JP2017153740A - Chair - Google Patents

Abstract

In a chair in which the front part of a seat is formed as a deformation-permitting part and the deformation-permitting part is wound downward to adjust the depth of the seat, the structure of the operation mechanism is simplified, and the seat is also reliably wound. To do. A seat has an inner shell, a cushion material, and a skin material, and an appropriate range on the front side is a deformation allowing portion. A horizontally long rotating shaft 7 is rotatably attached to an outer shell 5 that supports the seat 1, and a cylindrical body 9 is fixed to the rotating shaft 7. A rearward extension 4 a of the skin material 4 is connected to the outer periphery of the cylindrical body 9. When the rotating shaft 7 is rotated by operating the handle, the skin material 4 is pulled obliquely downward, and the deformation allowing portion 1a is wound downward. The structure can be simplified because of the entrainment deformation using the skin material 4. [Selection] Figure 1

Description

  The present invention relates to a chair capable of adjusting the longitudinal length (depth) of a seat.

  In the chair, the position of the front end of the seat can be adjusted according to the user's physique and preference. The adjusting means includes a method of moving the seat as a whole back and forth, and a method of forming a front portion of the seat in the deformation-permitting portion, and winding (or bending) the deformation-permitting portion downward. In this method, since the position of the rear end of the seat is constant, there are advantages such as avoiding interference with the backrest and preventing deterioration of aesthetics due to retreat.

  Then, as a means for bending the deformation allowable portion of the seat downward, a slider is disposed below the seat, and for example, as shown in Patent Documents 1 to 9, the front end portion of the slider and the front end portion of the seat are connected, In most cases, the deformable portion of the seat is wound downward or bent by pulling the slider.

  On the other hand, the applicant of the present application has proposed a chair that can maintain high support stability even when the seat is extended by supporting the deformation allowing portion from below with a support member (Patent Document 10).

European Patent EP10866635A European Patent EP1093737B German DEY 9300180 publication China CNY2457915 German DEA19531354 German DEB102007047028 European Patent EP2721956 US Patent US8210611 German DEA 19843550 gazette JP2013-2080A

  As described above, conventionally, the seat deformation permitting portion is usually pulled directly back by a slider, but the seat generally has a structure in which a cushion material is stretched on a resin inner shell (seat plate). Since the deformation allowing portion and the heel have a certain degree of strength so as to support the body, the deformation may not be smooth by simply pulling it backward.

  With regard to this point, Patent Document 10 facilitates deformation by forming a plurality of horizontally long slits in the inner shell, or facilitates deformation by forming a plurality of horizontally long grooves on the lower surface of the cushion material. With such a device, the chair embodying Patent Document 10 can easily adjust the depth of the seat.

  The present invention has been made against the background of such a situation, and mainly intends to provide an improved technique for an operation mechanism that transmits the movement of the operation tool to the deformation-allowing portion of the seat.

  The present invention includes various configurations specified in each claim. These inventions are premised on a basic configuration that “an appropriate range near the front of the seat is a deformation-permitting portion that bends downward by operating the operation tool”.

  And in invention of Claim 1, in the said basic composition, the surface of the said seat is comprised by the skin material, and the said deformation | transformation is carried out by pulling the front-end part of the said skin material in response to operation of the said operation tool. The permissible portion is wound or bent downward.

  According to a second aspect of the present invention, in the basic configuration described above, an operating body that rotates or slides by operation of the operating tool is provided below the seat, and the distal end portion of the seat and the operating body can be bent and deformed. Connected with joints.

  According to a third aspect of the present invention, in the above basic configuration, an operating body that slides back and forth by the operation of the operating tool is provided below the seat, and a front end of the operating body is formed in a guide portion formed at a front end portion of the seat. On the other hand, the guide portion of the seat is formed in an inclined shape that moves relative to the front end of the operating body and bends the deformation allowing portion of the seat downward when the operating body is retracted.

  According to a fourth aspect of the present invention, in the above basic configuration, an operating body that slides back and forth by the operation of the operating tool is provided below the seat, and the operation is performed between a front end of the operating body and a front end portion of the seat. An intermediate member is provided that turns or rotates when the body is retracted to bend the deformation allowing portion of the seat downward.

  According to a fifth aspect of the present invention, in the basic configuration described above, an operating body that rotates about a longitudinal slide center or a left-right longitudinal axis by operation of the operation tool, and a movement of the operating body below the seat. A slide-type or rotary-type interlocking body that pulls the front end portion of the seat diagonally backward and downward is disposed.

  According to a sixth aspect of the present invention, in the basic configuration described above, the operating tool rotates about a horizontally long axis. It should be noted that the inventions of the above-mentioned claims are not necessarily rejected, and some can be combined with each other. For example, claim 6 and claim 1 can be combined.

<< Effect of Claim 1 >>
The invention of claim 1 is characterized in that the skin material is pulled. However, since the skin material constitutes the surface of the seat, the front end of the seat can be reliably pulled backward (or downward). For this reason, the deformation | transformation permission part can be wound in firmly and it can also improve appearance.

  In addition, since the skin material is used as a pulling member, it is not necessary to perform processing for connecting the operating body to the inner shell, which can contribute to simplification of the structure. As a result, the cost can be reduced. Furthermore, since the skin material can be bent and deformed, it can be easily wound around a rotary actuator or pulled in a folded state in a side view through a support member. Therefore, there is an advantage that the freedom of design can be improved.

<< Effect of Claim 2 >>
In the second aspect of the invention, when the joint is made of a flexible material such as a string or cloth, it can be wound around the rotary actuator or the side surface via the support member as in the case of the first aspect. It becomes easy to pull it in a state of being folded into a square shape, and the design freedom can be improved.

  Further, in claim 2, when the joint is made of a material such as a waisted wire material, a resin plate, or a spring plate and both ends thereof are fixed to the operating body and the seat, the seat is bent and deformed. Accordingly, the joint posture changes, so that the joint pulls the seat, so that the seat can be deformed at a rate larger than the retracting rate of the operating body. Therefore, the seat depth can be quickly adjusted.

<< Effect of Claim 3 >>
Now, when the front end portion of the seat is pulled by the front / rear slide type operating body, the height of the connecting portion (or engaging portion) between the operating body and the seat is constant, so the deformation allowing portion swells upward while curling. The phenomenon can occur. On the other hand, in the invention of claim 3, since the front end portion of the seat can be pulled down while being lowered, there is an advantage that the seat can be prevented from being lifted or swollen.

  Further, in the invention of claim 3, since the center of bending (or the center of bending) of the deformation-permitting portion is shifted backward, the curvature radius of the bending of the deformation-permitting portion is made as small as possible and the bending is sharp. A state can also be realized.

<< Effect of Claim 4 >>
As described above, when the front end portion of the seat is pulled by the front / rear slide type operating body, the deformation allowing portion expands upward when the height of the connecting portion (or engaging portion) between the operating body and the seat is constant. However, in the fourth aspect of the present invention, the connecting portion (engagement portion) between the intermediate member and the seat can be shifted downward in conjunction with the backward movement of the operating body. , Can lift the seat.

  In addition, since various forms can be adopted for the intermediate member, it is possible to variously embody the aspect in which the seat is pulled back and deformed. For this reason, the freedom of design can be remarkably increased as compared with the case where the tip of the seat is simply pulled by the operating body. Furthermore, since it is possible to give the intermediate member a leverage, it is possible to easily adjust the depth of the seat quickly while reducing the amount of operation of the operation tool.

<< Effect of Claim 5 >>
If the structure of Claim 5 is employ | adopted, when bending a deformation | transformation permission part, the curvature radius can be enlarged, Therefore A deformation | transformation permission part can be bent and deformed with a light force. Therefore, the seat depth can be adjusted with a light force. Further, since the front end portion of the seat is pulled obliquely downward, it is possible to prevent the deformation allowing portion from floating and swelling when the deformation allowing portion is wound. Therefore, it can be excellent in aesthetics.

<< Effect of Claim 6 >>
If the operation tool is of the front / rear slide type, the operation tool may exceed a desired position due to excessive force applied, or conversely, the resistance may be large and difficult to move. When the operation tool is configured to be a rotary type, the operation tool can be strongly rotated with the braking force applied, and thus there is an advantage that it is possible to ensure that the seat is adjusted to a desired depth.

It is a figure which shows 1st Embodiment, (A) is a top view, (B) is BB view sectional drawing of (A). FIG. 2A is a sectional view taken along the line IIA-IIA in FIG. 1B, and FIG. (A) is the principal part vertical side view of 2nd Embodiment, (B) is the principal part longitudinal side view of 3rd Embodiment, (C) is the principal part longitudinal side view of 4th Embodiment. (A) The vertical side view before winding of 5th Embodiment, (B) is the vertical side view after winding of 5th Embodiment, (C) is the vertical side view of 6th Embodiment. It is a vertical side view of 7th Embodiment. It is a figure which shows 8th Embodiment, (A) is a vertical side view before winding, (B) is a vertical side view after winding. It is a vertical side view of 9th Embodiment. It is a vertical side view of 10th Embodiment.

  Next, an embodiment of the present invention will be described with reference to the drawings. In the following explanation, the front / rear / left / right wording is used to specify the direction, but the front / rear / left / right wording is based on the direction of the person normally sitting on the chair. The front view is a direction facing a person sitting on a chair. Moreover, although only the seat part is displayed in each figure, the chair is also provided with a backrest (in a mobile chair such as a rotary chair, a leg and a base provided at the upper end thereof are also provided).

(1). Structure of First Embodiment First, the first embodiment shown in FIGS. This first embodiment is a specific example of claims 1 and 6, and the seat 1 has a synthetic resin inner shell (seat plate) 2 and a cushion material 3 stretched on the upper surface thereof. . The surface of the cushion material 3 is covered with a skin material 4 such as a fabric. The seat 1 is formed in a substantially rectangular shape in plan view.

  The cushion material 3 may be integrally bonded to the inner shell 2 by insert molding or the like, or may be manufactured separately and held by the skin material 4. The skin material 4 is attached to the left and right side edges and the rear edge of the inner shell 2.

  There are various methods for attaching the skin material 4 to the inner shell 2. For example, a string can be attached to the edge of the skin material 4 and the string can be hooked on a boss provided on the lower surface of the inner shell 2. As another method, a tape-like edge member is fixed to the edge portion of the skin material 4 by sewing or the like, and this edge member is fitted into a boss formed on the lower surface of the inner shell 2. It is also possible to fix with a tucker.

  An outer shell (seat receiving member) 5 is disposed below the inner shell 2. The outer shell 5 is made of resin or sheet metal, and in the case of a rotary chair, the outer shell 5 is often fixed to an intermediate member arranged on the base. The outer shell 5 can also be fixed to the base. It is also possible to fix the inner shell 2 to a seat bracket made of a metal plate without using the outer shell 5.

  As shown in FIG. 2 (A), the outer shell 5 has left and right side walls 5a (and rear walls) and is open upward, and an outward flange 5b is provided at the upper end of the side wall 5a. Provided. Although omitted in the figure, a large number of ribs are provided on the upper surface of the outer shell 5 for reinforcement, and the inner shell 2 is supported by the ribs.

  A certain range of the front side of the seat 1 is a deformable portion 1 a that can be bent downward and deformed, and behind that is a fixed portion 1 b that is fixed to the outer shell 5. Along with this, the inner shell 2 and the cushion material 3 are also divided into a deformation allowing portion and a fixing portion. In the present embodiment, the deformation allowing portion 1a is set to a range of about 1/3 of the front side. However, generally, since the front / rear depth stroke of the seat is about 75 mm, such a depth adjustment is possible. The range before and after the deformation allowing portion 1a may be set.

  In the drawing, the deformation-permitting portion of the inner shell 2 is drawn in a simple plate shape, but actually, weakening means such as the horizontally long slit of Patent Document 10 is provided. It is preferable to provide a weakening means such as the laterally long groove of Patent Document 10 in order to facilitate downward bending also in the deformation allowing portion 3a of the cushion material 3.

  In the present embodiment, the slide support plate 6 overlaps the deformation allowing portion of the inner shell 2 from below. The left and right sides of the slide support plate 6 overlap the flange 5b of the outer shell 5, and have a hanging piece 6a that surrounds the flange 5b from the outside, and an inward horizontal piece 6b that is located below the flange 5b. . Therefore, the slide support plate 6 is attached to the outer shell 5 so as to be slidable back and forth so that it cannot be removed from the left and right.

  The hanging piece 6a of the slide support plate 6 is formed over the entire length of the slide support plate 6, but the inward horizontal piece 6b is formed in a jumping manner, and above the inward horizontal piece 6b of the slide support plate 6. In this part, there is a square hole that overlaps the horizontal piece 6b. For this reason, when manufacturing with a pair of metal molds that sandwich the slide support plate 6 from both the front and back sides, the inward horizontal piece 6b can be formed by so-called extraction.

  A downward bent portion 6 c is provided at the front end of the slide support plate 6. The slide support plate 6 is urged in the forward direction by a spring (not shown), and when the deformation allowing portion 1a of the seat 1 is wound downward, the slide support plate 6 moves backward against the spring. As shown in FIG. 2B, the front end of the slide support plate 6 is located somewhat behind the front end of the seat 1 with the seat 1 fully extended, but a downward load is applied to the front end of the seat 1. Since it does not usually hang, there is no inconvenience even if the front end of the slide support plate 6 is positioned behind the front end of the seat 1.

  The slide support plate 6 corresponds to the slide outer shell described in Patent Document 10. Also in this embodiment, it is possible to employ a slide support member having the same function as in Patent Document 10 and to support the inner shell 2 by the slide support member.

  A horizontally long rotating shaft 7 is disposed below the rear end portion of the deformation allowing portion 1 a of the seat 1. The left and right ends of the rotating shaft 7 are rotatably held by the left and right side walls 5a of the outer shell 5. The left and right ends or one end protrudes to the outside of the side walls 5a. The expression handle 8 is fixed.

  It is preferable that the handle 8 can be locked at an appropriate angle. Alternatively, it is possible to provide elastic engagement means and elastically hold at appropriate intervals. The lock means of the handle 8 can be set so that, for example, the lock is released when the handle 8 is pulled away from the outer shell 5, and the lock is returned by the spring when the hand is released from the handle 8.

  Further, a cylindrical body (winding member) 9 as an example of an operating body is fitted on the rotary shaft 7, and the rotary shaft 7 is key-engaged with end plates 10 provided at both ends of the cylindrical body 9. It is fixed by appropriate means. Accordingly, when the handle 8 is rotated, the cylindrical body 9 is rotated. A rearward extension 4 a is provided at the front end of the skin material 4, and the rear end of the rearward extension 4 a is fixed to the outer periphery of the cylindrical body 9.

  A forward piece 2 a and a downward piece 2 b are formed at the front end of the inner shell 2, and the rearward extension 4 a of the skin material 4 faces the cylindrical body 9 via the lower end of the downward piece 11. Further, since the cylindrical body 9 is smaller than the lateral width of the seat 1, the rearward extension 4 a is also smaller than the lateral width dimension of the seat 1.

(2) Summary of First Embodiment In the above configuration, when the handle 8 is rotated clockwise in the state of FIGS. 1 and 2, the rearward extension 4 a of the skin material 4 is wound around the cylindrical body 9. Therefore, as shown in FIG. 2 (B), the deformation allowing portion 1a of the seat 1 is caught in the lower part. Thereby, the position of the front end of the seat 1 can be adjusted. The slide support plate 6 is pushed backward against the spring by the bending of the inner shell 2.

  In this case, since the rearward extension 4a is flexibly deformable, the front end of the inner shell 2 is allowed to shift downward as the cylindrical body 9 rotates. Therefore, it is possible to prevent or remarkably suppress the deformation allowing portion 1a from being swollen upward, and to be involved in a good appearance. Moreover, since the skin material 4 is pulled, there is no slackness of the skin material 4. Also in this aspect, it is excellent in aesthetics.

  Further, since the rearward extending portion 4 a extends rearward from the front end of the seat 1, the deformation allowing portion 1 a of the seat 1 is wound by the rotation of the cylindrical body 9 so that the front end approaches the cylindrical body 9. For this reason, the front end of the seat 1 does not protrude downward, and the deformation allowing portion 1a can be wound compactly. Also in this aspect, it can be excellent in aesthetics.

  As shown by the alternate long and short dash line in FIG. 1 (B), a horizontally long idle bar 10 is arranged below the cylindrical body 9, and the rearward extension 4 a is connected to the cylindrical body 9 via the idle bar 10. It is also possible to fix. In this case, since the pulling direction of the front end of the seat 1 can be set as downward as possible, the deformation allowing portion 1a can be wound (bent) with a light force.

  In this case, if the idle bar 10 has a structure in which a roller is rotatably fitted to the core rod, the backward extension 4a can be pulled or returned without resistance. The idle bar 10 may be supported by left and right brackets protruding from the outer shell 5.

  As shown by a one-dot chain line in FIG. 2A, the cylindrical body 9 can be divided into a plurality of left and right parts, and these can be rotatably supported by a bracket 11 erected on the bottom surface of the outer shell 5. In this case, the rearward extension 4 a of the skin material 4 is also formed in a plurality of pieces corresponding to the number of cylindrical bodies 9.

  A solid roller may be used in place of the cylindrical body 9 as the operating body that winds the rearward extension 4 a of the skin material 4. Further, the rearward extension 4a does not necessarily have to be wound around a cylindrical working body, and can be pulled back by a back-and-forth moving slider. Returning and deforming the seat 1 and extending it toward the front is performed by the elastic restoring force of the seat 1.

(3). Second and third embodiments (FIG. 3)
FIG. 3 shows the second to fourth embodiments using a rack and a pinion as rearward pulling means for the rearward extension 4a when the rearward extension 4a is provided on the skin material 4 as in the first embodiment. doing. Each embodiment is a specific example of claim 1. Moreover, 2nd Embodiment and 4th Embodiment are applicable also to the specific example of Claim 6. FIG.

  Among these, in 2nd Embodiment shown to FIG. 3 (A), the winding roll 13 is fixed to the rotating shaft 7, or it integrates, and the rotating shaft 7 is rotated and the back extension part 4a to the winding roll 13 is carried out. First, the rotating shaft 7 is fitted into the longitudinally long elongated holes 14 provided in the left and right side walls 5a of the outer shell 5 so as to be slidable forward and backward and rotatable.

In addition, pinion gears 15 are fixed to both right and left ends of the take-up roll 13, and the pinion gears 15 are meshed with a rack 16 provided on the outer shell 5 from below. In the drawing, the rack 16 is arranged on the pinion gear 15, but in practice, it can be said that it is reasonable to arrange the rack 16 on the bottom plate of the outer shell 5.

  A handle 8 similar to that of the first embodiment is fixed to the rotating shaft 7. When the handle 8 is rotated, the take-up roll 13 rotates while sliding back and forth. Therefore, the pull due to the backward extension 4 a being wound around the take-up roll 13 and the pull due to the retraction of the rotating shaft 7 act on the front end of the seat 1. Thereby, compared with 1st Embodiment, the depth adjustment of the seat 1 can be performed with the small rotation amount of the rotating shaft 7. FIG.

  Also in this embodiment, a lock mechanism is provided in the operation means so that the rotary shaft 7 can be rotated after the lock is released.

  In the third embodiment shown in FIG. 3B, the position of the rotary shaft 7 is fixed, and the rack 16 moves back and forth. Therefore, a front / rear slide lever is disposed outside the outer shell 5, and the lever and the rack 16 are connected to each other. The slide support plate 6 can be moved back and forth by the rotation of the rotary shaft 7.

  In the fourth embodiment shown in FIG. 3C, the rearward extension 4 a is connected to the front end of the rack 16 in a configuration in which the rack 16 is moved back and forth by the pinion gear 15. Although not shown, a handle 8 similar to that of the first embodiment is fixed to the rotary shaft 7.

(4). Fifth and sixth embodiments (FIG. 4)
FIGS. 4A and 4B show a fifth embodiment which is a specific example of claim 2. In this embodiment, a slider 18 that is movable back and forth as an example of an operating body is attached to the outer shell 5, and the front end of the slider 18 and the front end of the inner shell 2 are fixed by an elastic body 19 as an example of a joint. ing. The slider 18 has a certain length in the left-right direction. One elastic plate 19 is sufficient if it has a certain amount of left and right width, and in the case of a narrow width, a plurality of elastic plates 19 may be arranged so as to jump in the left and right direction. The slider 18 is held so as to only move back and forth by guide means (not shown).

  The elastic body 19 is an elastic metal plate such as a leaf spring, stainless steel, or steel plate, and has a certain level of waist strength. In the state where the seat 1 is fully extended, the elastic plate 19 has a substantially linear shape. The front end and the rear end of the elastic plate 19 are fixed to the front end of the inner shell 2 and the slider 18 integrally or via a coupling tool such as a clamp body (the slider 18 or the inner shell). On the other hand, it may be embedded by insert molding or the like.) For this reason, the elastic body 19 tends to maintain a horizontal posture in a side view. Although not shown, a lever located outside the outer shell 5 is attached to the slider 18.

  In this embodiment, when the slider 18 is retracted, the deformation allowing portion 1a of the seat 1 is pulled down by the elastic plate 19 and is wound downward, but the front end portion of the inner shell 2 is fixed to the elastic plate 19 by this winding deformation. Since the posture changes so as to face upward, the elastic body 19 is also bent and deformed. That is, since the elastic plate 19 has a certain amount of waist, the front end portion of the elastic plate 19 maintains the same posture as the front end portion of the inner shell 2, while the rear end portion has the same posture as the slider. If the 2 deformation | transformation permission part 1a is wound, the elastic board 19 will also bend and deform | transform.

  That is, when the slider 18 moves backward, the elastic body 19 entrains the knitting allowable portion 1a of the inner shell 2 while being bent and deformed. In this case, the shape in which the elastic plate 19 is bent and deformed differs depending on the conditions (for example, the waist strength of the elastic plate and the waist strength of the deformation allowing portion 1a of the inner shell 2). As one aspect, as shown by a solid line in FIG. 4B, it is assumed that the material is bent and deformed in a substantially L shape. As another aspect, as shown by a one-dot chain line in FIG. 4 (B), it is assumed that the vehicle is bent to a state where it is entirely lowered against a downwardly concave bow. As yet another aspect, as shown by a dotted line in FIG.

  In any case, since the deformation allowing portion 1a tends to move downward due to its own elastic force due to its own elastic force, the elastic plate 19 is deformed while moving the front end downward. Therefore, the front-rear interval of the elastic plate 19 is reduced as compared with that before the deformation, and as a result, the front end of the inner shell 2 is retracted by an amount larger than the retraction amount of the slider 18.

  Thus, since the front end of the seat 1 is pulled backward even by the bending deformation of the wire 19, the depth of the seat can be reduced with a small amount of movement of the slider as compared with the case where the inner shell 2 is pulled directly with a rigid slider. Adjustments can be made. The same effect can be obtained by using other connecting materials such as a resin plate, a laminated plate of different materials, a metal or resin wire, or a stiff wire instead of the metal elastic plate 19. The When using a wire or a wire, it is better to arrange a plurality of wires in the left-right direction.

  The action of pulling the front end of the inner shell 2 backward increases as the degree of bending of the elastic coupling body such as the elastic plate 19 increases. Further, the lower the front end, the better the inner shell 2 can be prevented from floating. As a means for exerting such an action strongly, it is possible to provide a regulating body that comes into contact with the upper surface of the elastic coupling body such as the elastic plate 19 as in the case of the idle bar 10 shown in FIG. . When the restricting body is provided in this manner, the elastic coupling body is prevented from moving upward and bent so as to escape downward, so that the slider 18 is placed as high as possible and the front end of the seat 1 is pulled downward as much as possible. Is possible. Therefore, the freedom of design can be improved and the responsiveness of the seat longitudinal adjustment to the lever operation can also be improved.

  The sixth embodiment shown in FIG. 4C is a specific example of claim 3. In this embodiment, the slider 18 is attached to the outer shell 5 so as to be movable back and forth, and the rod 20 provided at the front end of the slider 18 is locked to the front end portion of the inner shell 2 with the pin 21. The guide 2 is formed on the inner surface of the shell 2.

  The guide portion 22 has a long hole 23 that is long in the vertical direction and in the front-rear direction along the inclined inner surface of the front end of the inner shell 2. Therefore, the pin 21 and the guide part 22 can move relative to each other in the longitudinal direction of the guide part 22.

  In this embodiment, as indicated by the alternate long and short dash line, when the slider 18 is retracted, the deformation allowing portion 1a of the seat 1 moves downward while the guide portion 22 is pulled by the pin 21, thereby lowering the front end. However, it is rolled downward (turned back). Therefore, when the depth of the seat 1 is shortened, a phenomenon that the deformation allowing portion 1a swells up can be prevented. For this reason, it is excellent in aesthetics.

(5) Seventh and eighth embodiments (FIGS. 5 and 6)
The seventh embodiment shown in FIG. 5 and the eighth embodiment shown in FIG. 6 are specific examples of claim 4. Among these, in the seventh embodiment shown in FIG. 5, the outer shell 5 is provided with a longitudinally moving slider 18 as an operating body, and the front end of the slider 18 and the front end of the inner shell 2 are connected by a first link 24. In addition, the outer shell 5 and the front end of the inner shell 2 are connected by a second link 25. Although the second link 25 is located on the first link 24, the connecting portion between the second link 25 and the outer shell 5 may be located above the front end of the slider 18.

In the seventh embodiment, the front end of the inner shell 2 is pulled backward by the backward movement of the slider 18, but the movement of the front end of the inner shell 2 is restricted by the second link 25, and follows the locus indicated by reference numeral 26. Move. Along with this, the posture of the first link 24 also changes. That is, when the postures of the links 24 and 25 change, the seat deformation allowing portion 1a is wound downward.

  In this embodiment, since the front end of the seat 1 is forcibly moved downward by the second link 25, there is no floating phenomenon of the front end portion of the seat 1, and the appearance is excellent. Also, the structure is relatively simple. The links 24 and 25 are examples of intermediate members recited in the claims. It can be said that it is sufficient to have about two links 24 and 25 on the left and right. In the embodiment shown in FIG. 7, the front ends of the links 24 and 25 are connected to the downward bracket portion provided at the front end of the inner shell 2 while changing the vertical height. You may connect in a shape.

  In the eighth embodiment shown in FIG. 6, a laterally oblong cam (or link) 28 is disposed in front of the slider 18 as an example of the intermediate member recited in the claims. The shift portion is connected to the side wall 5 a of the outer shell 5, and the front end of the slider 18 and the cam 28 are connected by a link 29. The link 29 is connected to the cam 28 in front of and below the rotating branch 30 of the cam 28.

  A rearward extension 4 a of the skin material 4 is provided, and the rearward extension 4 a is connected to the lower surface of the outer periphery of the cam 28. Therefore, this embodiment corresponds to a specific example of claim 1. Instead of connecting the rearward extension 4a of the skin material 4 to the cam 28, it is also possible to connect the outer peripheral lower surface of the cam 28 and the front end of the inner shell 2 with a flexible joint member such as a string. is there. In this case, this embodiment corresponds to the embodiment of claim 2.

  In this embodiment, as shown in (B), when the slider 18 moves backward, the cam 28 swings greatly so that the front end thereof is directed downward from the downward direction. For this reason, the rearward extension 4a of the skin material 4 is greatly pulled backward, and the deformation allowing portion 1a of the seat 1 is wound downward. In this case, since the cam 28 pulls the rearward extension 4a largely by the lever principle, the depth of the seat 1 can be adjusted more quickly than when the inner shell 2 is simply pulled by the slider 18.

  By adjusting the rotation fulcrum of the cam 28 and the connection point with respect to the link 29, the manner of pulling the seat 1 can be variously changed. Therefore, it is excellent in design freedom. Further, in the example shown in the figure, the cam 28 is formed in an oval shape having two parallel long sides and two arc portions. In this case, the start of winding of the backward extension 4a of the skin material 4 is illustrated. Instead of starting from the long side portion as described above, it is possible to set the posture of the cam 28 so that the winding start starts from the arcuate portion. Thus, the winding of the backward extension portion 4a is possible. By changing the starting position so that the long side comes first, or the arc shape comes first, the retracting amount of the extension portion 4a is changed while the retracting amount of the slider 18 is kept constant. It is also possible to adjust.

(6). Ninth and tenth embodiments (FIGS. 7 and 8)
The ninth embodiment shown in FIG. 7 and the tenth embodiment shown in FIG. 8 embody Claim 5. Among these, in the ninth embodiment shown in FIG. 7, a horizontally long rotating shaft 7 is arranged on a fixed member such as an outer shell, and a pinion gear 31 as an example of an operating body is fixed to the rotating shaft 7. ing. An interlocking body 32 that pulls the front end of the seat 1 diagonally downward and rearward is slidably disposed on a fixed member such as an outer shell, and the rack 35 provided on the interlocking body 32 and the pinion gear 31 are engaged with each other. . The front end of the interlocking body 32 is connected to the front end of the inner shell 2 with a pin.

  A handle similar to that of the first embodiment is fixed to the outer end of the rotating shaft 7. When the handle is operated to rotate the rotating shaft 7 in the clockwise direction in the drawing, the interlocking body 32 is obliquely rearward and downward. It slides and the deformation | transformation permission part 1a of the seat 1 is wound down and deform | transformed. For this reason, the deformation | transformation permission part 1a of the seat 1 can be wound and deformed with a light force. In addition, there is no floating or swelling during the entrainment deformation.

  As the slide guide means of the interlocking member 32, a structure in which two guide pins 35 are fitted in the elongated hole 34 is adopted, but various guide mechanisms such as a dovetail groove system can be adopted. The rotating shaft 7 and the interlocking body 32 can be attached to a member such as an outer shell via a bracket. As the operation means, it is also possible to adopt a rotary lever instead of the rotary handle. In this case, the lever and the interlocking body 32 are connected by a link, and the interlocking body is operated by rotating the lever. 32 can be slid.

  In the tenth embodiment shown in FIG. 8, the front end of the seat 1 is pulled obliquely backward by the interlocking body 32. Although not shown, the interlocking body 32 is slid by a rotary handle or a rotary lever.

  In this embodiment, the slide support plate 6 is employed, and the front end portion of the slide support plate 6 has an arcuate shape 6 a that contacts the inner shell 2. And since the winding deformation | transformation of the front-end part of the seat 1 is performed by using the circular arc shape 6a of the slide support plate 6, the deformation | transformation of the seat 1 can be performed in a beautiful state.

  Although specific examples of each claim have been described above, the present invention can be variously embodied in addition to the above-described embodiments.

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

DESCRIPTION OF SYMBOLS 1 Seat 1a Deformation allowance part 1b Fixed part 2 Inner shell 3 Cushion material 4 Skin material 4a Backward extension part 5 Outer shell 5a Side wall 6 Slide support plate 7 Rotating shaft 8 Rotating handle as an example of operation tool 9 As an example of operating body 15 Pinion gear 16 Rack 18 Slider as an example of actuating body 19 Wire as an example of joint 21 Pin 22 Guide part 23 Slot 24, 25 Link as an example of intermediate member 28 Cam as an example of intermediate member 31 Operation Pinion gear as an example of body 32 interlocking body 33 rack

Claims (6)

An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
The surface of the seat is made of a skin material, and the front end portion of the skin material is pulled in conjunction with the operation of the operation tool, whereby the deformation permission portion is wound or bent downward,
Chair. An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
An operating body that rotates or slides by operation of the operating tool is provided below the seat, and the distal end portion of the seat and the operating body are connected by a joint that can be bent and deformed.
Chair. An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
An operating body that slides back and forth by operation of the operating tool is provided below the seat, and the front end of the operating body is engaged with a guide portion formed at the front end of the seat,
The guide portion of the seat is formed in an inclined shape that, when the operating body is moved backward, moves relative to the front end of the operating body and bends the deformation allowing portion of the seat downward.
Chair. An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
An operating body that slides back and forth by operation of the operating tool is provided below the seat, and when the operating body retreats between the front end of the operating body and the front end of the seat, the seat rotates or rotates. An intermediate member that bends the deformation allowable portion downward is provided.
Chair. An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
Below the seat, an operating body that rotates back and forth by rotating the operation tool or a left and right longitudinal axis, and a sliding type that pulls the front end of the seat diagonally backward and downward in conjunction with the movement of the operating body Or arrange a rotating interlocking body,
Chair. An appropriate range near the front of the seat is a configuration that is a deformation-permitting portion that bends downward by operating the operation tool,
The operation tool is a method of rotating around a horizontally long axis.
Chair.

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