JP5953738B2 - Chair - Google Patents

Description

  The present invention relates to a chair comprising a structural material that is elastically deformed when a load is applied.

  For various purposes such as improving sitting comfort, the material and cross-sectional shape of the synthetic resin seat frame and back frame are devised, and the seat frame and back frame are appropriately elastically deformed when a load is applied. Various devices have been developed (see, for example, Patent Document 1).

  However, in this type of chair, if the seat frame and the back frame are designed to be easily elastically deformed in order to soften the seating comfort, it may be deformed excessively when a large load is applied. It is necessary to provide a stopper or the like for keeping the elastic deformation of the seat frame and the back frame within a certain range at a place away from the seat frame and the back frame. When a stopper or the like is provided outside, there may be a problem that the cost increases due to an increase in the number of parts, an increase in the attaching process of these parts, or the like. In addition, when the stopper or the like is exposed to the outside, the appearance as a chair is affected, and the design may be deteriorated. On the other hand, when a stopper or the like cannot be provided outside, the seat frame and the back frame must be set firmly so that excessive deformation does not occur, and the seating comfort cannot be improved. is there.

  Such a dilemma exists not only for a seat frame and a back frame, but also for various components constituting the chair.

Japanese Patent Application No. 2011-136263

  An object of the present invention is to provide a chair that can eliminate the dilemma described above.

  The present invention employs the following configuration in order to solve the above-described problems. That is, the chair according to the present invention includes a structural material that is elastically deformed in response to a load, and is provided with a facing surface that forms a pair at a portion of the structural material that is elastically deformed, and the facing surface when the structural material is elastically deformed. Are arranged so that the elastic deformation characteristics of the structural material change in proximity to each other, and at least one of the facing surfaces is formed on a mounting part attached to the outer surface of the structural material. Features.

  Here, “proximity” includes a case of direct contact and a case of approaching gradually while compressing and deforming an elastic material between opposing surfaces.

  If this is the case, the resilience characteristics can be changed before and after the opposing surfaces of the structural material come close to each other, so a stopper or the like for suppressing excessive deformation when a large load is applied is provided on the seat frame. It is not necessary to provide it at a place away from the structural material such as the back frame or the like, and it is possible to improve the sitting comfort by giving an appropriate elastic deformation.

Structural materials are those having a hard portion which is elastically deformed when a load is applied, to form the opposing surfaces paired approaching along with the elastic deformation outward as viewed from the bending direction of the rigid portion Yes. Here, “outside as viewed from the bending direction” means the side on which the internal stress in the tensile direction increases as a load is applied and bending deformation proceeds regardless of the shape. In other words, for example, when an arc-shaped structural material is bent and deformed in a direction in which the radius of curvature decreases, the side opposite to the center of curvature is the outside. On the other hand, when the arc-shaped structural material is bent and deformed in a direction in which the radius of curvature increases, the center of curvature is the outside. Further, “inner side when viewed from the bending direction” means a side on which an internal stress in the compression direction increases as a load is applied and bending deformation proceeds regardless of the shape. In other words, for example, when an arc-shaped structural material is bent and deformed in a direction in which the radius of curvature becomes smaller, the center of curvature is the inside. On the other hand, when the arc-shaped structural material is bent and deformed in the direction in which the radius of curvature increases, the side opposite to the center of curvature is the inside.

  The opposing surfaces forming the pair are formed on an outward flange supported by a structural material, and an inward flange provided to cover the outward flange, and at least inward What has the collar part formed in the said attachment component is mentioned as a suitable aspect.

  As a specific aspect of the structural material, for example, a cantilevered structural material such as a back frame, a seat frame, a back frame, a seat frame, a back support rod, a headrest arm, etc. It can be considered that the opposite side is inside the elastic deformation.

  Further, as another specific aspect of the structural material, for example, a structural material that supports both ends, for example, a back plate supported on both ends, a seat plate, a lumbar support, an armrest, etc. What is inside can be considered.

  In order to realize the problem with a simple structure, it is preferable that the structural material is such that the facing surfaces directly contact each other when the structural material is elastically deformed more than a certain amount.

  The structural material includes a recessed portion that forms the facing surface, and may be one in which an elastomer is disposed on all or a portion of the recessed portion.

  Since this invention is the above structures, the chair which can eliminate the dilemma mentioned above can be provided.

The principal part side sectional view showing typically the chair of a 1st embodiment of the present invention. The bottom view which shows the chair concerning the embodiment typically. Action explanatory drawing which expands and shows typically the principal part of the chair concerning the embodiment. Action explanatory drawing which expands and shows typically the principal part of the chair concerning the embodiment. The principal part side sectional view showing typically the chair of a 2nd embodiment of the present invention. The principal part sectional drawing which shows typically the chair of 3rd Embodiment of this invention. The side view which shows typically the principal part of the chair of 4th Embodiment of this invention. The figure which shows the modification of the recessed part of this invention typically. The figure which shows the modification of the recessed part of this invention typically. The figure which shows the modification of the recessed part of this invention typically. The figure which shows the reference example of this invention typically. The figure which shows the reference example of this invention typically. Explanatory drawing which expands and shows typically the principal part of the modification of the recessed part of this invention. Explanatory drawing which expands and shows typically the principal part concerning the modification.

<First Embodiment>
First, a first embodiment of the present invention will be described with reference to FIGS.

  In this embodiment, the present invention is applied to a pipe chair. As schematically shown in FIGS. 1 and 2, the chair 1 includes a leg body 2 and a seat 4 supported by the leg body 2.

  As shown in FIGS. 1 and 2, the leg 2 includes left and right bases 27, front legs 281 raised from the front ends of the bases 27, rear legs 282 raised from the rear ends of the bases 27, A front seat receiving portion 261 that connects the upper ends of the left and right front legs 281, a rear seat receiving portion 262 that connects the upper ends of the left and right rear legs 282, and a left and right connection that connects the front legs 281 and the rear legs 282 upward. In this embodiment, the base 27, the front and rear legs 281 and 282, and the front and rear seat receivers 261 and 262 are formed by bending a single pipe. Yes. The front and rear seat receiving portions 261 and 262 are for supporting the front region F and the rear region R of the seat 4, respectively, and the seat 4 is provided with front and rear seat receiving portions 261 and 262 via a fastener (not shown). It is fixed to.

  As shown in FIGS. 1 and 2, the seat 4 includes a shell-like seat body 431 and a mounting portion 432 disposed on the lower surface of the seat body 431. The seat body 431 of the seat 4 is integrally formed of a hard synthetic resin, and mainly includes the hard portion 11. More specifically, a facing surface 113 that forms a pair in the elastically deforming portion of the seat 4 that is elastically deformed under a load is provided, and when the seat 4 is elastically deformed, the facing surface 113 comes close to The elastic deformation characteristics of the seat 4 are configured to change. That is, the seat 4 includes the hard portion 11 that is elastically deformed when a load is applied, and the concave portion 112 is formed on the surface that receives tensile stress due to the elastic deformation of the hard portion 11, that is, the downward surface 411. A pair of opposing surfaces 113 that are close together with the elastic deformation are formed inside the recessed portion 112, and the opposing surfaces 113 are in direct contact with each other when the hard portion 11 is elastically deformed more than a certain amount, The deformation of the hard portion 11 beyond the elastic deformation limit is suppressed. That is, the seat 4 includes a hard portion 11 that elastically deforms in the bending direction when a load is applied, and a pair that approaches the outside along with the elastic deformation when viewed from the bending direction of the hard portion 11. The opposing surface 113 is formed. The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The facing surface 113 is formed on each of the first and second mounting parts 101 and 102 attached to the outer surface of the seat 4. More specifically, the opposing facing surfaces 113 forming the pair are formed in an outward flange 101a supported by the seat 4 and an inward flange 102a provided so as to cover the outward flange 101a. In this case, an outward flange 101 a is formed on the first attachment component 101, and an inward flange 102 a is formed on the second attachment component 102. In the seat 4, the side on which the load is applied when seated is the inside of the elastic deformation. In this embodiment, a single recessed portion 112 is formed on the downward surface 411 of the seat 4, and the elastomer is not disposed in the recessed portion 112. The recessed portion 112 is formed at a boundary that divides the front region F and the rear region R of the seat 4. That is, the recessed portion 112 is formed in the vicinity of the center in the front-rear direction of the seat 4 in the left-right direction, and a part of the inner side facing the recessed portion 112 is the facing surface 113. In other words, the hard portion 11 includes a thin portion 91 and thick portions 92 that are provided on both sides of the thin portion 91 and have a thickness dimension larger than that of the thin portion 91. The recessed portion 112 is formed between the portions 92, and the facing surface 113 is formed inside the recessed portion 112.

  In the case of such a chair 1, various seating feelings can be obtained by combining the sinking operation of the seat 4 and the elastic deformation of the seat 4. That is, when sitting on the seat 4 in the office posture (S), as shown in FIG. 4, due to the load caused by the weight of the seated person, the vicinity of the recessed portion 112 of the seat 4 is significantly elastically deformed, The boundary portion between the front region F and the rear region R sinks. 3 and 4, the hard portion 11 of the seat 4 before elastic deformation and after elastic deformation, and the first and second attachment parts 101 and 102 are shown in an enlarged manner. This elastic deformation is mainly governed by the elastic characteristics of the thin-walled portion 91 until the opposing surfaces 113 of the recessed portion 112 come into contact with each other. The deformation of the thin portion 91 is prohibited and is governed by the elastic characteristics of the thick portion 92. That is, the elastic deformation characteristics of the hard portion 11 change suddenly before and after the opposing surfaces 113 come into contact with each other, and after the opposing surface 113 comes into contact, the seat 4 is prevented from sinking further. Even after the hard portion 11 reaches the elastic deformation limit and the opposing surfaces 113 come into contact with each other, if the force in the excessive sinking direction is applied to the seat 4, the thick portion of the hard portion 11 of the seat 4 is increased. A slight deformation is performed while being controlled by the elastic characteristics of the portion 92. That is, when the seat occupant applies a load to the seat 4 and the hard portion 11 of the seat 4 reaches the elastic deformation limit, as shown in FIG. The facing surface 113 formed on the 101a and the facing surface 113 formed on the inward flange portion 102a of the second mounting component 102 directly contact each other. Therefore, further elastic deformation of the seat 4 is suppressed, and further depression of the seat 4 cannot be performed.

  As described above, the chair 1 according to the present embodiment includes the seat 4 that is elastically deformed by receiving a load, and is provided with the opposing surface 113 that forms a pair at the elastically deformed portion of the seat 4. When the elastic deformation is performed, the facing surface 113 comes close to each other so that the elastic deformation characteristics of the seat 4 change, and at least one of the facing surfaces 113 is attached to the outer surface of the seat 4. Since the second mounting part 102 is formed, the resilience characteristics can be changed before and after the opposed surface 113 of the seat 4 abuts. For this reason, it is not necessary to provide a stopper or the like for suppressing excessive deformation when a large load is applied, and it is possible to improve the sitting comfort by providing appropriate elastic deformation. Therefore, there is no problem that the degree of freedom in designing the chair 1 is significantly impaired by the installation of the above-described stopper and the like.

  The seat 4 is provided with a hard portion 11 that elastically deforms in the bending direction when a load is applied, and is opposed to the outside as viewed in the bending direction of the hard portion 11 along with the elastic deformation. Since the surface 113 is formed, the attachment members 101 and 102 forming the facing surface 113 have a relatively complicated structure. Although it is difficult to form such a complicated structure integrally with the seat 4, the first mounting component 101 and the second mounting component 102 that form the facing surface 113 are combined with the seat 4 as in the present embodiment. If they are formed separately, they can be easily molded even with complicated shapes. That is, it is possible to prevent the mold from becoming complicated and suitable for mass production.

  The pair of opposing surfaces 113 are formed on an outward flange 101a supported by the seat 4 and an inward flange 102a provided so as to cover the outward flange 101a. Since the outward flange portion 101a is formed on the first attachment component 101 and the inward flange portion 102a is formed on the second attachment component 102, the first attachment to the seat 4 is first performed. By attaching the second attachment component 102 after attaching the component 101, the opposing surfaces 113 that form a pair on the downward surface 411 side of the seat 4 can be formed. In addition, by changing the attachment position of the 1st attachment component 101 and the 2nd attachment component 102, it is also possible to change the distance between the opposing surfaces 113, and to set various ease of elastic deformation.

  Since the side to which the seat 4 is loaded is the side that is elastically deformed when the seat 4 is seated, there is no possibility that the seated person's clothes and the like are sandwiched between the facing surfaces 113.

  Since the facing surfaces 113 directly contact each other when the seat 4 is elastically deformed more than a certain amount, the resilience characteristics can be rapidly changed before and after the facing surfaces 113 of the seat 4 abut. . Moreover, since the thing of this embodiment forms both the opposing surfaces 113 which make a pair in the attachment components 101 and 102 separate from the seat 4, when the opposing surfaces 113 are rubbed and worn out, The separate mounting parts 101 and 102 can be replaced.

Second Embodiment
Next, a second embodiment of the present invention will be described with reference to FIG.

  In this embodiment, the present invention is applied to a pipe chair. As shown in FIG. 5, the chair 1 includes a leg 2 and a seat 4 and a backrest 5 supported by the leg 2.

  As shown in FIG. 5, the leg 2 includes left and right bases (not shown), front legs 281 raised from the front ends of the bases, rear legs 282 raised from the rear ends of the bases, and the left and right front legs 281. A seat receiving portion 261 that connects between the upper ends of the left and right rear legs, a backrest receiving portion 263 that connects the upper ends of the left and right rear legs 282, and a left and right connecting the upper end portion of the front legs 281 and the middle portion of the rear legs 282. In this embodiment, the base, the front and rear legs 281 and 282, the seat receiving part 261 and the backrest receiving part 263 are formed by bending a single pipe. ing. The seat receiving portion 261 is for supporting the front region F of the seat 4, and the seat 4 is fixed to the seat receiving portion 261 via a fixing tool (not shown). The backrest receiving portion 263 is for supporting the upper region U of the backrest 5, and the backrest 5 is fixed to the backrest receiving portion 263 via a fastener (not shown).

  As shown in FIG. 5, the seat 4 includes a shell-like seat body 431 and a mounting portion 432 disposed on the lower surface of the seat body 431. The seat body 431 of the seat 4 is integrally formed of a hard synthetic resin, and mainly includes the hard portion 11. More specifically, a facing surface 113 that forms a pair in the elastically deforming portion of the seat 4 that is elastically deformed under a load is provided, and when the seat 4 is elastically deformed, the facing surface 113 comes close to The elastic deformation characteristics of the seat 4 are configured to change. That is, the seat 4 includes the hard portion 11 that is elastically deformed when a load is applied, and the concave portion 112 is formed on the surface that receives tensile stress due to the elastic deformation of the hard portion 11, that is, the downward surface 411. A pair of opposing surfaces 113 that are close together with the elastic deformation are formed inside the recessed portion 112, and the opposing surfaces 113 are in direct contact with each other when the hard portion 11 is elastically deformed more than a certain amount, The deformation of the hard portion 11 beyond the elastic deformation limit is suppressed. That is, the seat 4 includes a hard portion 11 that elastically deforms in the bending direction when a load is applied, and a pair that approaches the outside along with the elastic deformation when viewed from the bending direction of the hard portion 11. The opposing surface 113 is formed. The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The facing surface 113 is formed on each of the first and second mounting parts 101 and 102 attached to the outer surface of the seat 4. More specifically, the opposing facing surfaces 113 forming the pair are formed in an outward flange 101a supported by the seat 4 and an inward flange 102a provided so as to cover the outward flange 101a. In this case, an outward flange 101 a is formed on the first attachment component 101, and an inward flange 102 a is formed on the second attachment component 102. In the seat 4, the side on which the load is applied when seated is the inside of the elastic deformation. In this embodiment, a single recessed portion 112 is formed on the downward surface 411 of the seat 4, and the elastomer is not disposed in the recessed portion 112. The recessed portion 112 is formed in a portion corresponding to the seated person's buttocks. In other words, the recessed portion 112 is formed in the rear region R of the seat 4, and a part of the inside of the recessed portion 112 that faces the recessed portion 112 serves as the facing surface 113. In other words, the hard portion 11 includes a thin portion 91 and thick portions 92 that are provided on both sides of the thin portion 91 and have a thickness dimension larger than that of the thin portion 91. The recessed portion 112 is formed between the portions 92, and the facing surface 113 is formed inside the recessed portion 112. A backrest 5 is integrally provided continuously at the rear end of the seat 4.

  As shown in FIG. 5, the backrest 5 includes a shell-like backrest main body 531 and a mounting portion 532 arranged on the back side of the backrest main body 531. The backrest main body 531 of the backrest 5 is integrally formed of a hard synthetic resin, and the backrest 5 is mainly composed of the hard portion 11. More specifically, a facing surface 113 is provided that is paired with a portion of the backrest 5 that is elastically deformed by receiving a load, and the opposing surface 113 approaches the backrest 5 when the backrest 5 is elastically deformed. Thus, the elastic deformation characteristics of the backrest 5 are changed. That is, the backrest 5 includes the hard portion 11 that is elastically deformed when a load is applied, and a concave portion 112 is formed on a surface that receives tensile stress due to elastic deformation of the hard portion 11, that is, the rearward surface 511. And a pair of opposing surfaces 113 that come close to each other along with the elastic deformation are formed inside the recessed portion 112, and the opposing surfaces 113 are in direct contact with each other when the hard portion 11 is elastically deformed more than a certain amount. The deformation of the hard part 11 exceeding the elastic deformation limit is suppressed. That is, the backrest 5 is provided with a hard portion 11 that elastically deforms in the bending direction when a load is applied, and a pair that approaches the outer side with the elastic deformation as viewed from the bending direction of the hard portion 11. The opposing surface 113 which forms is formed. The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The facing surface 113 is formed on each of the first and second mounting parts 101 and 102 attached to the outer surface of the backrest 5. More specifically, the opposing facing surfaces 113 forming a pair are formed on an outward flange 101a supported by the backrest 5 and an inward flange 102a provided so as to cover the outward flange 101a. An outward flange 101 a is formed on the first attachment component 101, and an inward flange 102 a is formed on the second attachment component 102. In the backrest 5, the side on which the load is applied when sitting is the inside of the elastic deformation. In this embodiment, a single recessed portion 112 is formed on the rearward surface 511 of the backrest 5, and the elastomer is not disposed in the recessed portion 112. The recessed portion 112 is formed at a portion corresponding to the waist of the seated person. That is, the recessed portion 112 is formed in the lower region D of the backrest 5, and a part of the inner side of the recessed portion 112 that faces is used as the facing surface 113. In other words, the hard portion 11 includes a thin portion 91 and thick portions 92 that are provided on both sides of the thin portion 91 and have a thickness dimension larger than that of the thin portion 91. The recessed portion 112 is formed between the portions 92, and the facing surface 113 is formed inside the recessed portion 112.

  In the case of such a chair 1, various seating feelings can be obtained by combining the sinking operation of the seat 4 and the elastic deformation of the seat 4 or the backrest 5. That is, when sitting on the seat 4 in the office posture (S), as shown by the solid line in FIG. 5, the load due to the weight of the seated person acts on the front region F of the seat 4, so Is supported in a stable state without tilting. Further, when the seated person's load shifts to the rear region R of the seat 4, the rear region R of the seat 4 sinks with respect to the front region F of the seat 4 as shown by a two-dot chain line in FIG. 5. At the same time, the lower region D of the backrest 5 moves rearward with respect to the upper region U of the backrest 5, and the seated person is softly received. This operation is carried out by elastically deforming the hard part 11 at the place where each recessed part 112 is formed in the seat 4 and the backrest 5. This elastic deformation is the same as that of the first embodiment, and the elastic deformation characteristics of the hard portion 11 change suddenly before and after the opposing surfaces 113 come into contact with each other. It is possible to prevent the seat 4 and the backrest 5 from being elastically deformed further. That is, when the hard portion 11 reaches the elastic deformation limit, the facing surface 113 formed on the first mounting component 101 and the facing surface 113 formed on the second mounting component 102 directly contact each other. It will be. Therefore, further elastic deformation of the seat 4 and the backrest 5 is suppressed. That is, the seat 4 and the backrest 5 are kept in a preset deformed shape unless an excessive force is applied in a state where the opposing surfaces 113 are in contact with each other. In FIG. 5, the seat body 431 and the backrest body 531 after being elastically deformed are indicated by two-dot chain lines, and the first and second mounting parts 101 and 102 and other parts are not shown. These are also deformed along with the elastic deformation.

<Third Embodiment>
Next, a third embodiment of the present invention will be described with reference to FIG.

  As shown in FIG. 6, the chair 1 of this embodiment includes a backrest 5 in which a mesh-like tension fabric 52 is stretched between left and right back frames 51, and a lumbar is provided on the waist of the backrest 5. Support 85 is provided. The lumbar support 85 has both ends supported by the left and right back frames 51 and a holding portion 851 disposed on the back side of the stretched fabric 52, and a load on the front side of the holding portion 851. And a lumbar support body 852 made of a hard synthetic resin that can be elastically deformed in the thickness direction.

  The present invention is applied to the lumbar support main body 852 of the chair 1 as described above.

  As shown in FIG. 6, the lumbar support main body 852 mainly includes the hard portion 11. More specifically, a facing surface 113 is provided that is paired with a portion of the lumbar support body 852 that is elastically deformed by receiving a load, and the lumbar support body 852 is elastically deformed. The elastic deformation characteristics of the lumbar support main body 852 are changed in proximity to each other. That is, the lumbar support main body 852 includes the hard portion 11 that is elastically deformed when a load is applied, and a concave portion is formed on a surface that receives tensile stress due to elastic deformation of the hard portion 11, that is, a rearward surface 853. 112 is formed on the inner side of the recessed portion 112 to form a pair of opposed surfaces 113 that come close to each other with the elastic deformation, and the opposed surfaces 113 directly contact each other when the hard portion 11 is elastically deformed more than a certain amount. Thus, the hard portion 11 is prevented from being deformed beyond the elastic deformation limit. In other words, the lumbar support main body 852 includes the hard portion 11 that elastically deforms in the bending direction when a load is applied, and approaches the outer side in association with the elastic deformation as viewed from the bending direction of the hard portion 11. A pair of opposing surfaces 113 are formed. The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The facing surface 113 is formed on the first and second mounting parts 101 and 102 attached to the outer surface of the lumbar support main body 852, respectively. More specifically, the opposing facing surfaces 113 forming a pair are an outward flange 101a supported by the lumbar support body 852, and an inward flange 102a provided so as to cover the outward flange 101a. And an outward flange 101 a is formed on the first attachment component 101, and an inward flange 102 a is formed on the second attachment component 102. In the lumbar support main body 852, the side on which the load is applied when seated is the inside of the elastic deformation. In this embodiment, a plurality of recessed portions 112 are formed on the rearward surface 853 of the lumbar support main body 852, and the elastomer is not disposed in the recessed portions 112. The recessed portion 112 is formed at a portion corresponding to the waist of the seated person. That is, the recessed portion 112 is formed at the center of the lumbar support main body 852 and at both the left and right sides, and a part of the inside of the recessed portion 112 facing each other serves as the facing surface 113. In other words, the hard portion 11 includes a thin portion 91 and thick portions 92 that are provided on both sides of the thin portion 91 and have a thickness dimension larger than that of the thin portion 91. The recessed portion 112 is formed between the portions 92, and the facing surface 113 is formed inside the recessed portion 112.

  With such a chair 1, when the seated person's waist is strongly pressed against the lumbar support 85, the hard part 11 of the lumbar support body 852 is elastically deformed, and the seated person's waist is softly received. This elastic deformation is the same as that of the first embodiment, and the elastic deformation characteristics of the hard portion 11 change suddenly before and after the opposing surfaces 113 come into contact with each other. It is suppressed that the lumbar support main body 852 is further curved. That is, when the hard part 11 in the lumbar support main body 852 reaches the elastic deformation limit, the facing surfaces 113 come into direct contact with each other. Therefore, further elastic deformation of the lumbar support main body 852 is suppressed. Therefore, with such a lumbar support 85, it is possible to keep the seated person's waist soft while maintaining a certain degree of moderation. In FIG. 6, the lumbar support main body 852 after elastic deformation is shown by a two-dot chain line, and the first and second mounting parts 101 and 102 and other parts are not shown, but these are also described above. Deforms with elastic deformation.

<Fourth embodiment>
Next, a fourth embodiment of the present invention will be described with reference to FIG.

  As shown in FIG. 7, the chair 1 of this embodiment includes a backrest 5 having a shell shape and a back support member 7 that supports the backrest 5, and an upper rear portion of the backrest 5. A hanger 86 is provided. The hanger 86 includes a base 861 attached to the upper end of the back support member 7, a hanger column 862 extending upward from the base 861, and a hanger body 863 supported on the upper end of the hanger column 862. The base 861, the hanger column 862, and the hanger body 863 are integrally formed of a hard synthetic resin.

  The present invention is applied to the hanger column 862 of the chair 1 as described above.

  As shown in FIG. 7, the hanger column 862 is mainly composed of the hard portion 11. More specifically, a facing surface 113 is provided that is paired with a portion of the hanger column 862 that is elastically deformed under a load, and the hanger column 862 is elastically deformed. Thus, the elastic deformation characteristics of the hanger column 862 are changed. That is, the hanger column 862 includes the hard portion 11 that is elastically deformed when a load is applied, and the concave portion 112 is formed on the surface that receives tensile stress due to the elastic deformation of the hard portion 11, that is, the forward-facing surface 864. And a pair of opposing surfaces 113 that come close to each other along with the elastic deformation are formed inside the recessed portion 112, and the opposing surfaces 113 are in direct contact with each other when the hard portion 11 is elastically deformed more than a certain amount. The deformation of the hard part 11 exceeding the elastic deformation limit is suppressed. That is, the hanger column 862 includes the hard portion 11 that elastically deforms in the bending direction when a load is applied. The opposing surface 113 which forms is formed. The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The facing surface 113 is formed on the first and second mounting parts 101 and 102 attached to the outer surface of the hanger column 862, respectively. More specifically, the pair of opposing surfaces 113 are formed on an outward flange 101a supported by the hanger column 862 and an inward flange 102a provided so as to cover the outward flange 101a. An outward flange 101 a is formed on the first attachment component 101, and an inward flange 102 a is formed on the second attachment component 102. As for this hanger support | pillar 862, the opposite side to the side where a load is applied becomes an inner side of elastic deformation. In this embodiment, a plurality of recessed portions 112 are formed on the forward-facing surface 864 of the hanger column 862, and the elastomer is not disposed in the recessed portions 112. The recessed portions 112 are formed at two locations on the top and bottom of the hanger column 862, and a part of the inside of the recessed portions 112 facing each other is used as the facing surface 113. In other words, the hard portion 11 includes a thin portion 91 and thick portions 92 that are provided on both sides of the thin portion 91 and have a thickness dimension larger than that of the thin portion 91. The recessed portion 112 is formed between the portions 92, and the facing surface 113 is formed inside the recessed portion 112.

  With such a chair 1, the hanger support 862 can be elastically deformed rearward relatively easily, so that the operation of putting clothes on the hanger 86 and the operation of removing clothes from the hanger 86 can be easily performed. . This elastic deformation is the same as that of the first embodiment, and the elastic deformation characteristics of the hard portion 11 change suddenly before and after the opposing surfaces 113 come into contact with each other. The hanger column 862 is prevented from further bending. In addition, there is a certain limit to the deformation of the hanger column 862 during the operation, and the hanger column 862 is not deformed unnecessarily, so that unexpected external force acts on the clothes and the hanger column 862 is detached from the hanger 86. Problems can be suppressed. In FIG. 7, the hanger column 862 and the hanger body 863 after being elastically deformed are indicated by a two-dot chain line, and the first and second attachment parts 101 and 102 and other parts are not illustrated. These also deform with the elastic deformation.

  The present invention is not limited to the embodiment described above.

  In the embodiment described above, the opposing surfaces forming a pair are separately formed on the first attachment component and the second attachment component. However, as shown in FIG. 8, only one of the opposing surfaces is the structural material. It may be formed on a mounting part attached to the outer surface. Hereinafter, the same code | symbol is attached | subjected to the location similar to the chair 1 of 1st Embodiment, and detailed description is abbreviate | omitted. In other words, the seat 4 is formed with one of the opposing surfaces 113 formed on the mounting part 102 attached to the downward surface 411 of the seat 4 as a structural material, and the other of the opposing surfaces 113 provided integrally with the seat 4. 433 is formed. More specifically, the opposing facing surfaces 113 forming the pair have an outward flange portion 101a of a protrusion 433 formed integrally with the seat 4, and an inward flange portion provided so as to cover the outward flange portion 101a. 102a, an outward flange 101a is formed on the projection 433, and an inward flange 102a is formed on the mounting part 102. If it is such, the recessed part 112 which makes a complicated shape by simple operation | work of attaching one component can be formed. Further, the shape and / or size of the outward flange formed integrally with the seat is not limited to the illustrated one and can be variously changed. For example, the first mounting component 101 of the first to fourth embodiments described above may be formed integrally with the seat 4.

Further, as another example, as shown in FIGS. 9 to 1 0, both of the opposed surfaces of the pair may be one formed in a single fitting. 9 and 10, the structural material includes a hard portion 11 that elastically deforms in the bending direction when a load is applied, and the elastic material is outwardly viewed from the bending direction of the hard portion 11. A pair of opposing surfaces 113 are formed that come close to each other with deformation, and the opposing surfaces 113 formed at a plurality of locations are formed on a single attachment component 103 attached to the outer surface of the structural material. . The outside as viewed from the bending direction is the side where the internal stress in the tensile direction increases as the bending deformation progresses as a load is applied, and the center of curvature when the bending radius is reduced in the direction of decreasing the radius of curvature. And the opposite side. The attachment component 103 is attached to the hard portion 11 via a gap 104 for enabling the contact surface 113 to contact and separate. Moreover, what is shown in FIG. 11 is a reference example, but the structural material includes a hard portion 11 that elastically deforms in the bending direction when a load is applied. A pair of opposing surfaces 113 are formed on the inner side when viewed from the bending direction, and the opposing surfaces 113 are formed in a plurality of locations. The opposing surfaces 113 are attached to the outer surface of the structural material. The mounting part 103 is formed. The inner side when viewed from the bending direction is the side on which the internal stress in the compression direction increases as the bending deformation progresses as a load is applied, and the center of curvature when bending in a direction in which the radius of curvature decreases Point to the side. As described above, the recessed portion 112 may be provided on the surface that receives the compressive stress due to the elastic deformation of the hard portion 11.

As described above, when the opposing surfaces forming a pair approaching with the elastic deformation are formed on the outer side when viewed from the bending direction of the hard portion, the shape of the recessed portion and the shape of the mounting part are illustrated. Various modifications are possible without being limited to those.

  The mounting method of the mounting part is, for example, fixed through a fastening device such as a screw, fitted into a recessed portion provided in the structural material, or fixed to a protruding portion such as a protruding rib provided in the structural material. Various methods such as sliding from the side and fitting and fixing, or bonding using an adhesive or the like can be employed.

  The place where the facing surface is provided is not limited to that described above, and various changes can be made. For example, you may provide a recessed part in the boundary part of a seat and a backrest. Further, the type of chair is not limited to a pipe chair, and the office rotation includes a leg, a seat supported by the leg via a support mechanism, and a backrest supported by the seat. It may be applied to a chair.

  In the embodiment described above, the case where no elastomer is arranged in the recessed portion has been described, but it is needless to say that the elastomer may be arranged in the whole or a part of the recessed portion. As an example in which the elastomer is arranged on a part of the recessed portion, those shown in FIG. 13 and FIG. 14 can be cited. In the chair 1 as a structural material, an elastomer 12 which is a resin having rubber elasticity is disposed between opposing surfaces 113. More specifically, the opposing facing surfaces 113 forming the pair have an outward flange 101a of a projection 433 formed integrally with the seat 4, and an inward flange provided so as to cover the outward flange 101a. An outward flange 101a is formed on the projection 433, and an inward flange 102a is formed on the mounting part 102. The attachment component 102 is attached to the seat 4 using a fastening tool B such as a screw. More specifically, a mounting recess that forms one end side of the elastomer 12 on the outward flange portion 101a of the protrusion 433 and an attachment recess that distributes the other end side of the elastomer 12 to the inward flange portion 102a of the mounting component 102 are provided. And the elastomer 12 is disposed between the both mounting recesses. When a downward load is applied to the chair 1, the facing surface 113 gradually approaches while compressing and deforming the elastomer 12 that is an elastic material between the facing surfaces 113. Therefore, it is possible to improve the sitting comfort by giving an appropriate elastic deformation. In the case where the elastomer is disposed on the entire recessed portion, when the hard portion is deformed to a predetermined elastic deformation limit, the opposed surfaces approach each other via the elastomer, and the elastomer is applied to a portion of the recessed portion. In the case of arranging, when the hard portion is deformed to a predetermined elastic deformation limit depending on the arrangement method, the facing surfaces are in direct contact with each other, and the facing surfaces are approached via an elastomer You could think so. Moreover, what kind of thing may be sufficient also about the shape of the elastomer distribute | arranged in a recessed part. Furthermore, it goes without saying that the outward flange portion may be formed in a mounting part separate from the seat.

  In the embodiment described above, the ratio of the thickness dimension between the thick part and the thin part may be set as appropriate according to the required elastic deformation characteristics.

  In addition, various changes may be made without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Chair 101,102,103,105 ... Mounting component 101a ... Outward collar part 102a ... Inward collar part 11 ... Hard part 112 ... Recessed part 113 ... Opposite surface 12 ... Elastomer

Claims (6)

A structural material that is elastically deformed under a load is provided, and a pair of opposing surfaces are provided at a portion of the structural material that is elastically deformed. The deformation characteristics are configured to change, and at least one of the facing surfaces is formed on a mounting part attached to the outer surface of the structural material ,
The structural material is provided with a hard portion that is elastically deformed when a load is applied, and a pair of opposing surfaces are formed on the outside as viewed from the bending direction of the hard portion and approached with the elastic deformation. A chair characterized by that. The opposing surfaces forming the pair are formed on an outward flange supported by a structural material, and an inward flange provided to cover the outward flange, and at least inward The chair according to claim 1, wherein a collar portion is formed on the attachment part. The chair according to claim 1 or 2, wherein the structural material has an elastic deformation inner side opposite to a side on which a load is applied when seated. The chair according to claim 1 or 2, wherein the structural material is such that a side on which a load is applied when sitting is an inner side of elastic deformation. The chair according to claim 1, 2, 3, or 4, wherein the structural material is configured such that the opposing surfaces directly contact each other when the structural material is elastically deformed more than a certain amount. The chair according to claim 1, 2, 3, 4, or 5, wherein the structural material includes a recessed portion that forms the facing surface, and an elastomer is disposed on all or a part of the recessed portion. .

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