JP4960670B2 - Chair - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a chair which makes a lumbar support portion of a backrest move forward by sitting and can make a device compact and as well as prevent it from rattling. <P>SOLUTION: The seat of the chair is supported by a front support link 7 and a rear support link 14 which can rearward incline. The front support link 7 and the rear support link 14 rearward incline and the seat 2 is lowered and rearward moves and the lumbar support portion 17a of the backrest 3 moves forward when a person sits on the chair. Therefore the lumbar support function can be exhibited even though the person shallowly sits. Returning springs 36 for returning the seat 2 torsion springs in which the load acts on coils in a winding direction and fit into bearing bodies 29 from the outside while being stored in the hollow portion of the front support link 7. The returning spring 36 is compactly stored and the rattling of the seat 2 can be prevented by storing the same in the front support link 7. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a chair in which a lumbar support portion of a backrest can move forward by sitting.

  There are many chairs in which the seat and the backrest move together. The most common is a synchro-type chair in which the seat tilts backwards and retracts when a person leans on the backrest. As an example, Patent Document 1 discloses that a seat is supported by front and rear support links, and the backrest is attached to a frame that rotates around a front support link. The conventional synchro-type chairs including Patent Document 1 are those in which the seat is interlocked with the rocking of the backrest, and the seat and the backrest basically do not move when the person is seated.

  On the other hand, Patent Document 2 discloses a chair in which when a person sits shallowly, the seat tilts forward about the substantially middle part of the front and back, and the backrest greatly tilts in conjunction with the forward tilt of the seat (note that In Patent Document 2, the backrest tilts forward even when seated deeply, but the degree is smaller than when seated shallowly, and the backrest does not tilt forward when seated in a state where the seat does not tilt.

In this Patent Document 2, when a person sits shallowly on the front part of the seat, the backrest is greatly inclined forward, and the person's back is pushed at the upper part of the backrest. Then, the user feels uncomfortable because of the forward turning state, and the sitting position is shifted backward. The chair of Patent Document 2 is a kind of chair for making a person (especially a child or a student) to take a correct sitting posture by giving discomfort when a person sits on the front end of the seat. It is.
Japanese Patent No. 3638855 Japanese Examined Patent Publication No.46-27517

  For example, when a person uses a chair to perform various operations in an office or the like, he does not necessarily sit deeply, but often sits shallowly. On the other hand, in recent chairs, the importance of the lumbar support function that supports the waist from the back has been pointed out in order to reduce the burden on the body of the person sitting. In other words, if the lumbar part is supported from the rear, the person is held in a state where the back muscles are stretched, so that the burden on the lumbar spine and pelvis is remarkably reduced. Therefore, in recent years, a chair with a lumbar support that supports a human lumbar portion in a concentrated manner has become widespread.

  However, when a person sits shallowly, there is a gap between the backrest and the waist, so the person is prone to a stooped back, which increases the burden on the lumbar spine and causes back pain, and the internal organs are compressed, causing gastrointestinal disorders There is a risk of causing problems. Conventionally, this problem has not been recognized, including Patent Documents 1 and 2. Therefore, the applicant of the present application has proposed a chair that can exhibit a lumbar support function even in a case where the user sits shallowly in Japanese Patent Application No. 2005-237660.

  The invention of the present application is an extension of the invention of the prior application and intends to provide an improved chair while maintaining the same function as the invention of the prior application.

Chair of the present invention is provided with a seat and backrest, below the said seat being arranged seat support, and the seat and the seat support to their seats及 beauty seat support and the relative rotation It is connected via a front support link and a rear support link.When a person is seated, each support link tilts backward, the seat descends while retreating, and each support link returns to the position before tilting backward. includes a use spring skip back to further the backrest in a state in which the seat is lowered and retracted may post tilted against the locking spring.
On the other hand, the lower portion of the backrest has become a lumbar support portion capable of supporting human lumbar seated, the seat back, and Attach at least in the lumbar support portion back support so as to advance the dynamic is When each support link by seating people post tilted against the spring return the at least the lumbar support portion of the backrest via a connecting kinematic device is advanced dynamic.

In the invention of claim 1, the return spring is a torsion spring that is wound in a coil shape and acts so that a load entrains the coil. The torsion spring includes the front support link or the rear support link. It arrange | positions so that the shaft center of the attached rotating shaft may be wound from the outer side.

The invention of claim 2 is the embodiment of the invention of claim 1 embodied as a suitable form for a synchro-type chair. The invention extends to the rear of the base and extends to the rear of the base. and it includes a back support frame which is linked to the rear tilted base and the locking spring for elastically supporting the tilt after the back support frame.

A slide shaft that moves backward against the elasticity of the locking spring is connected to the base, and the front support link is attached to the slide shaft so that it can tilt backward, while the back support frame the rear support link is mounted for the rear tilt in.

Furthermore, the front support link has a slide shaft coaxial with the cylindrical portion, while the return spring in the cylindrical portion of the front support link is built, the interlocking device, the support link An interlocking spring that allows the backrest lumbar support portion to move backward while being rearwardly tilted is disposed, and the rear support link is urged backward by the interlocking spring.

  In claim 2, the return spring and the interlocking spring exist, but the spring force of the return spring acting on the front support link is larger than the spring force of the interlocking spring acting on the rear support link. It is set to be.

  In the invention of claim 2, the spring is incorporated in the front support link in the synchro-type chair, but as another configuration of the present invention, it is also possible to incorporate the spring in the rear support link in the synchro-type chair. . Alternatively, it is possible to incorporate a spring in the rear support link in a non-synchronous chair.

  The present invention includes both a mode in which the seat is directly attached to the support link and a mode in which the seat is indirectly attached to the support link with a frame-like or plate-like intermediate member. Similarly, the rear link includes both a mode in which the rear link is directly connected to the back support frame and a mode in which the rear link is attached to the member.

  In the present invention, the seat descends while retreating by the rotation of the support link (translates diagonally rearward), but the sum of the retreat dimension of the seat and the advance dimension of the lumbar support portion is set to about 100 mm. Is preferred.

  Various springs such as a compression coil spring, a tension spring, a leaf spring, and a gas spring can be used as the spring for returning the support link to the original position (or returning the seat to the original position). The springs require a certain arrangement space.

On the other hand, the present invention uses a torsion spring that acts so that a load entrains a coil, and this torsion spring is arranged so as to wind the axis of the rotating shaft. The space is very small, so that the return spring can be arranged compactly. As a result, the appearance of the chair can be refreshed, and for example, a problem that the return spring interferes with other members when the chair is assembled can be prevented.

  The chair according to the invention of claim 2 has a rocking function in addition to the lumbar support function when seated shallowly. In addition, since the interlocking device is equipped with a spring for interlocking, it is possible to push the lumbar support part in a shallow sitting state to shift the body backward, or to sit deeply from the beginning without moving the lumbar support part forward Therefore, it is possible to accurately meet the user's request.

  By the way, the support link is connected to the seat or the like with a pin (shaft), but from the point of processing accuracy, there is some clearance between the support link and the pin, or between the pin and the bearing part, Also, the clearance may increase during use. For this reason, there is a risk of looseness in the seat and the support link, which may cause discomfort to the person when sitting.

  On the other hand, in the second aspect of the invention, the rear support link is pushed to the backward tilted position by the elastic restoring force of the interlocking spring, while the front support link is set to the return position by the return spring. That is, the front support link and the rear support link are biased in opposite directions. In other words, the front support link and the rear support link are in a tension relationship, so that no backlash occurs between the front support link and the rear support link and the seat. This is one of the advantages of claim 2.

  Further, in claim 2, since the return spring is built in the hollow portion of the front support link, the return spring is made more compact, and the return spring is damaged because the front support link serves as a cover. And there is no movement of the return spring. This is also the advantage of claim 2. Further, as another advantage of claim 2, there is an advantage that the return spring can be made compact (downsized). This point will be explained based on the embodiment.

  Next, an embodiment of the present invention will be described with reference to the drawings. This embodiment is applied to a rotary chair for office use or the like.

(1). Outline of Chair First, an outline of a chair will be described mainly with reference to FIGS. 1 is an overall perspective view of the chair, FIG. 2A is a front view of the chair, FIG. 1B is a side view of the chair, FIG. 3 is a rear view of the chair, and FIG. 4 is a partial plan view of the chair. 5 is a partially broken side view showing the support means of the seat, FIG. 6 is a plan view taken along VI-VI in FIG. 5, FIG. 7A is a partial perspective view of the base, and FIG. FIG. 7C is an exploded perspective view of the members constituting the member, and FIG. 7C is a sectional view taken along the line VIIC-VIIC of FIG. 5 with the seat attached.

  The chair includes a leg 1, a seat 2, and a backrest 3. The leg 1 includes a group of branch legs 4 extending horizontally and a leg column (gas cylinder) 5, and a base 6 made of a metal plate opened upward is attached to the upper end of the leg column 5. For example, as shown in FIGS. 5 and 7C, the seat 2 includes a resin seat inner shell (seat plate) 2a and a cushion 2b stretched on the upper surface thereof.

As clearly shown in FIG. 7C, the front portion of the seat 2 is connected to the base 6 via left and right front support links 7 and left and right laterally long first support shafts 8. The first support shaft 8 corresponds to the slide shaft described in claim 2 . A pair of left and right front brackets 9 sandwiching the front support link 7 from both the left and right sides are integrally formed at the front portion of the seat inner shell 2a, and the front bracket 9 and the upper portion (bearing portion) 7a of the front support link 7 Are connected by a front pin 10 so as to be relatively rotatable. The seat 2 is gently recessed in an upward concave shape when viewed from the front.

  A pair of left and right swing frames 11 are disposed on both left and right sides of the base 6 so as to be tilted backward as viewed from the side and extend rearward of the base 6. 12 is fixed (the back frame 12 is an example of a back support described in claim 1). In this case, as shown in FIG. 11, a substantially upward boss portion 11 c is provided at the rear end of the swing frame 11, and this boss portion 11 c is fitted into a hole (not shown) provided in the back frame 12. .

  In the present embodiment, the swing support frame 11 and the back frame 12 constitute the back support frame described in the claims. The swing frame 11 and the back frame 12 can be integrated with each other, and the back frame 12 can be rephrased as a back column.

  The swing frame 11 is connected to the rear portion of the base 6 by a second support shaft 13 so as to tilt backward about the front end portion thereof. The rear portion of the seat 2 and the swing frame 11 are connected to each other via a pair of left and right rear support links 14 so as to be relatively rotatable. Therefore, in this embodiment, the swing frame 11 also constitutes a part of the seat support described in the claims.

  The front support link 7 and the rear support link 14 are slightly tilted backward in a side view in a neutral state (basic position) where no person is seated. For this reason, when the person is seated, the support links 7 and 14 are tilted backward. Accordingly, the seat 2 moves backward (or slides obliquely backward) while descending with almost no change in the posture in side view. Both support links 7 and 14 are preferably made of metal.

A pair of left and right rear brackets 15 sandwiching the rear support link 14 from the left and right are integrally formed at the rear portion of the seat inner shell 2a, and the rear bracket 15 and the rear support link 14 are connected by a left and right longitudinal rear pin 16. Yes. The front support link 7 and the rear support link 14 form a parallel support link mechanism. Relationship between the rear support link 14 and the swing frame 11 is discussed later.

  The backrest 3 is composed of only a resin-made back plate 17 having flexibility. Accordingly, in the present embodiment, the backrest 3 and the back plate 17 are synonymous. A large number of longitudinal ribs 18 and 19 are formed at substantially equal intervals on the front and rear surfaces of the back plate 17. The back plate 17 is gently curved in a forward-facing concave shape in plan view in both upper and lower portions. Further, the lower end of the back plate 17 is located near the seat 2 in the non-sitting state, and the lower portion of the back plate 17 is a lumbar support portion 17a that is curved in a forwardly convex shape with a loose curvature in a side view. .

The back plate 17 has an upper end portion attached to the back frame 12 so as not to be separated. On the other hand, a vertex portion of the lumbar support portion 17a is connected to the fifth interlocking link 20, and a lower end portion of the lumbar support portion 17a is a fourth end portion. It is connected to the interlocking link 21, and when the seat 2 is lowered and retracted, the lumbar support portion 17a moves forward greatly. The fourth interlocking link 21 and the fifth interlocking link 20 constitute a part of the interlocking device .

Reference numeral 21 'shown in FIG. 6 is a member constituting the locking equipment for holding the state be seated not move the seat 2. If you always people there is a deeply sit habit to use is, can I had been held in the locked equipment Therefore, so as not to move the seat 2. Details of each part will be described below.

(2) Details of the Peripheral Part of the Base First, the configuration of the part centered on the base 6 will be described mainly with reference to FIGS. 8 is a partially broken separated view showing the mounting structure of the front support link 7, FIG. 9A is a cross-sectional view taken along line AA of FIG. 8 in the assembled state, and FIG. 8B is the assembled state. It is BB sectional drawing of FIG.

  As described above, the base 6 is formed in a box shape opened upward, and the reinforcing bracket 25 is fixed to the inside and the rear portion thereof. The bush 26 fixed to the base 6 and the reinforcing bracket 25 (see FIG. 5). ) Is attached to the upper end of the leg support 5.

  In the front part of the left and right side plates of the base 6, there is an elongated hole 27 having a side-view shape in which the first support shaft 8 is slidably fitted in the front-rear direction. A resin bush 28 is vacated in the long hole 27. A bearing body (slider) 29 is fitted to the bush 28 so as not to rotate from the outside so as to be slidable. The first support shaft 8 is fitted to the left and right bearing bodies 29. As shown in FIG. 7C, the first support shaft 8 is fixed to the bearing body 29 with a washer 30a and a screw 30b. The bearing body 29 is made of metal or resin.

  Inside the base 6, two left and right locking springs (compression coil springs) 31 are arranged in a posture extending in the front-rear direction, and a front spring receiver 32 is fitted into the shaft 8 from the rear side. The reinforcing bracket 25 is formed with a receiving wall 25 a that supports the fixed rear spring receiver 33. When the handle 34a (see FIG. 2A) provided on the operation rod 34 is rotated, the initial elastic force of the locking spring 31 changes.

For example, as shown in FIG. 7 (C), the front support link 7 has a portion of an inclined posture rising obliquely outward in a front view, and the lower end portion is a cylindrical portion 7a extending horizontally. The upper part 7b is a bearing part. Further, a portion of the front support link 7 between the upper portion 7b and the horizontal portion 7a is opened outward (to make the thickness as uniform as possible).

  As shown in FIG. 7 (B), the bearing body 29 includes a rectangular portion 29a that is slidably fitted to the bush 28 so as to be slidable, and a small-diameter cylindrical portion 29b that rotatably enters the cylindrical portion 7a of the front support link 7. It has. In addition, a pair of stopper portions 29c extending outward in a state of being spaced from the small diameter cylindrical portion 29b is formed at the base portion of the small diameter cylindrical portion 29b. The pair of outwardly facing stopper portions 29c are disposed on both sides of the axis.

A return spring 36 is fitted into the small diameter cylindrical portion 29 b of the bearing body 29. The return spring 36 is a torsion coil spring that acts to wind the coil by a load, and the coil portion is located between the outward stopper portion 29a and the small-diameter cylindrical portion 29b. Further, the return spring 36 has one end portion 36a that contacts the side surface of one outward stopper portion 29c in the bearing body 29, and an outward other end portion 36b that extends parallel to the axis of the coil. .

  For example, as can be easily understood from FIG. 9 (A), a pair of inward contacts that hit the side surfaces of the stopper portion 29c of the bearing body 29 when the front support link 7 rotates are provided inside the cylindrical portion 7a of the front support link 7. A stopper portion 7c is formed, and the inward stopper 7c contacts the outward stopper portion 29c of the bearing body 29, whereby the front support link 7 is rotated by a certain angle (for example, about 50 to 55 degrees). Is allowed.

  Accordingly, a portion of the inner surface of the cylindrical portion 7a in the front support link 7 that is not the inward stopper portion 7c is a groove 35 that allows the outward stopper portion 29c of the bearing body 29 to relatively rotate. In addition, the code | symbol 7d shown in FIG.9 (B) is a stolen hole for making thickness as uniform as possible.

  The length of the inward stopper portion 7 c of the front support link 7 is set to be the same or slightly longer than the length of the outward stopper portion 29 c in the bearing body 29. A stopper groove 37 into which the other end portion 36b of the return spring 36 is fitted on the inner surface of the cylindrical portion 7a of the front support link 7 extends in the axial direction in a state where one inward stopper portion 7c is divided. Is formed.

  Therefore, after setting the return spring 36 at a predetermined position, the front support link 7 is fitted into the small diameter cylindrical portion 29b of the bearing body 29, and the other end portion 36b of the return spring 36 is fitted into the stopper groove 37, and then As shown by the arrow in FIG. 8, the front support link 7 is rotated against the elasticity of the return spring 36, so that the inward stopper portion 7c is positioned so as not to interfere with the outward stopper portion 29c. The front support link 7 can be easily attached to the bearing body 29 by the procedure of pushing in the front support link 7.

  When the return spring 36 is built in the front support link 7 as in the present embodiment, the return mechanism of the front support link 7 becomes compact and the assembly is facilitated. In FIG. 7 (C), the outward stopper portion 29c and the stopper groove 37 are drawn at the same height position, but this is for convenience and the height of the two is actually different. Yes.

  As described above, the support links 7 and 14 extend upward in a posture inclined obliquely outward in a front view. For this reason, even if the lateral width of the base 6 is much smaller than the lateral width of the seat 2, the seat 2 is supported by the support links 7 and 14 at portions close to the left and right ends. For this reason, the seat 2 is allowed to bend and deform in a downward concave shape when a person is seated. The cushioning property is given to the seat 2 by this bending deformation.

  For example, as shown in FIG. 6, the swing frame 11 is fitted to the side plate of the base 6 via the bush 38. The second support shaft 13 is held in the swing frame 11 so as not to be detached by screws or snap rings (not shown). A front and rear long projecting portion 11 a that opens outward is formed at the front end of the swing frame 11. The swing frame 11 is made of metal such as an aluminum die cast product. Of course, it is also possible to employ sheet metal products and resin molded products. Further, the left and right swing frames 11 can be integrally connected at the rear end.

By the way, when a person sits down on a chair, it is common that the thigh hits the front end of the seat 2 first. In some cases, the user sits down after putting both hands on the seat. In this case, it is common to place the hands on the left and right ends of the front end of the seat (otherwise, it is difficult to support the body with the hands). . On the other hand, since the support links 7 and 14 are inclined, as shown in a vector diagram in FIG. 2B, the load acting on the support links 7 and 14 with the seating is a downward component force F1 and a backward force. can be divided into a component force F2, as the seat 3 backward force component is large it tends to descend (support link is likely to rearward tilting.).

If a load is applied directly above the front support link 7, the backward component force acting on the front support link 7 is small, but the backward component force on the rear support link 14 is large. Therefore, when comparing the case where the return spring 36 having the same elastic restoring force is provided on the front support link 7 and the case where the return spring 36 is provided on the rear support link 14, a downward load is first applied to the front portion of the seat 3. under general use conditions, than the case of providing the return spring 36 to the front support link 7, towards the case of a return spring 36 provided on the rear support link 14 is turned seat 2 is easily lowered (That is , the rear support link 14 is easy to tilt backward with a light force.)

In other words, in order to ensure a certain resistance against the downward movement of the seat 2, the return spring is applied to the rear support link 14 in a use state in which a downward load is first applied to the front portion of the seat 2. It is possible to secure a high resistance with a weak spring when the return spring is provided on the front support link 7 rather than the front support link 7. Therefore, when the structure in which the return spring 36 is built in the front support link 7 is adopted, a small return spring 36 can be used. As a result, further downsizing, improvement in assembly efficiency, or cost reduction can be achieved. Can do it. This is also an advantage of claim 2 and this embodiment.

(3) Details of interlocking device Next, details of the interlocking device will be described with reference to FIGS. 10 is an exploded perspective view of members constituting the interlocking device, FIG. 11 is a partially broken plan view centering on the members constituting the interlocking device, and FIG. 12 is a longitudinal side view of the main part.

  For example, as shown in FIG. 10, the interlocking device of the present embodiment includes a metal box-shaped receiving member 41 that opens upward, and a square drive shaft 42 that is fitted to the left and right rear support links 14 so as not to rotate relative to each other. A pair of left and right first interlocking links 43 fitted to the drive shaft 42 so as not to rotate relative to each other, a second interlocking link 46 connected to the first interlocking link 43 via a first pin 45, and a second interlocking link 46 of the third interlocking link 48, the fourth interlocking link 21 connected to the middle part of the third interlocking link 48 in a vertically rotatable manner, and the third interlocking link 48. And a fifth interlocking link 20 connected to the upper end so as to be relatively rotatable.

The fourth interlocking link 21 and the fifth interlocking link 20 have already been described. In the present embodiment, an interlocking link mechanism (interlocking device) is configured by the first to fifth interlocking links. The second interlocking link 46 is made of a metal plate and includes a top plate 46a and left and right side plates 46b. An interlocking spring 49 is disposed below the top plate 46a. This interlocking spring 49 also constitutes a part of the interlocking device.

  For example, as shown in FIG. 10, the receiving member 41 has a left and right overhanging portion 41a which is raised and has a stepped shape in a front sectional view, and as shown in FIG. 11, the left and right overhanging portion 41a is rocked. The moving frame 11 is fixed to the inwardly projecting portion 11b of the moving frame 11 with screws 50. The front end of the left and right side plates 41b constituting the receiving member 41 is a bearing 41b 'having a round hole. The small diameter cylindrical portion 14a of the rear support link 14 is connected to the bearing 41b' via a bush 52. It is fitted so that it can rotate relative to it.

The rear support link 14 is similar in appearance to the front support link 7, but has the following unique structure. That is, first, the above-described drive shaft 42 is fitted to the rear support link 14 so as not to be relatively rotatable, and the drive shaft 42 is held by the rear support link 14 so as not to be detached by screws 53. Next, the rear support link 14 includes an overlapping portion 14 b that overlaps an arcuate upward recess (not shown) formed in the swing frame 11, and comes into contact with the swing frame 11. A stopper portion 14c that restricts the rotation range is formed.

Next, the first interlocking link 43 will be described. A slit groove 43 a that fits into the first interlocking pin 45 is formed at the tip of the first interlocking link 43. Further, as shown in FIGS. 11 and 12 , a protective member 55 made of resin overlaps one surface of the first interlocking link 43.

  Next, the second interlocking link 46 will be described. The rear end portion of the second interlocking link 46 is connected to the receiving member 41 by a support shaft 47. The left and right side plates 46b constituting the second interlocking link 46 have a forward extension 46c, and the first pin 45 is slidably fitted in a long hole 58 formed in the forward extension 46c.

  As described above, the slit 43a of the first interlocking link 43 is fitted in the first pin 45. When the first interlocking link 43 rotates downward, the second interlocking link 46 tilts forward (rotates downward) around the support shaft 47 so that the front end moves downward. As can be understood from FIG. 12, the rotation range of the first interlocking link 43 is restricted by hitting the bottom surface of the receiving member 41.

  A downward piece 59 is formed by cutting and raising the top plate 46a of the second interlocking link 46, and a cylinder 61 is attached to the downward piece 59 and one side plate 46b via a pin 60. The spring 49 is fitted from the outside (in FIGS. 10 and 11, the positions of the holes for forming the downward pieces 59 are displayed in the opposite directions). The interlocking spring 49 is a torsion spring in which a load acts in the coil winding direction, and both the one end portion 49a and the other end portion 49b extend in the tangential direction of the coil. For example, as clearly shown in FIG. 13B, one end portion 49 a of the interlocking spring 49 is in contact with the top plate 46 a of the second interlocking link 46 from below.

  On the other hand, the third interlocking link 48 is connected to the rear portion of the left and right side plates 41b of the receiving member 41 by the support shaft 57 described above, and a forward projecting portion 48a is formed at the lower end of the third interlocking link 48. The other end 49b of the interlocking spring 49 is in contact with the forward projecting portion 48a of the third interlocking link 48 from above. Further, a recess 62 that opens downward is formed in the forward projecting portion 48 a of the third interlocking link 48, and the recess 62 fits into the stopper pin 63 that spans the left and right side plates 46 b of the second interlocking link 46. ing.

  When the second interlocking link 46 rotates downward, the third interlocking link 48 tilts forward about the support shaft 59. Since the forward projecting portion 48 a of the third interlocking link 48 is merely pressed by the interlocking spring 49, the third interlocking link 48 tilted forward is independently tilted against the elasticity of the interlocking spring 49. (Return rotation). Further, the third interlocking link 48 does not tilt forward, and only the second interlocking link 46 can be rotated downward.

  Next, the upper part related to the backrest 3 of the interlocking device will be described. As described above, the interlocking device includes the fourth interlocking link 21 and the fifth interlocking link 20. For example, as shown in FIG. 12, the fourth interlocking link 21 connects the middle part of the third interlocking link 48 with the lower end of the back plate 17. Further, the upper and lower middle portions of the fourth interlocking link 21 and the third interlocking link 48 are connected by a left and right longitudinal pin 64. On the other hand, a pair of left and right lower bearing portions 65 sandwiching the fourth interlocking link 21 from both left and right sides project from the lower end of the left and right intermediate portion of the back plate 17, and the fourth interlocking link 21 and the lower bearing portion 65 are connected to each other. They are connected by a pin 66 that is long in the left-right direction.

  Although the left-right width dimension of the fourth interlocking link 21 is small, as shown in FIG. 3, the fifth interlocking link 20 has a large left-right length that is slightly smaller than the left-right width dimension of the back plate 17, and The fifth interlocking link 20 has a shape that is bowed in a forwardly concave shape in plan view. Then, as shown in FIG. 12, a pair of left and right bearing brackets 67 is provided at the left and right intermediate part of the fifth interlocking link 20, and the bearing bracket 67 and the upper end of the third interlocking link 48 are connected by a left and right longitudinal pin 68. Has been.

  Also, as shown in FIG. 10, bearing pieces 69 projecting forward are formed at the left and right ends of the fifth interlocking link 20, while the left and right ends of the lumbar support portion 17a of the back plate 17 Two upper bearing brackets 70 that fit into the bearing pieces 69 of the five interlocking links 20 are projected, and the upper bearing brackets 70 and the bearing pieces 69 are connected by left and right longitudinal pins 71.

  The back plate 17 is connected by a fifth interlocking link 20 in a state where both ends are supported. Accordingly, the lumbar support portion 17a of the back plate 17 is allowed to be deformed so as to sink backward in plan view due to the body pressure of the person who is seated.

The back plate 17 is made of a rubbery synthetic resin, and in a single state, the shape of the side view and the plan view can be greatly changed by a person holding and applying force with both hands. It has that degree of flexibility. A number of vertically long ribs 18 and 19 are formed on both front and rear surfaces of the back plate 17. Although details are omitted, as shown in FIG. 2B, the upper portion of the back plate 17 is fitted to the upper portion 12a of the back frame 12, and the back plate 17 is in a state in which the lumbar support portion 17a can move forward. It is attached to the upper part 12a of the back frame 12.

(4). Explanation of movement, etc. The whole movement of the chair described above is shown in FIG. That is, when a person sits down, the front and rear support links 7 and 14 tilt backward, and the seat 2 moves backward while descending. When the drive shaft 42 rotates in conjunction with the rearward tilt of the rear support link 14, the first interlocking link 43 tilts backward, and the rotation of the first interlocking link 43 causes the second interlocking link 46 and the interlocking spring 49 to rotate. Is transmitted to the 35th interlocking link 48, and the third interlocking link 48 tilts forward. As a result, the lumbar support portion 17a of the back plate 17 moves forward. This embodiment is retracted dimension of the seat 2 is set to 50mm extent.

Since the swing frame 11 and the back frame 12 do not tilt backward only when a person is seated, the upper end portion of the back plate 17 is held so as not to move back and forth. Then, the fourth interlocking link 21 and the fifth interlocking link 20 are rotated so that the lumbar support portion 17a of the back plate 17 can move forward (when the lumbar support portion 17a moves forward , It is also possible to slide or advance the upper end of the backrest 3 downward).

  The lumbar support portion 17a moves forward by rotating the back plate 17 around its upper end. Therefore, the lumbar support portion 17a tends to increase in height while moving forward. In the neutral state where no person is seated, the lumbar support portion 17a is positioned considerably below. However, when a person is seated, the lumbar support portion 17a is lowered and the lumbar support portion 17a moves forward and becomes higher. The support portion 17a has an optimum height for supporting the area around the lumbar vertebra (especially the third lumbar vertebra) of the seated person.

  It is possible to kill the function of the interlocking mechanism so that the lumbar support portion 17a does not move forward even if the seat is retracted and lowered, and the switching device for turning the interlocking function ON / OFF in this way is the third interlocking function. This can be achieved by switching the link 48 between the forward tiltable state and the forward tiltable state.

(5). Other Variations The present invention can be embodied in various ways other than the above embodiment. For example, the return spring can be fitted on the first support shaft 8 and the drive shaft 42 of the above-described embodiment. It is also possible to fit the return spring to the cylindrical portion of the support link from the outside. Further, needless to say, the backrest can be structured such that a cushion material is stretched on a back inner shell made of synthetic resin.

  The specific structure of the interlocking device can be embodied in various ways. For example, it is not always necessary to employ an interlocking link mechanism. For example, it is possible to change the downward movement of the seat by sitting to the pulling force of the wire and push the lumbar support part by pulling the wire.

Furthermore, the application object of the present invention is not limited to a rotary chair with casters, but can be applied to other types of chairs such as a chair having a frame structure for legs. Further, the shape and material of the back support frame can be freely set as necessary. The entire backrest can be moved forward by tilting the support link, or the lumbar support portion can be particularly advanced while the backrest moves forward as a whole.

It is a general perspective view of the chair according to the implementation embodiments. (A) The front view of a chair, (B) is a side view of a chair. It is a rear view of a chair. It is a partial top view of a chair. It is a partially broken isolation | separation side view which shows the support means of a seat. FIG. 6 is a plan view taken along the line VI-VI in FIG. 5. (A) is a partial perspective view of the base, (B) is an exploded perspective view of members constituting the first support link mechanism, and (C) is a sectional view taken along the line VIIC-VIIC in FIG. 5 with a seat attached. . It is a partially broken isolation | separation top view of a bearing body and a front support link. (A) is the sectional view on the AA line of FIG. 8 in an assembly state, (B) is sectional drawing on the BB line of FIG. 8 in an assembly state. It is a separation perspective view of the member which constitutes an interlocking device. FIG. 12 is a partially cutaway plan view of a main part of the interlocking device, and FIG. It is a vertical side view of the principal part of an interlocking device. It is a frame structure diagram showing movement of a seat and a backrest.

DESCRIPTION OF SYMBOLS 1 Leg 2 Seat 3 Backrest 6 Base which comprises a seat support body 7 Front support link 7a Cylindrical part 7c Inward stopper part 8 The 1st spindle (slide shaft) as an example of a rotating shaft
DESCRIPTION OF SYMBOLS 11 Swing frame which comprises the back support frame which is an example of a back support body 12 Back frame which comprises the back support frame which is an example of a back support body 13 2nd spindle
14 Rear support link 17 Back plate 29 Bearing body 29a Small diameter cylindrical portion 29c Outward stopper portion 31 Locking spring 36 Return spring 49 Interlocking spring

Claims (2)

With a seat and a backrest,
Below the said seat being arranged seat support, the seat and the seat support, it is connected via a front support link and the rear support link to their seats及 beauty seat support and the relative rotation , together with the seat and tilted backward with human sits each support link is retracted while descending, has a use spring skip back to be back the respective support link on the attitude of the rear 傾前, further, the seat While the backrest can be tilted back and forth against the locking spring ,
The lower part of the backrest has become a lumbar support portion capable of supporting human lumbar seated, the seat back, and Installing least the lumbar support portion is taken up in the back support so as to advance the dynamic, human When each support link by seating of post tilted against the spring return the at least the lumbar support portion of the backrest is moved forward movement through the communicating operated device,
The structure
The return spring is a torsion spring that is wound in a coil shape and acts so that a load entrains the coil, and the torsion spring has an axis of a rotating shaft to which the front support link or the rear support link is attached. Arranged to wind from the outside,
Chair. A base provided at the upper end of the leg, the back support frame which is linked to the rear tilt to the base extends behind the base, and the locking spring for elastically supporting the tilt after the back support frame Has
A slide shaft that moves backward against the elasticity of the locking spring is connected to the base, and the front support link is attached to the slide shaft so that it can tilt backward, while the back support frame is attached to the back support frame. wherein Ri Contact rear support link is mounted for the rear tilt,
Furthermore, the front support link has a slide shaft coaxial with the cylindrical portion, while the return spring in the cylindrical portion of the front support link is built, the interlocking device, the support link An interlocking spring that allows the lumbar support portion of the backrest to move backward while being tilted backward is disposed, and the rear support link is urged in the backward tilting direction by the interlocking spring,
The chair according to claim 1.

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