Chair with return force mechanism

Abstract

A chair according to the present invention has a reference position P located midway in a front-back direction in a movable range of a seat 2. The chair includes a return force generation mechanism 4 configured to generate a return force in a direction to return the seat 2 moved from the reference position P at least in the front-back direction to the reference position P. The return force generation mechanism 4 includes an elastic member 40 configured to increase the return force in the direction to return the seat to the reference position P as the amount of movement of the seat from the reference position P increases.

Claims

1. A chair configured to be movable in the front-back direction and in a left-right direction and having a reference position located midway in a front-back direction and in a left-right direction in a movable range of a seat, the chair comprising: a first return force generation mechanism configured to generate a return force in a direction to return the seat moved from the reference position in the front-back direction to the reference position; and a second return force generation mechanism configured to generate a return force in a direction to return the seat moved from the reference position in the left-right direction to the reference position, wherein the first return force generation mechanism comprises an elastic member configured to increase the return force in the direction to return the seat to the reference position as an amount of movement of the seat from the reference position increases, wherein the second return force generation mechanism is configured to shift the center of gravity of the seat upward in accordance with the movement of the seat from the reference position, wherein regardless of whether the seat moves front, back, left or right, a movement end of the seat inclines downward in accordance with the amount of movement of the seat.

2. The chair according to claim 1, wherein in the first return force generation mechanism, the reference position is located midway in the front-back direction in the movable range and is a position when a person is not seated, and the seat is stationary on that the elastic force in the front-back direction is zero or balanced at the reference position in the front-back direction.

3. The chair according to claim 1, wherein the first return force generation mechanism is configured to variably adjust an elastic biasing force.

4. The chair according to claim 1, wherein the elastic member of the first return force generation mechanism comprises a first elastic member for applying an elastic biasing force toward the reference position when the seat is located forward of the reference position, and a second elastic member for applying an elastic biasing force toward the reference position when the seat is located backward of the reference position.

5. The chair according to claim 1, wherein the first return force generation mechanism includes a single elastic member for applying an elastic biasing force toward the reference position when the seat is located forward of the reference position, and for applying an elastic biasing force toward the reference position when the seat is located backward of the reference position.

6. The chair according to claim 1, wherein the first return force generation mechanism includes a front link member having a lower end pivotally supported around a left-right shaft n1 by a casing, and a back link member having a lower end pivotally supported around a left-right shaft n2 by the casing, and the seat is attached to upper ends of the front link member and the back link member via left-right shafts n3 and n4, wherein a portion of supporting positions of the left-right shafts n1, n2, n3 and n4 can be changed in the front-back direction such that an initial displacement of the elastic member is changed to make an elastic biasing force variably adjustable.

7. The chair according to claim 1, wherein the first return force generation mechanism includes a front link member having a lower end pivotally supported around a left-right shaft n1 by a casing, and a back link member having a lower end pivotally supported around a left-right shaft n2 by the casing, and the seat is attached to the upper ends of the front link member and the back link member via the left-right shafts n3 and n4, wherein a first contact plate and a second contact plate are configured to be integrally pivotal with the back link member and the front link member, respectively, so as to be configured to vary a distance from the left-right shaft n1 to the portion of the first contact plate to be brought into contact with the elastic member and a distance from the left-right shaft n2 to the portion of the second contact plate to be brought into contact with the elastic member, such that an initial position of the elastic member is changed to change the displacement of the elastic member due to the positional change of the seat to make repelling force properties of the elastic member variably adjustable.

8. The chair according to claim 1, wherein the first return force generating mechanism is configured to shift the reference position to a position where the elastic force in the front-back direction is zero or balanced by changing the initial displacement of the elastic member.

9. The chair according to claim 1, comprising a backrest located backward of the seat, wherein the seat and the backrest are movable in conjunction with each other in the front-back direction, and a movement end of the seat inclines downward in accordance with the amount of movement of the seat.

10. The chair according to claim 7, wherein the first return force generating mechanism is configured to shift the reference position to a position where the elastic force in the front-back direction is zero or balanced by changing the initial position of the elastic member.

11. The chair according to claim 1, wherein the second returning force generating mechanism is composed of a pair of link members.

12. The chair according to claim 11, wherein the pair of link members have a stable position at a portion that holds the object to be suspended by gravity at the lowest position, and regardless of the moving direction from this position to the left or right, the tip side in the moving direction is tilted downward and the center of gravity of the seat is raised with generating a return force in accordance with the above accordingly.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a chair according to a first embodiment of the present invention.

(2) FIG. 2 is a right-side view of the chair according to the first embodiment of the present invention.

(3) FIG. 3 is a front view of the chair according to the first embodiment of the present invention.

(4) FIG. 4 is a right-side view illustrating a state where a seat according to the first embodiment of the present invention is moved forward.

(5) FIGS. 5A to 5B3 are a drawing illustrating a return force generation mechanism according to the first embodiment of the present invention.

(6) FIG. 6 is a drawing illustrating a state where a return force is increased by a change of the position of an elastic member in the first embodiment of the present invention.

(7) FIG. 7 is a drawing illustrating a left-right movement mechanism according to the first embodiment of the present invention.

(8) FIG. 8 is a perspective view of the chair according to a second embodiment of the present invention.

(9) FIG. 9 is a right-side view of the chair according to the second embodiment of the present invention.

(10) FIG. 10 is a right-side view illustrating a state where the seat according to the second embodiment of the present invention is moved forward.

(11) FIG. 11 is a right-side view illustrating a state where the seat according to the second embodiment of the present invention is moved backward.

(12) FIG. 12 is a drawing illustrating a state where the reference position of the seat is shifted backward by a change of the position of the elastic member in the second embodiment of the present invention.

(13) FIG. 13 is a drawing illustrating a modified example of the present invention.

MODE FOR CARRYING OUT THE INVENTION

(14) Herein, a first embodiment of the present invention will be described with reference to FIGS. 1 and 5A to 5B3.

(15) FIGS. 1 to 3 are respectively perspective, right-side, and front views of a chair according to the first embodiment. FIG. 4 is an explanatory drawing of movement of the chair according to the first embodiment. The chair is configured such that a seat 2 integrally formed with a backrest 3 is rotatably supported by a leg support pole 11 protruding from a leg 1. The position of the seat 2 when no one is seated is defined as a reference position P. The chair includes a function to move and return the seat 2 with respect to the reference position P.

(16) Specifically, the leg 1 of the chair includes leg blades 1b having ends to which casters 1a are respectively attached. The leg support pole 11 is attached to a center hole of the leg blades 1b. A support base 12 adapted to support the seat 2 is rotatably attached to an upper end of the leg support pole 11.

(17) The seat 2 is supported by the support base 12 to be movable forward or backward by a front-back movement mechanism 6 and to be movable right or left by a left-right movement mechanism 7.

(18) The front-back movement mechanism 6 includes a front link member 61 having a lower end pivotally supported around a left-right shaft n1 by a casing 8, and a back link member 62 having a lower end pivotally supported around a left-right shaft n2 by the casing 8. When the seat 2 is located at the reference position P, an upper end of the front link member 61 is attached in a forward tilted posture to a bracket 21 at a front end of the seat 2 to be pivotal around a left-right shaft n3 and an upper end of the back link member 62 is attached in a backward tilted posture to a bracket 22 at a back end of the seat 2 to be pivotal around a left-right shaft n4. In other words, when the seat 2 is moved forward from the reference position P, the front link member 61 is brought into a further forward tilted posture and the back link member 62 is brought into an upright posture. Thus, the seat 2 is tilted forward. Meanwhile, when the seat 2 is moved backward, the back link member 62 is brought into a further backward tilted posture and the front link member 61 is brought into an upright posture. Thus, the seat 2 is tilted backward.

(19) Also, the left-right movement mechanism 7 includes a left link member 71 and a right link member 72. Upper ends of the respective link members 71, 72 are pivotally supported around front-back shafts m1, m2 by appropriate portions of the support base 12. When the seat 2 is located at the reference position P, lower ends of the respective link members 71, 72 are pivotally attached to the casing 8 around front-back shafts m3, m4 in a state where the link members 71, 72 are tilted with the lower ends located near each other; thereby the casing 8 is suspended. The casing 8 includes a hollow part opened downward, and the support base 12 is arranged in the hollow part without interfering with the hollow part.

(20) That is, when the seat 2 is moved left with respect to the support base 12, the inclination of the left link member 71 decreases to come close to a vertical posture and the inclination of the right link member 72 increases to come close to a horizontal posture. As a result, the casing 8 is tilted left in front view as illustrated in FIG. 7. Meanwhile, when the seat 2 is moved right with respect to the support base 12, the inclination of the right link member 72 decreases to come close to a vertical posture and the inclination of the left link member 71 increases to come close to a horizontal posture. As a result, the casing 8 moves right in front view, i.e., moves in the opposite direction illustrated in FIG. 3.

(21) In other words, the seat 2 is moved forward or backward with respect to the support base 12 via the casing 8 swingable right or left, therefore being configured to be movable independently in each of front-back or left-right directions. As a result, multiple behaviors or movements of the seat 2 can be realized.

(22) In addition, the chair includes a first return force generation mechanism 4 illustrated in FIGS. 2 and 5A to 5B3 and a second return force generation mechanism 5 illustrated in FIG. 3. Each of the return force generation mechanisms 4, 5 are configured to generate a return force in a direction to return the seat moved in the front-back or left-right direction to the reference position P, and is designed to increase the return force for returning the seat to the reference position P as the amount of movement of the seat from the reference position P increases.

(23) The first return force generation mechanism 4 includes a cylinder 40 as an elastic member supported through a support portion 40x by the casing 8, and rods 40a1, 40a2 respectively protruding backward and forward from opposite ends of the cylinder 40. The first return force generation mechanism 4 is configured to store an elastic repelling force when each of the rods 40a1, 40a2 is retracted in the cylinder 40. Specifically, as illustrated in FIG. 5A, the rods 40a1, 40a2 are respectively connected to retainers 40b1, 40b2 in the cylinder 40. A compression spring 40c is interposed between the retainers 40b1, 40b2. Each of the rods 40a1, 40a2 is independently retractable in the cylinder 40 while compressing the spring 40c. In addition, the cylinder 40 is fixed to the support base 12.

(24) Also, contact plates 12a, 12b are provided at positions opposite to ends of respective rods 41a, 42a. The contact plates 12a, 12b are configured to be integrally pivotal with the backlink member 62 and the front link member 61, respectively. Thus, the seat 2 is moved forward as illustrated from a state of FIG. 2 to a state of FIG. 4. At this time, in accordance with a standing movement of the backlink member 62, the contact plate 12a integral with the backlink member 62 compresses the rod 40a1 while pushing the rod 40a1; therefore, the front link member 61 tilts forward to separate from the rod 40a2. Consequently, the spring 40c is compressed to store a backward return force. When the seat 2 is moved backward, a reversed action to the above-mentioned forward movement allows the contact plate 12b integral with the front link member 61 to compress the rod 40a2; therefore, the spring 40c is compressed to store a forward return force. The spring 40c may be configured to have a natural length in a state where the seat 2 is located at the reference position P. Alternatively, the spring 40c may be initially compressed to be set in a condition that the repelling force is balanced when the seat 2 is located at the reference position P.

(25) In such a case, the first return force generation mechanism 4 may be configured by a pair of cylinders 41, 42 as elastic members as illustrated in FIGS. 5A to 5B3. In this case, an elastic repelling force is stored when each of the rods 41a, 42a protruding from the respective cylinders 41, 42 is retracted therein. The cylinders 41, 42 are arranged to be movable with the seat 2 in the front-back direction. The cylinder 41 is configured such that the rod 41a protrudes backward and faces to the contact plate 12a, and the cylinder 42 is configured such that the rod 42a protrudes forward and faces to the contact plate 12b. Thus, when the seat 2 is moved forward, the rod 41a of the one cylinder 41 is compressed as illustrated in FIG. 5B 3 to store a backward return force. Meanwhile, when the seat 2 is moved backward, the rod 42a of the other cylinder 42 is compressed as illustrated in FIG. 5B 2 to store a forward returning force. In such a case, the repelling force may not be stored or may be balanced when the seat is located at the reference position in FIG. 5B 1.

(26) With such a configuration, the compression properties of the both cylinders 41, 42 may be changeable. In the first embodiment, a spring coefficient of the cylinder 42 to be compressed at the time of the forward movement of the seat 2 is appropriately set to be smaller than a spring coefficient of the cylinder 41 to be compressed at the time of the backward movement of the seat 2.

(27) Further, a pair of link members 71, 72 configuring the left-right movement mechanism 7 illustrated in FIG. 3 also serves the second return force generation mechanism 5 configured to generate a return force in a direction to return the seat 2 moved from the reference position P in the left-right direction to the reference position P. That is, the pair of link members 71, 72 is configured to hold an object to be suspended in the lowest position by gravity, and the position is defined as a stable position. Even when the object is moved from the stable position either right or left, the center of gravity of the seat shifts upward while a movement of the tip side is inclining downward in accordance with the amount of movement. Accordingly, a return force is generated and a return force at the reference position P becomes zero.

(28) In the first embodiment, the reference position P is located midway in a front-back movable range. However, since the chair is configured such that the seat is integrally formed with the backrest, it is effective that for example, by application of an appropriate stopper, a backward movable distance of the seat 2 and the backrest 3 from the reference position P is set to be larger than a forward movable distance of the seat 2 and the backrest 3 from the reference position P.

(29) Additionally, as illustrated in FIG. 6, a return force adjustment mechanism 40z is provided in the first embodiment. The return force adjustment mechanism 40z is configured such that an initial position of the cylinder 40 as the elastic member is changed to change the displacement of the cylinder 40 due to the positional change of the seat 2. The return force adjustment mechanism 40z is configured to move up/down the support portion 40x supporting the cylinder 40. Accordingly, a distance from the left-right shaft n1 to the contact plate 12a to be brought into contact with the rod 40a1 and a distance from the left-right shaft n2 to the contact plate 12b to be brought into contact with the rod 40a2 vary. Therefore, according to the principle of leverage, for the same amount of movement of the seat 2, the displacement of the cylinder 40 increases as the cylinder 40 is moved upward. Consequently, a reaction force increases. On the other hand, the displacement of the cylinder 40 decreases as the cylinder 40 is moved downward; therefore, a reaction force decreases.

(30) As described above, the chair according to the first embodiment includes the return force generation mechanism 4 configured to generate a return force in a direction to return the seat moved from the reference position P at least in the front-back direction to the reference position P. The return force generation mechanism 4 includes the cylinder 40 as the elastic member configured to increase the return force for returning the seat to the reference position P as an amount of movement of the seat from the reference position P increases.

(31) Such a chair is different from a conventional chair movable only backward in that the chair according to the first embodiment is movable in the opposite direction, i.e., movable forward; therefore, increasing a posture changeable range. Further, at the time of either forward or backward movement of the seat 2, the center of the gravity of the seat is likely to shift downward as the seat moves. In this case, the force to shift upward the center of gravity that has been shifted downward is needed to return the seat to the reference position P. Accordingly, the return force is set so as to increase in accordance with the amount of either forward or backward movement of the seat 2 from the reference position P. With such a configuration, the seat 2 can stop at an appropriate position in a balanced manner, or the assist force for allowing a sitting person to change his/her posture can be obtained from the return force generation mechanism 4. Consequently, according to the chair of the present invention, the sitting person can be appropriately seated not only in a normal sitting posture in a state where the chair is located at or adjacent to the reference position P or in a backward tilted posture when the seat is moved backward, but also in a forward tilted posture when the seat is moved forward. As a result, the chair allowing the sitting person not to easily get tired even when being seated for a long time can be realized.

(32) Further, the reference position P is located midway in the front-back movable range, and is a position when a person is not seated, and the seat 2 is stationary on that the elastic force in the front-back direction is zero or balanced at the reference position P. Consequently, the smooth behavior of the seat located from a position adjacent to the reference position P can be effectively realized, and in addition, at the time of the forward or backward movement of the seat from the reference position P, an initial reaction force can be appropriately applied.

(33) Further, the return force generation mechanism 4 is configured to variably adjustable an elastic biasing force. Therefore, even if the force required to return the seat to the reference position P increases in accordance with the increase of the physical size of a sitting person, the return force can be adjusted by the adjustment in accordance with the physical size or preference of the sitting person.

(34) Moreover, as illustrated in FIG. 5A, the cylinder 40 as a single elastic member realizes for applying an elastic biasing force toward the reference position P when the seat 2 is located forward of the reference position P, and a mechanism for applying an elastic force toward the reference position P when the seat 2 is located backward of the reference position P. Therefore, the number of components of the cylinder 40 or the like as the elastic member can be reduced, and in addition, the basic function of the present invention can be simply configured.

(35) Also, as illustrated in FIGS. 5B1 to 5B3, the chair is provided with: the cylinder 41 as an elastic member configured to apply an elastic biasing force toward the reference position P when the seat 2 is located forward of the reference position P; and the cylinder 42 as an elastic member configured to apply an elastic force toward the reference position P when the seat 2 is located backward of the reference position P. The elastic biasing forces are separately set. In such a case, even for the same sitting person, the way that the center of gravity shifts downward at the time of the forward movement of the seat differs from the way that the center of gravity shifts downward at the time of the backward movement of the seat. Therefore, likewise, the force required to return the seat at the time of the forward movement differs from the force required to return the seat at the time of the backward movement. However, with the above-mentioned configuration, an appropriate usage environment can be offered suitably with each of directions.

(36) Additionally, in FIG. 1, a portion of supporting positions of the shafts n1 to n4 is changed in the front-back direction and thereby an initial displacement of the elastic member may be changed so that the elastic biasing force is variably adjustable.

(37) Further, as illustrated in FIG. 6, the initial position of the elastic member is changed so that the displacement of the elastic member 40 due to the positional change of the seat 2 is changed; therefore, repelling force properties of the elastic member 40 are variably adjustable. In such a case, without changing the reference position, a return force can be changed by changing a lever ratio.

(38) Furthermore, as in the first embodiment, the backrest 3 is provided backward of the seat 2, and the backrest 3 and the seat 2 are movable in conjunction with each other in the front-back direction. In this case, the seat 2 is configured such that a movement end inclines downward in accordance with the amount of movement. Therefore, the chair with appropriate usability including a forward or backward tilted posture can be realized.

(39) Moreover, the seat 2 is movably supported in the front-back direction and the left-right direction by the front-back movement mechanism 6 and the left-right movement mechanism 7 that are separate mechanisms. The separate return force generation mechanism 5 for left-right direction is also provided. Therefore, the seat 2 is independently movable not only in the front-back direction and but also in the left-right direction. In addition, the separate return force generation mechanism 4, 5 for left-right direction is provided. Therefore, the seat 2 can be smoothly moved and more various usages of the seat 2 can be offered.

(40) In this case, the left-right return force generation mechanism 7 is configured to shift the center of gravity of the seat 2 upward in accordance with the movement of the seat 2 from the reference position P. When the seat 2 is located at the reference position P, the center of gravity of the seat is located at the lowest position. When the seat 2 is moved right or left, the center of gravity is shifted upward. Thus, without the application of an elastic member or the like, a return force due to gravity can be automatically obtained. Also, the return force is appropriately suitable for the weight of a sitting person.

(41) In addition, the foregoing elastic member is not limited to a spring.

Second Embodiment

(42) Next, an example where an extension spring is applied to an elastic member configuring an elastic return mechanism will be described with reference to FIGS. 8 to 12.

(43) The chair according to a second embodiment of the present invention is different from the chair according to the first embodiment mainly in a front-back movement mechanism 206 and a first elastic force return mechanism 204 for front-back direction, and is substantially the same as the chair according to the first embodiment regarding the left-right movement mechanism and the second return force generation mechanism for left-right direction. Therefore, differences will be mainly described below.

(44) The front-back movement mechanism 206 includes a front link member 261 having a lower end pivotally supported around a left-right shaft s1 by a support base 212, and a guide hole t1 provided in the support base 212 and formed in an upward recessed shape inclined downward from the front side toward the back side. With respect to the illustrated seating part 2 located at the reference position P, an upper end of the front link member 261 is attached in a forward tilted posture to a bracket 221 at the front end of the seat 2 to be pivotal around a left-right shaft s3. An intermediate position of the guide hole t1 is engaged with a left-right shaft s4 provided at the back end of the seat 2. In other words, when the seat 2 is moved forward from the reference position P as illustrated from a state of FIG. 9 to a state of FIG. 10, the front link member 261 is brought into a further forward tilted posture and the left-right shaft s3 is moved.

(45) In addition, the left-right shaft s4 located on the back side is lifted forward and upward along the guide hole t1. Thus, the seat 2 is tilted forward. Meanwhile, when the seat 2 is moved backward from the reference position P as illustrated from a state of FIG. 9 to a state of FIG. 11, the front link member 261 is brought into an upright posture and the left-right shaft s4 located on the back side is moved backward and downward. Thus, the seat 2 is tilted backward.

(46) In addition, the first return force generation mechanism 204 is configured such that an extension spring 241 as a single elastic member realizes a mechanism for applying an elastic biasing force toward the reference position P when the seat 2 is located forward of the reference position P, and a mechanism for applying an elastic force toward the reference position P when the seat 2 is located backward of the reference position P. The spring 241 is attached between a link member 263 provided continuously with the upper end of the link member 261 to integrally rotate with the link member 261 around the left-right shaft s3, and a bracket 222 provided on a lower surface of the seat 2. When the seat 2 is moved forward as illustrated from a state of FIG. 9 to a state of FIG. 10, the spring 241 is pulled in a bent manner such that the link member 263 and the spring 241 project upward. Therefore, the spring 241 stores a backward return force. Meanwhile, when the seat 2 is moved backward as illustrated from a state of FIG. 9 to a state of FIG. 11, the spring 241 is pulled backward in a bent manner such that the link member 263 and the spring 241 project downward. Therefore, the spring 241 stores a forward return force. In other words, even when the seat 2 is moved either forward or backward from the reference position P, the spring 241 is pulled. In addition, the reference position is obtained in a state where the link member 263 and the spring 241 are linearly arranged.

(47) As described above, the chair according to the second embodiment includes the return force generation mechanism 204 configured to generate a return force in a direction to return the seat 2 moved from the reference position P at least in the front-back direction to the reference position P. The return force generation mechanism 204 includes the spring 241 as the elastic member configured to increase the return force for returning the seat to the reference position P as the amount of movement of the seat from the reference position P increases. Therefore, the appropriate return force is obtained from the return force generation mechanism 204. Consequently, a sitting person can be appropriately seated not only in a normal sitting posture in a state where the seat is located at or adjacent to the reference position P or in a backward tilted posture when the seat is moved backward, but also in a forward tilted posture when the seat is moved forward. As a result, the chair allowing a sitting person not to easily get tired even when being seated for a long time can be realized.

(48) Also, in the chair according to the second embodiment, the single elastic member 204 realizes a mechanism for applying an elastic biasing force toward the reference position P when the seat 2 is located forward of the reference position P, and a mechanism for applying an elastic force toward the reference position P when the seat 2 is located backward of the reference position P. Therefore, the number of components of the elastic member can be reduced, and in addition, the basic function of the present invention can be simply configured. Further, the extension spring is applied and thereby a large movable range can be secured and a flexible movement can be realized.

(49) Furthermore, the chair according to the second embodiment includes an initial position adjustment mechanism 40z2 configured to change an initial position of the spring 241 as the elastic member. The initial position adjustment mechanism 40z2 is provided with a function to move up/down the bracket 222 supporting the spring 241 and change an attachment position of the spring 241 to the bracket 222. In accordance with the adjustment of the attachment position of the spring, the link member 263 is rotated together with the link member 261 from a state of FIG. 9, and the horizontal shaft s4 located on the back side is moved backward and downward along the guide hole t1. Therefore, the reference position P of the seat 2 shifts backward.

(50) Thus, the reference position is effectively adjustable with the use of the return force adjustment mechanism 204.

(51) Also, an initial displacement of the elastic member may be surely changed to change the reference position.

(52) Moreover, as illustrated in FIG. 13, a grip 140G is operated to project or retract a retainer 140b1, and thereby an initial compressed state may be changed to change the amount of an initial compression of a spring 140c of a cylinder 140. In FIG. 13, the grip 140G and the retainer 140b1 are connected by a threaded shaft 140R having an external thread, and the external thread of the threaded shaft 140R is screwed with an internal thread provided on the cylinder 140. Thus, a spring reaction force according to the amount of operation of the grip can be applied to a rod 140a2. Such a configuration is effectively applicable to the cylinder of FIG. 5A or the like.

(53) Some embodiments of the present invention are described above; however, specific configurations of respective components may not be limited only to the foregoing embodiments. Various modifications can be made to the configurations without departing from the scope of the present invention.

(54) For example, the reference position is not necessarily balanced at an intermediate position in the front-back direction and may be obtained in such a way that the seat is elastically pressed at a front limit position in a movable range. In this case, the chair is configured so as not to be movable forward from the reference position.

INDUSTRIAL APPLICABILITY

(55) The present invention is applicable to a chair suitably used in an office or the like.

DESCRIPTION OF REFERENCE NUMERALS

(56) P: reference position 2: seat 4: first return force generation mechanism (front-back direction) 40, 41, 42: elastic member 5: second return force generation mechanism (left-right direction)