing tube portion 63 protrudes inwardly, the distance between the tips of the left and right bearing tube portions 63 is considerably small. Therefore, the bending moment acting on the first support shaft 16 is small, and the first One spindle 16 has high durability. Moreover, since the left and right side arms 61 are positioned on the left and right outer sides of the base 3, the front back frame 13 as a whole has a high resistance to twisting.

  In this embodiment, the base 3 is formed with a window hole 65 into which the load acting portion 64 of the front back frame 13 is fitted from below. For this reason, the side arm 61 is arranged outside the base 3. Although the overall rigidity is increased, the front back frame 13 can be easily attached to the base 3.

  Further, since the window hole 65 and the load acting portion 64 are covered with the center cover 66 as shown in FIG. 13A, even if a person touches the lower surface of the base 3 with his / her hand, it is a safety problem. There is no. Also, there is no aesthetic problem. The advantage of having a frame structure in which the back frame 12 is opened up and down is not related to the separation of the back frame 12 into the front back frame 13 and the rear back frame 14, and the whole is integrated. It can also be applied to a structured back frame.

(4). Features of the back frame itself As described above, the front back frame 13 has the front and rear joint portions 61 and 62, but the front and rear joint portions 61 and 62 are connected by the center connecting portion 67 at the left and right intermediate portions. ing. Therefore, the front back frame 13 has two spaces 68 that are opened up and down. The lower and rear back frame 14 has a wide area base 69 connected to the front back frame 13 and a pair of left and right back posts 70 protruding upward from the rear end thereof. Is connected to the upper end of the back column 70, and the lower end of the backrest 5 is connected to the rear part of the base 69 and the left and right intermediate part.

  As shown in FIG. 3B, the base 69 of the rear back frame 14 is formed with a recess 71 having a downward opening that fits into the rear joint portion 62 of the front back frame 13, and the front portion. A pair of left and right arm portions 72 that fit into the space 68 of the back frame 13 from above are formed. The arm portion 72 extends to the lower surface of the front joint portion 61 of the front back frame 13, and as shown in FIG. 3A, the arm portion 72 is formed with a fitting groove 72a having an upward opening. The front joint portion 61 of the back frame 13 is formed with a fitting protrusion 61a into which the fitting groove 72a is fitted. The arm portion 72 may be provided in the front back frame 13 and the space 68 may be provided in the rear back frame 14, or the arm portion 72 may be provided with a fitting protrusion 61a.

  Now, as described in JP 2011-24752 A, in the rocking chair, the backrest is attached to the back frame, but the back frame is also made to be a front-rear separation system. Thus, when the back frame is a front-rear separation system, there is an advantage that processing is facilitated particularly when a molded product is formed (a complication and an increase in size of the mold can be prevented). However, if the back frame is composed of a plurality of members, the strength may be reduced as compared with a monolithic product.

  On the other hand, in the present embodiment, the rear back frame 14 is mounted on the front back frame 13 from above, and the arm portion 72 and the front back frame 13 are fitted vertically, so that the back frame 12 As a whole, the unity is remarkably improved, and even if it is connected by one screw 15, it has a sturdy structure. More specifically, the rear back frame 14 is subjected to an action of turning about the rear joint portion 62 as a fulcrum due to a backrest load, but the arm portion 72 is applied to the front back frame 13 of the front back frame 13 from below. Because of the contact fitting, the back load can be accurately supported even with one screw 15 (the load is not applied to the screw 15 at all).

  Further, since the side arms 60 of the front back frame 13 are connected by the front and rear joint portions 61 and 62 and the front and rear joint portions 61 and 62 are connected by the center connecting portion 67, the front back frame 13 is also connected. On the other hand, the rear back frame 14 has a high rigidity because the base 68 spreads in a plate shape, and the front back frame 13 and the rear back frame 14 have high rigidity. The back frame 12 has a solid structure although it is composed of two parts.

  On the outer surface of the left and right side arms 61 in the front back frame 13, an elbow mounting portion 73 for fixing an armrest device (not shown) projects outwardly. The elbow attachment portion 73 has a hollow shape that is open outward in a triangular shape in a side view. The side arm 60 is subjected to an action of twisting in a front view due to a downward load acting on the armrest device, but the elbow mounting portion 73 is located outside the front joint portion 61 in the side arm 61. Even if a large load is applied to the armrest device, the side arm 60 is not twisted and deformed, and an extremely high support strength can be secured. The elbow attachment portion 73 may be provided at the location of the rear back frame 14 in the side arm 60.

(5) Support structure of intermediate fitting As described above, the intermediate fitting 6 is supported by the base 3 through the slider 19 and the slider receiver 20 so as to be movable back and forth. Details of this point will be described mainly with reference to FIGS. As shown in FIG. 18, a flange 3a projecting outward is provided on the upper surface of the base 3, and a resin slider receiver 20 is fitted to the front portion of the flange 3a from the left and right outer sides. On the other hand, the slider 19 is attached to the intermediate metal fitting 6.

  As shown in FIG. 19A, the intermediate fitting 6 is formed with a recess 76 for attaching the slider 19, and the recess 76 has a mounting hole 77 that is convex outward in plan view. The attachment hole 77 extends to the upper surface of the intermediate fitting 6, and a square engagement hole 78 is formed inside the attachment hole 77 on the upper surface.

  On the other hand, the slider 19 has a base portion 19a. The base portion 19a has a fitting groove 79 that fits into the narrow edge portion 77a of the mounting hole 77, and an engagement that fits into the engaging hole 78 from below. A claw 80 and a foot 81 projecting downward from the intermediate metal fitting 6 are provided, and a projecting portion 81 a projecting outward in the lateral direction is provided at the lower end of the foot 81.

  The slider receiver 20 has an inward groove 82 that fits into the flange 3 a of the base 3, and is fixed to the flange 3 a with a screw 83. The left and right slider receivers 20 are in contact with each other below the base 3. As can be clearly understood from FIG. 19B, the slider receiver 20 has a support surface 84 on which the base 19 a of the slider 19 is placed. The support surface 84 is curved upward and convex in a side view, and the slider 19 slides on the support surface 84, so that the seat 4 moves backward while tilting backward. An upward space is formed in the support surface 84, and the space is filled with grease.

  The support surface 84 of the slider receiver 20 is divided into left and right sides with a long slot 85 cut open between labors. As can be understood from FIG. 19C, the long groove 85 is a dovetail groove whose lower part enters the left and right outer sides, and when the foot portion 81 of the slider 19 is fitted into the long groove 85, the intermediate metal 6 Is held on the base 3 through the slider 19 and the slider receiver 20 so as not to be separated upward. As described above, since the intermediate metal fitting 6 is held so as not to be separated upward by using the slider 19 and the slider receiver 20, the structure is simple and the assembling work can be reduced.

(6) Reaction force adjusting mechanism As shown in FIG. 17, for example, an elastic force adjusting unit 88 is provided in the base 3 to provide resistance against the backward tilting of the backrest 5. This point will be described mainly with reference to FIGS.

  The elasticity adjusting unit 88 has left and right support brackets 89 arranged along the left and right inner surfaces of the base 3. The support bracket 89 has a flap 89a that overlaps the flange 3a of the base 3 from above. The flap 89a overlaps the flange 3a of the base 3 and is fastened to the slider receiver 20 with screws 83 (see FIG. 18). .

  Further, as shown in FIG. 21A, for example, the elasticity adjusting unit 88 includes a spring unit 90 disposed between the left and right support brackets 89, an operation shaft 91 rotatably attached to the left and right support brackets 89, It has a substantially Y-shaped posture holding body 92 attached to the left and right sides of the spring unit 90 in a side view.

  The spring unit 90 is a substantially square tubular member 93 opened rearward, a compression coil spring (not shown) disposed inside the tubular member 93, and a movable member slidably fitted to the tubular member 93. It comprises a spring receiver 95. The movable spring receiver 95 has a substantially square shape when viewed from the front. For this reason, the inside of the cylindrical member 93 is also substantially in the shape of a square. In addition, a guide pin 98 is provided on the movable spring receiver 95, while a longitudinal guide groove 97 into which the guide pin 96 is fitted is formed on the inner side of the cylindrical member 93.

  A support shaft 100 is provided at the front end portion of the cylindrical member 53 so as to protrude outward in the left and right directions. The support shaft 100 is fitted into a hole 101 provided in the support bracket 89 via a bush. Since the support bracket 89 is fixed to the base 2, the spring unit 90 rotates up and down around the support shaft 100.

  And as shown in FIG. 14, the movable spring receiver 95 is pushed by the load action part 64 which comprises the front end of the front part back frame 13. As shown in FIG. Although not shown in the figure, the load acting portion 64 is provided with a cushioning material made of a resin having excellent wear resistance.

  For example, as can be understood from FIG. 13, a circumferential cam 110 having a pair of left and right main cam portions 111 is fitted to the operation shaft 91, while on the left and right side surfaces of the cylindrical member 93 constituting the spring unit 90, A cam receiving portion 112 with which the main cam portion 111 of the circumferential cam 110 abuts is provided. In the present embodiment, the circumferential cam 101 is formed with five cam surfaces 110 having different distances from the rotation axis. Therefore, when the circumferential cam 100 is rotated by the operation shaft 91, the spring unit 90 is Then, the distance (span) from the first support shaft 16 to the movable spring receiver 95 changes, and as a result, the resistance against rocking can be adjusted in five steps.

  For example, as shown in FIG. 21B, a posture holding cam portion 112 is integrally formed outside the main cam portion 111. A cam surface whose distance from the shaft center is opposite to that of the main cam portion 111 is formed on the outer periphery of the posture holding cam portion 112, and the upper portion 92 a of the force holding body 92 is positioned at the posture holding cam portion 112. It contacts from above. For this reason, the main cam portion 111 of the circumferential cam 110 is held in contact with the cam receiving portion 112. As a result, the cylindrical member 93 can be accurately rotated regardless of which direction the operating shaft 91 is rotated.

  For example, as shown in FIG. 22B, a band plate-like spring portion 114 that comes into contact with the cam receiving portion 112 from below is integrally provided at the lower portion of the force holding body 92. The spring portion 114 has a mountain shape in a side view, and the apex portion is in contact with the cam receiving portion 112. For this reason, the posture holding body 92 can rotate so that the upper portion 92 a is separated from the cam receiving portion 112 against the elasticity of the spring portion 114. Thereby, the rotation of the circumferential cam 110 is allowed.

(7). Locking device Next, a locking device for controlling the locking of the backrest 4 will be described mainly with reference to FIGS. The lock device has the lock gas cylinder 21 as described above. As shown in FIG. 23A, the lock gas cylinder 21 has a cylindrical body 21a and a rod 21b slidably fitted thereto.

  In this embodiment, the rod 21b protrudes rearward, and as shown in FIG. 24C, a support member 120 made of resin or the like is attached to the front end (rear end) of the rod 21b, and the support member 120 is attached to the third shaft 121. It is inserted. The third shaft 121 is inserted and supported by the left and right side plates 122 a of the base bracket 122 fixed to the rear portion of the base 3. The base bracket 122 is fixed with a bush 123 opened vertically, and the leg support 1 is fitted to the bush 123 from below.

  A mounting groove 124 into which the third shaft 121 is fitted is formed in the support member 120 so as to open substantially upward. Accordingly, the locking gas cylinder 21 is in a posture in which the mounting groove 124 is opened so as to open substantially downward, and then the support member 120 is fitted into the third shaft 121, and then the cylindrical body 21a is directed forward. Can be attached to the third shaft 121 in a one-touch manner. As described above, the locking gas cylinder 21 is attached in a state where the intermediate metal fitting 6 is attached to the base 2.

  As shown in FIG. 24C, in a state where the locking gas cylinder 21 is set in a predetermined posture, the support member 120 is held by the base bracket 122 so as not to drop. Accordingly, the locking gas cylinder 21 is held so that it cannot be removed from the front and rear. The base bracket 1221 has a horizontal piece 122b on which the support member 120 is placed facing forward.

  As shown in FIG. 24, a lever piece 126 for operating the push valve 125 of the locking gas cylinder 21 is fitted into the support member 120 from below. A support shaft portion (not shown) is formed at the lower end of the lever piece 126, and the support shaft portion is fitted in a bearing groove (not shown) provided in the support member 120. The upper part of the lever piece 126 is exposed on the support member 120. Then, the other end of the tube 27 is fitted into the recess 120 a provided at the front end of the upper end of the support member 120 from above, and the ball 28 a fixed to the other end of the cable 28 is hooked on the upper end of the lever piece 126. Yes.

  When the lock switching lever 25 to which the present invention is applied is turned, the lever piece 126 is selectively held between the locked posture and the free posture. As a result, the lock gas cylinder 21 is switched between a free state that can be expanded and contracted and a locked state that cannot be expanded and contracted.

  As shown in FIG. 23, a horizontally elongated fourth shaft 127 is attached to the front end portion of the locking gas cylinder 21, and the fourth shaft 127 includes left and right bottom plates, left and right side plates 128a, and flap pieces 1298b. The pin receiving member 129 having the above is fitted and held from above. That is, the flap piece 128b of the pin receiving member 128 protrudes outward from the upper end of the side plate 128a, and the fourth shaft 127 is fitted from above into the pin receiving groove 129 formed by cutting and opening the flap piece 128b and the side plate 128a. Yes.

  The flap piece 128b of the pin receiving member 128 is disposed on the lower surface of the intermediate fitting 6, and is held by the front plate 6a and the inner plate 6b of the intermediate fitting 6 so that it cannot move back and forth and cannot move left and right. As shown in FIG. 23C, a stepped portion 128c that fits to the tip of the inner plate 6b of the intermediate fitting 6 is formed at the rear portion of the pin receiving member 128. It is held immovable.

  The fourth shaft 127 is held by a stopper 131 inserted and attached to the intermediate bracket 6 from the front so that it cannot be pulled out upward and left and right. Accordingly, the flap 128b of the pin receiving member 128 is supported from below by the stopper 131. Therefore, the pin receiving member 128 is held so as not to be dropped without being screwed. The stopper 131 is made of resin, has left and right feet 131a extending rearward from the front plate, and has a substantially L shape in rear view. A hole 132 into which the foot 131 of the stopper 131 is fitted is formed in the front plate 6a of the intermediate bracket 6.

  The present invention can be embodied in a chair. Therefore, it can be used industrially.

1 Leg support (gas cylinder)
3 Base 4 Seat 6 Intermediate Bracket 21 Locking Gas Cylinder 23 Locking Lever Device 25 Applying the Present Invention 25 Lock Switching Lever 26 Retaining Member 27 Tube Constructing the Cable Conduit 28 Cable Constructing the Cable Conduit 28a Ball 29 Lever 30 Finger hook portion 31 Bag-like portion 32 Rotation support portion 33 Restriction portion (rotation receiving portion)
35 Land portion 38 Receiving hole as an example of receiving portion 43 Engaging hole as an example of engaging portion 49 Engaging claw

Claims (3)

It has a lever device in which one end of a cable for operating a gas cylinder or other member is pulled by a turning operation of a lever rotatably held on a support,
While the lever includes a rotation support portion that is rotatably fitted to a receiving portion provided on the support body, and a finger hooking portion that is operated by a person to touch the finger,
The supporting member is attached with a retaining member that covers the rotation supporting portion of the lever or the restricting portion formed concentrically therewith from the side opposite to the receiving portion, and the retaining member and the supporting member. Is provided with an engaging claw that elastically deforms and then returns when the retaining member is pressed against the support, and the other is engaged with the engaging claw. An engaging portion is provided to hold the stop member so as not to be detached from the support.
Chair. The lever has a bag-shaped portion that opens toward the support, and a lever member that can rotate integrally with the lever is disposed inside the bag-shaped portion. One end of the cable is locked,
The chair according to claim 1. The retaining member has a gate shape having a pair of feet so as to straddle the cable, the engaging claw is provided on the left and right feet, and the engaging portion is provided on the support,
The chair according to claim 1 or 2.

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