JP2023080189A - folding chair - Google Patents

Abstract

To provide a compact folding chair which is simply structured and which is small in a width direction dimension of front and rear legs.SOLUTION: A folding chair 10 includes: a pair of front legs 12; a pair of rear legs 14 rotatably journaled for the front legs 12; and a seat part 16 which is rotatable for the front legs 12 and the rear legs 14 between a horizontal state and a flipped-up state. Then, with the rear legs 14 arranged in an inner side from the front legs 12, the seat part 16 is rotatably journaled on spindle legs by one of the front legs 12 and the rear legs 14 as the spindle legs. Further, a position in which the rear legs 14 are journaled for the front legs 12 is set forward from the position where the seat part 16 is journaled for the spindle legs. Also, the spindle provided in the spindle legs possesses an extension part which is extended outward from the rear legs 14, and caused to support the front legs 12 when the folding chair 10 is opened by the extension part.SELECTED DRAWING: Figure 5

Description

The present invention relates to foldable chairs.

Conventionally, many foldable chairs have been developed that can be folded to save space when not in use (for example, Patent Document 1).

The folding chair disclosed in Patent Document 1 is provided with a release operation tool on the back surface of the backrest, and by operating the release operation tool, the lock device provided on the bottom surface of the seat part can be unlocked. is now possible.

JP 2016-105911 A

However, the folding chair disclosed in Patent Document 1 has a problem that the mechanism for flipping up the seat portion when folded is complicated, and that the widthwise dimension of the front and rear legs is larger than the widthwise dimension of the seat portion. ,

SUMMARY OF THE INVENTION It is an object of the present invention to provide a compact folding chair having a simple structure and a small widthwise dimension of the front and rear legs.

According to one aspect of the invention,
A pair of front legs, a pair of rear legs rotatably supported with respect to the front legs, and a seat rotatable with respect to the front legs and the rear legs between a horizontal state and a flipped state. A folding chair comprising:
The rear legs are arranged inside the front legs,
The seat portion is rotatably supported by the rear leg as a pivot leg,
The position at which the rear leg is pivotally supported with respect to the front leg is forward of the position at which the seat portion is pivotally supported with respect to the pivot leg,
A support shaft provided on the support shaft leg has an extension portion extending outward from the rear leg, and the extension portion supports the front leg when the folding chair is unfolded. is provided.

According to the present invention, the folding mechanism can be configured with a simple structure, and the widthwise dimension of the front and rear legs can be made smaller than the widthwise dimension of the seat portion. As described above, it is possible to provide a compact folding chair with a simple structure and a small width dimension of the front and rear legs.

It is a perspective view of folding chair 10 concerning an embodiment to which the present invention was applied. It is a front view of folding chair 10 concerning an embodiment to which the present invention was applied. It is a rear view of folding chair 10 concerning an embodiment to which the present invention was applied. 1 is a plan view of a folding chair 10 according to an embodiment to which the present invention is applied (state (a) in which armrests 24 are unfolded; state (b) in which they are flipped up). FIG. It is a bottom view of folding chair 10 concerning an embodiment to which the present invention was applied. It is a left side view of folding chair 10 concerning an embodiment to which the present invention was applied. 1 is a perspective view showing a folded state of a folding chair 10 according to an embodiment to which the present invention is applied; FIG. It is the figure which expanded centering on the bottom face of the seat part 16 in the state which folded the folding chair 10. FIG. FIG. 11 is a perspective view of the folding chair 10 according to Modification 1 in a folded state; FIG. 11 is a perspective view of the foldable chair 10 according to Modification 1 in an unfolded state; FIG. 11 is a perspective view of the folding chair 10 according to Modification 2 in a folded state; FIG. 11 is a perspective view of the folding chair 10 according to Modification 3 in a folded state; It is the figure which expanded centering on the bottom face of the seat part 16 in the state which folded the folding chair 10 which concerns on the modification 4. FIG. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to Modification 5 is folded. FIG. 11 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to Modification 6 is folded. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to Modification 7 is folded. FIG. 14 is a plan view showing the shape of the seat surface of the seat portion 16 of the folding chair 10 according to Modification 8; FIG. 14 is a plan view showing the shape of the seat surface of the seat portion 16 of the folding chair 10 according to Modification 8; FIG. 21 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to Modification 9 is folded. FIG. 14 is a cross-sectional view of the folding chair 10 according to Modification 9 in a folded state; FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to another embodiment of Modification 9 is folded. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to another embodiment of Modification 9 is folded. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to another embodiment of Modification 9 is folded. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to another embodiment of Modification 9 is folded. FIG. 12 is an enlarged view centering on the bottom surface of the seat portion 16 in a state where the folding chair 10 according to another embodiment of Modification 9 is folded. FIG. 3 is a schematic diagram for explaining the structure of an armrest 24; FIG. 3 is a cross-sectional view for explaining the structure of an armrest 24; FIG. 11 is a perspective view for explaining the structure of the first modification of the armrest 24; FIG. 11 is a cross-sectional view for explaining the structure of a modified example 1 of the armrest 24; It is a figure for demonstrating the structure regarding the modified example 2 of the armrest 24. FIG. It is a figure for demonstrating the structure regarding the modified example 3 of the armrest 24. FIG. It is a figure for demonstrating the structure regarding the modified example 3 of the armrest 24. FIG. FIG. 13 is a diagram showing a pivotal support means 133 according to Modified Example 3 of the armrest 24; FIG. 16 is a diagram showing a state in which a shaft member 168 is pulled out in relation to Modified Example 3 of the armrest 24; FIG. 3 is a schematic diagram showing the positional relationship among a shaft support means 133, a receiving portion 146, and a contact portion 148; FIG. 36 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the embodiment shown in FIG. 35; FIG. 10 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 1; FIG. 10 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 1; FIG. 12 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modified example 2; FIG. 10 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modified example 2; FIG. 12 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 3; FIG. 12 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 3; FIG. 13 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 4; FIG. 12 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 4; FIG. 12 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 5; FIG. 13 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modified example 5; FIG. 14 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 6; FIG. 13 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the body member 144 is not provided in the positional relationship modification 6; FIG. 14 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification example 7; FIG. 13 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 7; FIG. 14 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 8; FIG. 14 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 8; FIG. 14 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 in the positional relationship modification 9; FIG. 13 is a schematic diagram showing the positional relationship among the pivot means 133, the receiving portion 146, and the contact portion 148 when the main body member 144 is not provided in the positional relationship modification 9;

(Regarding the configuration of the folding chair 10)
A configuration of a folding chair 10 (hereinafter simply referred to as "chair 10") according to the present embodiment will be described with reference to FIGS. 1 to 7. FIG. The chair 10 according to this embodiment generally includes a pair of front legs 12, a pair of rear legs 14, a seat portion 16, a link connecting bar 18, a link bar 20, a backrest 22, and armrests 24. there is It should be noted that the backrest 22 and armrests 24 are not essential components of the present invention and may be omitted.

Throughout this specification, the direction in which the user sitting on the chair 10 faces is referred to as "forward", and the opposite direction is referred to as "backward".

The front leg 12 is a member formed by bending a pipe material having a circular cross section. In this embodiment, the front legs 12 have a backrest support portion 26 extending slightly forward and downward from the rear to the front when the chair 10 is unfolded (that is, the state shown in FIGS. 1 to 6). , followed by a horizontal portion 28 that extends horizontally, and a front leg portion 30 that follows the horizontal portion 28 and extends forward and downward again. A leg rubber 32 is attached to the lower end of the front leg portion 30 .

The pair of front legs 12 are connected to each other by horizontally extending backrest mounting portions 34 at the upper ends of the respective backrest support portions 26 . That is, the pair of front legs 12 in this embodiment are formed by bending one pipe material. Of course, the pair of front legs 12 may be configured by combining a plurality of pipe materials.

The lower end of the front leg 12 in this embodiment has a double-pipe structure, and a plurality of height adjustment holes 38 are formed on the surface of the outer pipe 36 at predetermined intervals. is provided with a height adjusting pin 42 which can be retracted from the surface of the inner pipe 40 and which is fitted into one of the height adjusting holes 38 . Thereby, the height from the floor to the seat portion 16 can be adjusted by adjusting the length of the front leg portion 30 of the front leg 12 .

Like the front leg 12, the rear leg 14 is a member formed by bending a pipe material having a circular cross section. In this embodiment, the rear legs 14 are composed of a seat support portion 44 extending slightly rearward and downward from the horizontal direction from the front to the rear in the unfolded state of the chair 10, and a rear support portion 44 extending rearward and downward. It is configured integrally with the leg portion 46 . A leg rubber 48 is also attached to the lower end of the rear leg portion 46 . Further, in this embodiment, each rear leg 14 is made of a different pipe material.

Similarly to the front leg 12, the lower end of the rear leg 14 also has a double-pipe structure. From 54 , a height adjusting pin 56 is provided which can be retracted from the surface of the inner pipe 54 and which is fitted into any of the height adjusting holes 52 .

In this embodiment, the rear legs 14 are arranged inside the front legs 12 . The pair of front legs 12 and the pair of rear legs 14 are rotatably pivoted to each other at the central portion of the horizontal portion 28 of the front legs 12 and the tip portion of the seat support portion 44 of the rear legs 14 . there is Specifically, a front leg-side pivot hole 58 is formed in the central portion of the horizontal portion 28 of the front leg 12, and a rear leg-side pivot hole 60 is formed in the front end portion of the seat support portion 44 of the rear leg 14. The front leg 12 and the rear leg 14 are rotatable relative to each other by inserting the pivot pin 62 through them. Further, as shown in FIG. 6, the pivotal support positions of the front leg 12 and the rear leg 14 in this embodiment (that is, the position where the front leg-side pivotal support hole 58 and the like are formed) are the front end of the front leg 12 and the rear leg 12. It is in an intermediate position between the rear ends of the legs 14 . The position of the front leg side support hole 58 for supporting the rear leg 14 on the front leg 12 is not limited to the central portion of the horizontal portion 28 of the front leg 12 as described above. , the front leg side pivot hole 58 may be provided at a position close to the front leg portion 30 .

In the present embodiment, a seat support pin 64 for supporting the seat 16 with the rear leg 14 is fitted slightly behind the rear leg side support hole 60 in the seat support 44 of the rear leg 14 . A seat portion shaft support hole 66 into which the seat portion is inserted is formed. In other words, the pair of rear legs 14 in this embodiment serve as "supporting legs" that rotatably support the seat portion 16. As shown in FIG. Further, the position at which the rear leg 14 is pivotally supported with respect to the front leg 12 (for example, the position of the rear leg-side pivot hole 60) is such that the seat portion 16 is pivotally supported with respect to the pivot leg (that is, the rear leg 14). It is in front of the position where it is located (that is, the seat portion pivot hole 66).

Furthermore, in the present embodiment, a front leg support portion 63 that supports the horizontal portion 28 of the front leg 12 from below when the chair 10 is unfolded is provided at the position of the seat portion pivot hole 66 in the seat portion support portion 44 of the rear leg 14 . It protrudes outward. The front leg support portion 63 has a portion of the seat portion pivot pin 64 that protrudes outward from the rear leg 14, and the seat portion pivot pin 64 is inserted through the center of the pipe-shaped front leg support member 65. It is composed by

The seat portion 16 is a member having a seat surface on which the user sits, and is rotatable with respect to the front legs 12 and the rear legs 14 between a horizontal state and a raised state. Specifically, as described above, the seat portion 16 is rotatably supported by the seat portion pivot pin 64 between the pair of rear legs 14 which are pivot legs. For this reason, seat portion pivot pin holes 68 for receiving the seat portion pivot pins 64 are formed on both rear side surfaces of the seat portion 16 in this embodiment. In this embodiment, the seat surface of the seat portion 16 has a relatively wide front portion and a relatively narrow rear portion (see FIG. 4B).

Further, as shown in FIG. 8, a stopper 70 is provided at the front central portion of the bottom surface of the seat portion 16 to engage with the link connection bar 18 when the seat portion 16 is in a horizontal state with the chair 10 unfolded. It is The stopper 70 in this embodiment has an engaging claw 72 formed at its lower end portion which is pivotably attached to the bottom surface of the seat portion 16 , and the engaging claw 72 is engaged with the link connection bar 18 . By doing so, the horizontal state of the seat portion 16 can be maintained.

Further, on both sides of the front side of the bottom surface of the seat portion 16, there are provided a pair of support plates that support the front portion of the seat portion 16 with the link connection bars 18 by coming into contact with the link connection bars 18 when the seat portion 16 is in a horizontal state. are formed, and fitting grooves 76 into which the link connecting bars 18 are fitted are formed in the supporting projections 74 respectively.

A pair of brackets 78 are provided on the bottom surface of the seat portion 16 slightly forward of the position where the seat portion pivot pin hole 68 at the rear end portion is formed. The bracket 78 is composed of a pair of bracket plate members 80 facing each other in parallel. Also, each bracket plate member 80 is formed with a shaft mounting pin insertion hole 81 into which a shaft mounting pin 79 for shaft mounting the other end of the link bar 20 to the bracket 78 is inserted.

The position where the pair of brackets 78 are provided is not limited to the position forward of the position where the seat pivot pin hole 68 at the rear end of the bottom surface of the seat 16 as described above is formed. It may be behind the position where the axial support pin hole 68 is formed.

Further, the seat portion 16 in this embodiment is configured by overlapping a seat portion surface member formed of a relatively soft material on a seat portion bottom member formed of a relatively hard material. Of course, the seat portion 16 may be made of one kind of material, or may be made of three or more kinds of materials.

The link connection bar 18 is a member formed by bending a solid bar with a circular cross section, and one end of the link connection bar 18 is connected to the inner surface of the portion where the horizontal portion 28 and the front leg portion 30 of one front leg 12 are connected to each other. The other end is connected to the inner surface of the portion where the horizontal portion 28 and the front leg portion 30 of the other front leg 12 are connected to each other. Further, the link connection bar 18 in this embodiment has end portions 82 extending substantially horizontally inward from both ends, and a central portion 84 extending substantially horizontally in the center portion slightly forward and slightly below the end portions 82 . is integrally composed of

The engaging claw 72 of the stopper 70 on the seat portion 16 described above engages with the central portion 84 of the link connecting bar 18 . Also, the end portion 82 of the link connection bar 18 is fitted into the fitting groove 76 of the support protrusion 74 in the seat portion 16 .

Thus, the pair of front legs 12 in this embodiment are "link legs" with the link connecting bar 18 installed therebetween.

One end of the link bar 20 is rotatably connected to the link connection bar 18 (more precisely, the end 82 of the link connection bar 18), and the other end is rotatably connected to the bottom surface of the seat 16. It is a movably connected member.

Still referring to FIG. 8, in this embodiment, one end of the link bar 20 is composed of a link bar body member 86 and a link connection bar clamping member 88, and the link bar body member 86 and the link connection bar clamping member Recesses 90 and 92 into which the link connecting bar 18 is fitted are formed in the mutually facing surfaces of 88, respectively. The link bar body member 86 and the link connection bar clamping member 88 are united using screws 94 or the like so that the link connection bar 18 is sandwiched between the recesses 90 and 92 , respectively, so that one end of the link bar 20 is connected to the link connection bar 18 . is rotatably connected to the

The other end of the link bar 20 is formed with an attachment pin insertion hole 96 for attaching the other end of the link bar 20 to the bracket 78 formed on the bottom surface of the seat portion 16 . By inserting the shaft mounting pin 79 into the shaft mounting pin insertion hole 81 formed in the bracket 78 and the shaft mounting pin insertion hole 96 , the other end of the link bar 20 is pushed against the bottom surface of the seat portion 16 . rotatably connected.

In this embodiment, a reinforcing bar 21 is installed between the pair of rear legs 14, which are "supporting legs", but the reinforcing bar 21 is not an essential component of the present invention.

Returning to FIG. 1 to FIG. 7, the backrest 22 is a member for supporting the back of the user sitting on the seat portion 16 from behind. It is attached to the attachment portion 34 . Of course, the backrest 22 may be attached, for example, to the backrest supports 26 of the pair of front legs 12, or may be attached to other members.

The armrest 24 is a member for the user sitting on the seat portion 16 to rest his or her elbow. In this embodiment, a pair of armrests 24 are attached so as to protrude forward from the central portion of the backrest attachment portion 34 of the pair of front legs 12 . Further, the armrest attachment portion 98, which is the attachment portion of each armrest 24 to the front leg 12, is configured so that the tip of the armrest 24 can rotate with respect to the front leg 12, and the chair 10 is unfolded. Rotation is stopped at a position where the armrest 24 is substantially horizontal. Of course, armrest 24 may be attached to other members.

(Procedure for folding the folding chair 10)
According to the folding chair 10 of the embodiment described above, it can be folded from the unfolded state (the state shown in FIGS. 1 to 6) by the following procedure. That is, the stopper 70 provided on the bottom surface of the seat portion 16 is swung, and the engaging claw 72 formed on the lower end portion of the stopper 70 is removed from the link connection bar 18 . After that, the front end portion of the seat portion 16 is lifted (flipped up) around the seat portion pivot pin 64 inserted into the rear end side surface of the seat portion 16 .

Then, the seat portion 16 rotates about the seat portion pivot pin 64 with respect to the pair of rear legs 14, and the link bar 20 connected to the bracket 78 provided on the bottom surface of the seat portion 16 creates a link connection. A pair of front legs 12 rotate in a direction approaching rear legs 14 via a bar 18 . This results in the chair 10 being folded as shown in FIG. 7 with the seat 16 fully raised. In this embodiment, the pair of armrests 24 are not linked to the above-described folding operation by lifting the seat portion 16, and the user separately flips up the armrests 24 with respect to the front legs 12. .

In order to return from the folded state shown in FIG. 7 to the unfolded state shown in FIGS. 1 to 6, the procedure described above may be reversed.

(Features of folding chair 10)
According to the chair 10 of the present embodiment, the link connection bar constructed between the bottom surface of the seat portion 16 rotatably supported by the rear legs 14, which are pivot legs, and the front legs 12, which are link legs. 18 and the link bar 20 is rotatably arranged, and the rear leg 14 is arranged inside the front leg 12 together with the link bar 20, so that the folding mechanism can be configured with a simple structure. Moreover, the widthwise dimension of the front legs 12 and the rear legs 14 can be made smaller than the widthwise dimension of the seat portion 16 . As described above, it is possible to provide a compact folding chair 10 having a simple structure and a small width dimension of the front legs 12 and the rear legs 14 .

(Modification 1)
In the above-described embodiment, the rear leg 14 is the "supporting leg" that rotatably supports the seat portion 16, and the front leg 12 is the "link leg" on which the link connection bar 18 is installed. but this can be replaced. That is, as shown in FIGS. 9 and 10, the seat portion 16 rotates around the front leg-side pivot hole 100 formed in the horizontal portion 28 of the front leg 12 by the pivot pin 62. The front leg 12 serves as a "supporting leg" that rotatably supports the seat portion 16. As shown in FIG. Each end of the link connection bar 18 is connected to the side surface of the rear end of the seat support portion 44 of each rear leg 14, and the rear leg 14 serves as a "link leg" on which the link connection bar 18 is installed. there is

In the case of Modification 1, the seat portion support bar 102, which has a role of supporting the front end portion of the bottom surface of the seat portion 16 in the unfolded state, is positioned between the connecting positions of the horizontal portion 28 and the front leg portion 30 of the pair of front legs 12. erected in between.

Further, the stopper 70 provided on the bottom surface of the seat portion 16 may be provided on the front end portion of the bottom surface of the seat portion 16 and engaged with the seat portion support bar 102, as in the above-described embodiment. , and may be provided at the rearward end of the bottom surface of the seat 16 to engage the link connecting bar 18, as shown in FIGS.

(Modification 2)
Further, in the above-described embodiment, the seat 16 is rotated by pulling up the front end of the seat 16 to fold the chair 10. Instead of this, as shown in FIG. The seat portion 16 may be rotated by pulling up the rear end of the portion 16 . In this case, when the chair 10 is unfolded, the position at which the rear leg 14 is pivotally supported with respect to the front leg 12 (for example, the position of the rear leg side pivot hole 60) is the opposite of the above-described embodiment. It is behind the position (that is, the seat portion pivot hole 66) where the seat portion 16 is pivotally supported with respect to the leg (that is, the rear leg 14).

(Modification 3)
Further, as shown in FIG. 12, the front legs 12 are used as "supporting legs", the rear legs 14 are used as "link legs", and the rear end of the seat portion 16 is pulled upward to fold the chair 10. good too.

(Modification 4)
In the embodiment described above, as shown in FIG. 8, the other end of the link bar 20 is fitted between the pair of bracket plate members 80 forming the bracket 78. As shown in FIG. 2, a shaft mounting pin insertion hole 81 into which the shaft mounting pin 79 is inserted may be provided in the side portion of the rear end portion of the seat portion 16, and the other end portion of the link bar 20 may be shaft mounted therein. .

(Modification 5)
Further, as shown in FIG. 14, a protrusion 104 extending in the width direction of the chair 10 is formed from the rear end of the bottom surface of the seat portion 16, and a pivot pin is inserted into the end face of the chair 10 in the width direction of the protrusion 104. A hole 81 may be formed into which the other end of the link bar 20 may be pivotally attached.

(Modification 6)
Further, as shown in FIG. 15, two protruding portions 106 are formed from the rear end portion of the bottom surface of the seat portion 16, and each of these protruding portions 106 is formed with a shaft attachment pin insertion hole 81. The other end of the link bar 20 may be pivotally attached to the outer end surface of the portion 106 .

(Modification 7)
Further, as shown in FIG. 16, two protruding portions 106 are formed from the rear end portion of the bottom surface of the seat portion 16, and each of these protruding portions 106 is formed with a shaft attachment pin insertion hole 81. The other end of the link bar 20 may be pivotally attached to the inner end surface of the portion 106 .

As mentioned in Modifications 4 to 7, the manner of connection between the bottom surface of the seat portion 16 and the other end portion of the link bar 20 is not limited to a particular manner, but in any manner, the pivot leg ( For example, the position at which the other end of the link bar 20 is pivoted (that is, the position of the pivot pin insertion hole 81) is better than the position at which the seat portion 16 is pivotally supported with respect to the rear leg 14). It is located near the link connection bar 18 .

(Modification 8)
As shown in FIG. 4B, the seat surface of the seat portion 16 in the above-described embodiment has a relatively wide width at the front portion and a relatively narrow width at the rear portion. The shape of the seat surface of 16 is not limited to this. For example, as shown in FIG. As shown at 18, the width of the front portion and the width of the rear portion may be set the same.

(Modification 9)
Further, as shown in FIG. 19, a rotation urging member 110 may be provided that acts on the bottom surface of the seat portion 16 to urge the seat portion 16 to rotate upward. In the embodiment shown in FIG. 19, a torsion spring is used as the rotational biasing member 110 . This torsion spring is a so-called "double" torsion spring, and two "single" torsion springs each having a coil portion 112, a first arm portion 114, and a second arm portion 116 are integrated together. It is formed and constitutes the rotation biasing member 110 of the present embodiment. Specifically, the tip portions of both first arm portions 114 are bent substantially at a right angle, and the tip portions of the first arm portions 114 are connected to each other.

Also, the length of the pivot pin 79 for pivoting the other end of the link bar 20 to the bracket 78 formed on the bottom surface of the seat portion 16 is set to be longer than the width of the bracket 78. , and both end portions of the shaft attachment pin 79 projecting from the bracket 78 are inserted into the both coil portions 112 to be positioned. Furthermore, the tip portions (portions bent substantially at right angles) of both of the first arm portions 114 described above abut on the surface of the link bar 20 . Further, as shown in FIG. 20, the tip of the second arm portion 116 is also bent substantially at a right angle, and the bent tip is inserted into a fixing hole 120 formed in the bottom surface of the seat portion 16. there is

As a result, the rotation biasing member 110 , which is a “double” torsion spring, acts on the bottom surface of the seat portion 16 to bias the bottom surface of the seat portion 16 to rotate upward with respect to the link bar 20 . To lift a seat part 16 with a little force to fold a folding chair 10, and to maintain the folded state by preventing the seat part 16 from undesirably rotating downward from the folded state. can be done.

In the embodiment shown in FIG. 19, a "double" torsion spring pivot biasing member 110 was attached to both link bars 20, but of course either one of the link bars could be mounted as shown in FIG. The rotation biasing member 110 may be attached only to 20 .

Also, as shown in FIG. 22, a “single” torsion spring may be used as the rotational biasing member 110 .

Furthermore, as shown in FIG. 23, a so-called compression spring may be used as the rotation biasing member 110. FIG. In this case, one end of the push spring (rotational biasing member 110 ) is in contact with the bottom surface of the seat portion 16 and the other end is in contact with the surface of the link bar 20 . Of course, in this embodiment, an elastomer such as rubber having a predetermined elastic force can be used in place of the compression spring.

Further, as shown in FIG. 24, a leaf spring formed by bending a strip-shaped member may be used as the rotation biasing member 110 . In this embodiment, the leaf spring (rotation biasing member 110) is arranged so that one end thereof abuts the bottom surface of the seat portion 16 and the other end abuts the surface of the link bar 20. be.

25 is also included in the "rotation biasing member 110 that acts on the bottom surface of the seat portion 16 and biases the seat portion 16 to rotate upward". In this embodiment, a "single" torsion spring is used as the pivot biasing member 110 . The tip of the pivot pin 62 that rotatably attaches the front leg 12 and the rear leg 14 to each other protrudes toward the inside of the folding chair 10, and this protruding tip is fitted into the coil portion 112 of the torsion spring. inserted. An arm locking pin 122 projects inward from the side surface of the horizontal portion 28 of each front leg 12 . Furthermore, the first arm portion 114 of the torsion spring (rotation biasing member 110 ) is locked by the arm locking pin 122 , and the second arm portion 116 contacts the bottom surface of the seat portion 16 . As a result, the torsion spring (rotation biasing member 110) acts on the bottom surface of the seat portion 16 to bias the seat portion 16 upward.

(Regarding the armrest 24)
Next, the armrests 24 attached to the folding chair 10 according to the present invention will be described in detail. As described above, the armrest 24 has the armrest mounting portion 98 , and the tip of the armrest 24 is rotatable with respect to the frame 130 that extends above the seat portion 16 of the front leg 12 . Also, the armrests 24 are not essential components of the present invention, but they do not have to be provided on the folding chair 10, that is, they can be freely or freely attached.

As shown in FIGS. 26 and 27, the armrest 24 generally includes an armrest main body 132, pivot means 133, and rotation restricting means 134. As shown in FIGS. In addition, the above-described armrest mounting portion 98 is composed of the shaft support means 133 and the rotation restricting means 134 .

The armrest main body 132 is a substantially linear rod-shaped member, and one end portion provided with the armrest mounting portion 98 is attached to the frame 130 of the front leg 12 . Since the armrest main body 132 is a member that is directly touched by the user, it is preferable to cover the surface of the armrest main body 132 with a soft material such as urethane or resin.

A pair of left and right mounting portions 138 are formed at one end of the armrest main body 132 so as to face each other (FIG. 27), and the frame 130 is fitted between the mounting portions 138 .

Furthermore, a receiving rod 147 is provided between the pair of mounting portions 138 of the armrest body 132 . When the armrest body 132 is rotated downward to the unfolded position where the user can use the receiving rod 147, the receiving rod 147 is located at a position lower than the pivot means 133 and in front of the frame 130. It is disposed at a position where it abuts on the main body member 144 on the side.

The pivot means 133 is means for rotatably attaching the armrest main body 132 to the frame 130 of the front leg 12, and may be, for example, a hexagonal socket bolt/nut. In this embodiment, the pair of mounting portions 138 of the armrest main body 132 are formed with pivoting means insertion holes 140 respectively, and the main body member 144 is also formed with a pivoting means insertion second hole 141. , and the frame 130 of the front leg 12 is also formed with a pivot means insertion hole 142 . The shaft support means 133 has a shaft support means insertion hole 140 on one side, a shaft support means insertion second hole 141, a shaft support means insertion hole 142, and a shaft support means insertion second hole 141 and a shaft support means insertion hole 140 on the other side in this order. The armrest main body 132 is rotatably attached to the frame 130 by being inserted.

The rotation restricting means 134 has a substantially cylindrical body member 144 , a receiving portion 146 and a contact portion 148 in this embodiment.

The body member 144 is a member that covers a portion of the frame 130 to which the armrest body 132 is attached. The main body member 144 according to this embodiment has a half-split structure and is composed of a pair of main body member pieces 145 . By combining these body member pieces 145 so as to sandwich the frame 130 , the body member 144 covering the frame 130 is completed. After the body member 144 is attached, the frame 130 is fitted between the pair of attachment portions 138 of the armrest body 132 together with the body member 144 .

The receiving portion 146 is a portion that directly receives a force applied in a direction to rotate the other end (tip portion) of the armrest body 132 further downward when the armrest body 132 is in the unfolded state. In this embodiment, the portion of the main body member 144 that is abutted by the above-described receiving rod 147 corresponds to this receiving portion 146 .

The contact portion 148 is a portion that theoretically rotates the main body member 144 about the pivotal support means 133 due to the force applied to the above-described receiving portion 146 and presses the frame 130 from the outside. In this embodiment, the end of the main body member 144 above the pivot means 133 and on the rear side of the frame 130 serves as the contact portion 148 .

In this embodiment, a cover 150 is attached to the outer surface of the armrest main body 132 at a position corresponding to the attachment portion 138 so that the pivotal support means 133 and the receiving rod 147 are not directly visible from the outside. Note that the cover 150 is not an essential component of the present invention.

The armrest 24 according to the present embodiment is pivotally supported by the frame 130 of the front leg 12 by the pivot means 133, and is received when the armrest main body 132 is rotated downward to the unfolded position where the user can use it. The rod 147 presses the receiving portion 146 of the main body member 144, and the frame 130 receives a part of this force through the pivot means 133, and the contact portion 148 of the main body member 144 contacts the frame 130 to absorb the rest of the force. , the armrest main body 132 can be rotated with respect to the frame 130 from the unfolded position that can be used by the user to the storage position in which the armrest body 132 can be erected substantially vertically. The armrest body 132 can maintain its deployed position even if a force is applied to further rotate the armrest body 132 downward.

In addition, the main body member 144 is attached so as to cover the frame 130, and the receiving rod 147 is provided between the attachment portions 138 formed in the armrest main body 132, so that after the shaft support means 133 is extracted, When the armrest main body 132 and the main body member 144 are removed from the frame 130, only the pivot means insertion hole 142 remains in the frame 130, and no projections or the like remain undesirably. Therefore, the folding chair 10 without the armrests 24 can be used without any sense of incongruity even when the armrests 24 are entirely removed.

(Modification 1 of armrest 24)
In the embodiment described above, a hexagon socket bolt is used as the pivot means 133, but instead of this, a knurled bolt may be used as shown in FIGS. 28 and 29. FIG. By using the knurled bolt as the pivoting means 133 in this way, when the armrest 24 is unnecessary, such as when the user is in a low-care state, the pivoting means 133 can be removed without using a tool and the armrest main body can be mounted. The entire armrest 24 can be removed by removing 132 from the frame 130 and then removing the body member 144 from the frame 130 .

(Modification 2 of armrest 24)
As another example of the shaft support means 133 that can be removed without using a tool, as shown in FIG. You may

One end of the shaft member 162 is connected to the central position of the inner surface of one disk-shaped member 160, and the other end is formed with a male screw. A female screw into which the male screw is screwed is formed at the center position on the inner surface of the other disk-shaped member 160 . Further, on the outer surface of each disk-shaped member 160, a knob 164 is protrusively formed to be gripped by the user when turning the disk-shaped member 160. As shown in FIG.

As a result, when the armrest 24 is attached to the frame 130 , the tip of the shaft member 162 is inserted into the shaft support means insertion hole 140 or the like, and the knob 164 is turned to engage the female screw formed in the other disk-shaped member 160 . screw together. Conversely, when the armrest 24 is removed from the frame 130, the knob 164 is turned to separate the disc-shaped members 160 from each other, and the shaft member 162 is pulled out from the shaft member insertion hole 140 or the like, thereby removing the entire armrest 24. be able to.

(Modification 3 of armrest 24)
Furthermore, as another example of the shaft support means 133 that can be removed without using a tool, as shown in FIGS. The member 172 and the shaft pressing member urging member 174 may be used.

A shaft member insertion hole 176 into which the shaft member 168 is slidably inserted is formed in the disk-shaped member 166 (FIG. 33). A shaft pressing member 172 is rotatably attached to the surface of the disk-shaped member 166 , and a shaft pressing member biasing member 174 is positioned at a position at which the shaft pressing member 172 biases the tip of the shaft member 168 in a direction of pressing the shaft member 168 . is arranged. Furthermore, the tip of the shaft member 168 is rotatably attached to the shaft pressing member 172 .

As a result, in the natural state, the shaft member 168 is pushed into the shaft member insertion hole 176 by the shaft pressing member 172 biased by the shaft pressing member biasing member 174 pressing the tip of the shaft member 168 . Since the disk-shaped member 166 itself is fixed to the armrest main body 132, the opposite end of the shaft member 168 is inserted into the shaft support means insertion hole 142 while the shaft member 168 is pushed in. there is

In this way, since the shaft members 168 are inserted into the shaft support means insertion holes 142 from both sides of the frame 130 , the armrest main body 132 is attached to the frame 130 .

Conversely, when the armrest 24 is removed from the frame 130, by inclining the shaft pressing member 172 in the opposite direction against the biasing force of the shaft pressing member biasing member 174 (FIG. 34), the shaft member 168 is supported. It is pulled out from the means insertion hole 142 . This allows the entire armrest 24 to be removed without the use of tools.

(Modified example of positional relationship between shaft support means 133, receiving portion 146, and contact portion 148)
In the above-described embodiment, the positional relationship between the pivot means 133, the receiving portion 146, and the contact portion 148 is such that the pivot means 133 passes through the frame 130, and the bearing portion 146 is positioned as shown in FIG. The position is lower than the position of the pivotal support means 133 and is on the front side of the frame 130 (the side facing when the user sits on the seat portion 16; the same shall apply hereinafter). is higher than the position of the pivot means 133 and on the back side of the frame 130 (the side opposite to the front side described above; the same applies hereinafter).

If the main body member 144 is not provided, a receiving rod 147 is provided between the pair of mounting portions 138 of the armrest main body 132 as shown in FIG. More specifically, in the deployed position of the armrest 24 , the position of the receiving rod 147 is set lower than the pivot means 133 and in contact with the front side of the frame 130 . As a result, when the user applies a force to rotate the distal end portion of the armrest body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 which is the position where the frame 130 abuts. Abutment portion 148 at , receives the stress.

By the way, the armrest main body 132 can be rotated with respect to the frame 130 from the unfolded position that can be used by the user to the storage position in which the armrest body 132 can be erected substantially vertically. 35 and 36, the supporting means 133, the receiving portion 146, and the supporting means 133 as shown in Figs. And, it is established even if the positional relationship of the hit portion 148 is changed.

Therefore, a modified example of the positional relationship among the shaft support means 133, the receiving portion 146, and the contact portion 148 (hereinafter simply referred to as "positional relationship modified example") will be described below.

(Positional relationship modification 1)
As shown in FIG. 37, the positional relationship between the bearing means 133, the receiving portion 146, and the contact portion 148 is such that the bearing means 133 is set at a position penetrating the frame 130, and the receiving portion 146 and the contact portion 148 are arranged. may be set higher than the position of the pivot means 133, which are basically at the same position, and on the rear side of the frame 130. As shown in FIG.

In this case, the receiving rod 147 attached to the armrest body 132 is also positioned higher than the position of the pivot means 133 and on the rear side of the frame 130 when the armrest body 132 is in the deployed position. As a result, when the user applies a force to further rotate the tip of the armrest main body 132 downward, the receiving rod 147 abuts on the receiving portion 146 of the main body member 144, and the contact portion at basically the same position. 148 abuts frame 130 to absorb the stress.

When the main body member 144 is not provided, as shown in FIG. 38, the receiving rod 147 provided between the pair of mounting portions 138 of the armrest main body 132 is in contact with the pivotal support means 133 when the armrest main body 132 is in the unfolded position. , and is set to contact the rear side of the frame 130 . As a result, when the user applies a force to rotate the distal end portion of the armrest body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 which is the position where the frame 130 abuts. Abutment portion 148 at , receives the stress.

(Positional relationship modification 2)
As shown in FIG. 39, the positional relationship between the shaft support means 133, the receiving portion 146, and the contact portion 148 according to this modification is such that the shaft support means 133 is set at a position penetrating the frame 130, and the receiving portion 146 is , is set lower than the position of the shaft support means 133 and on the front side of the frame 130, and the position of the contact portion 148 is set lower than the position of the shaft support means 133 and higher than the position of the receiving portion 146. It may be set at a position that is high and overlaps with the frame 130 .

In this case, a projecting portion 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the body member 144 is, for example, as shown in the drawing, the receiving portion 146 is reversed in the figure by the receiving rod 147. Since it is pressed clockwise, the main body member 144 is formed with a protrusion contact portion 182 that contacts the protrusion 180 from the left side in the drawing so as to receive this pressing force. The shape of the protrusion contacting portion 182 is not limited to a linear shape as shown in the figure. corresponds to the protrusion contact portion 182 .

As a result, when the user applies a force to rotate the tip of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144 and rotates around the pivot means 133 in the figure. Although it tries to rotate counterclockwise, the contact portion 148 on the projection contact portion 182 comes into contact with the projection 180 formed on the frame 130 and receives the stress.

When the main body member 144 is not provided, as shown in FIG. 40, the receiving rod 147 provided between the pair of mounting portions 138 of the armrest main body 132 is positioned on the shaft supporting means 133 when the armrest main body 132 is in the deployed position. , and is set to contact the front side of the frame 130 . Further, a protrusion 180 is projected from a position on the frame 130 that is lower than the position of the pivoting means 133 and higher than the position of the receiving portion 146. , a protrusion contact portion 182 is formed to contact the protrusion 180 from the right side in the figure. A contact portion 148 is a position where the protrusion 180 and the protrusion contact portion 182 contact each other.

As a result, when the user applies a force to rotate the distal end portion of the armrest body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 of the frame 130 and also the projection 180 formed on the frame 130 . The stress is received by the abutting portion 148 on the armrest body 132 coming into contact with the protrusion abutting portion 182 formed on the armrest body 132 .

(Positional relationship modification 3)
As shown in FIG. 41, the positional relationship between the shaft support means 133, the receiving portion 146, and the contact portion 148 according to this modification is such that the shaft support means 133 is set at a position penetrating the frame 130, and the receiving portion 146 is , is set at a position lower than the position of the shaft support means 133 and overlapping the frame 130, and further, the position of the contact portion 148 is set at a position higher than the position of the shaft support means 133 and at a position overlapping the frame 130. You may

In this case, the main body member 144 is formed with a receiving rod abutting portion 184 that abuts on the receiving rod 147 from the right side in the figure so as to receive the stress from the receiving rod 147 as shown in the drawing. In addition, in order not to interfere with the receiving rod 147 when the armrest body 132 is flipped up and stored, the receiving rod contact portion 184 is positioned to the left in the drawing (that is, when the armrest body 132 is flipped up, the receiving rod 147 does not interfere with the receiving rod 147). A notch 186 is formed in the portion through which the light passes. Furthermore, if the receiving rod 147 is installed between the pair of mounting portions 138 of the armrest body 132, the receiving rod 147 interferes with the frame 130. The pair of mounting portions 138 protrude from the facing surfaces of the mounting portions 138 to the extent that they do not interfere with each other.

Further, a protrusion 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the body member 144 is configured such that the receiving portion 146 is moved counterclockwise in the figure by a receiving rod 147, as shown in the figure. Since it is pushed around, the body member 144 is formed with a projection abutting portion 182 that abuts against the projection 180 from the right side in the drawing so as to receive this pressing force. The shape of the protrusion contacting portion 182 is not limited to a linear shape as shown in the figure. corresponds to the protrusion contact portion 182 .

As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, The frame 130 receives a part of this stress via the shaft support means 133, and the contact portion of the protrusion contact portion 182 is turned counterclockwise in the drawing about the shaft support means 133. 148 abuts a projection 180 formed on frame 130 to take the remaining stress.

Also in the case of the positional relationship modification 3, when the body member 144 is not provided, as shown in FIG. A receiving rod abutting portion 184 that abuts on the receiving rod 147 from the right side is formed. In addition, if the receiving rod 147 is installed between the pair of mounting portions 138 of the armrest body 132, the receiving rod 147 interferes with the frame 130. The mounting portions 138 protrude from the opposing surfaces of the pair of mounting portions 138 to the extent that they do not interfere with the mounting portions 130 .

A projection 180 projects from a position corresponding to the contact portion 148 on the surface of the frame 130, and the mounting portion 138 has a projection contact portion 182 that contacts the projection 180 from the right side in the figure. formed.

As a result, when armrest main body 132 is in the unfolded position and the user applies a force to rotate the tip of armrest main body 132 further downward, receiving rod 147 is attached to receiving portion 146 of receiving rod abutting portion 184 . Along with the contact, the contact portion 148 on the protrusion contact portion 182 contacts the protrusion 180 formed on the frame 130 to receive the stress.

(Positional relationship modification 4)
As shown in FIG. 43, the positional relationship between the shaft support means 133, the receiving portion 146, and the contact portion 148 according to this modification is such that the shaft support means 133 is set at a position penetrating the frame 130, and the receiving portion 146 is The position is set higher than the position of the shaft support means 133 and on the rear side of the frame 130, and the position of the contact portion 148 is set higher than the position of the shaft support means 133 and further than the receiving portion 146. It may be set at a position that is low and overlaps with the frame 130 .

Further, a protrusion 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the body member 144 is configured such that the receiving portion 146 is moved counterclockwise in the figure by a receiving rod 147, as shown in the figure. Since it is pushed around, the body member 144 is formed with a projection abutting portion 182 that abuts against the projection 180 from the right side in the drawing so as to receive this pressing force. The shape of the protrusion contacting portion 182 is not limited to a linear shape as shown in the figure. corresponds to the protrusion contact portion 182 .

Further, the receiving rod 147 attached to the armrest main body 132 is also higher than the position of the pivot means 133 and is arranged on the rear side of the frame 130 . As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, Although it tries to rotate counterclockwise in the drawing about the pivotal support means 133, the contact portion 148 on the projection contact portion 182 comes into contact with the projection portion 180 formed on the frame 130, and the stress is received. .

Also in the case of the positional relationship modification 4, when the main body member 144 is not provided, as shown in FIG. It is set higher than the position of the support means 133 and on the back side of the frame 130, furthermore, the position of the contact part 148 is higher than the position of the pivotal support means 133 and lower than the receiving part 146, and further, It may be set at a position overlapping the frame 130 .

A projection 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the mounting portion 138 of the armrest main body 132 has a projection contact that contacts the projection 180 from the right side in the drawing. A contact portion 182 is formed.

Further, the receiving rod 147 attached to the armrest main body 132 is also higher than the position of the pivot means 133 and is arranged on the rear side of the frame 130 . As a result, when the armrest body 132 is in the deployed position and the user applies a force to further rotate the tip of the armrest body 132 downward, the receiving rod 147 comes into contact with the receiving portion 146 on the surface of the frame 130 . Along with contact, the contact portion 148 on the protrusion contact portion 182 contacts the protrusion 180 formed on the frame 130 to receive the stress.

In the modified examples of the positional relationship up to this point, the pivotal support means 133 was set at a position penetrating the frame 130. I will explain the case where As a means for arranging (indirectly fixing) the pivot means 133 on the front side or the back side of the frame 130 in this way, the pivot means 133 may be welded or adhered to the surface of the frame 130, or the frame 130 A means for projecting the bracket 190 from the bracket 190 and fixing the pivot means 133 to the bracket 190 is conceivable. In particular, by making the "third member" itself such as the bracket 190 detachable from the frame 130, no projections or the like remain undesirably on the frame 130 after the armrest 24 is removed. Therefore, the folding chair 10 without the armrests 24 can be used without any sense of incongruity even when the armrests 24 are entirely removed.

(Positional relationship modification 5)
As shown in FIG. 45, the positional relationship between the shaft support means 133, the receiving portion 146, and the contact portion 148 according to this modified example is adjusted to the position of the shaft support means 133 on the rear side of the frame 130 using, for example, a bracket (not shown). , the positions of the receiving portion 146 and the contact portion 148 may be set lower than the position of the pivot means 133, which are basically the same positions, and on the front side of the frame 130.

In this case, the receiving rod 147 attached to the armrest main body 132 is also located lower than the position of the pivot means 133 and on the front side of the frame 130 . As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, Abutment sites 148, which are essentially in the same position, abut the frame 130 to receive the stress.

Also in the case of the positional relationship modified example 5, when the main body member 144 is not provided, as shown in FIG. 146 and the contact portion 148 may be set lower than the position of the pivotal support means 133 and on the front side of the frame 130, which are at the same position.

In this case, the receiving bar 147 attached between the pair of attachment portions 138 of the armrest body 132 is also lower than the position of the pivot means 133 and on the front side of the frame 130 when the armrest body 132 is in the deployed position. are placed. As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 of the frame 130, and the frame is extended. A hit site 148 at the same location at 130 receives the stress.

(Positional relationship modification 6)
The positional relationship between the pivot means 133, the receiving portion 146, and the contact portion 148 according to this modified example is determined, for example, by using a bracket (not shown) to position the pivot means 133 on the rear side of the frame 130, as shown in FIG. , the position of the receiving portion 146 is set lower than the position of the shaft support means 133 and on the front side of the frame 130, and the position of the contact portion 148 is set lower than the position of the shaft support means 133. , and may be set at a position overlapping the frame 130 .

In this case, a projecting portion 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the receiving portion 146 of the body member 144 is pressed counterclockwise in the figure by the receiving rod 147. Therefore, as shown in the figure, the body member 144 is formed with a protrusion contact portion 182 that contacts the protrusion 180 from the left side in the figure so as to receive this pressing force. The shape of the protrusion contacting portion 182 is not limited to a linear shape as shown in the figure. corresponds to the protrusion contact portion 182 .

As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, When it is attempted to rotate counterclockwise in the drawing about the pivotal support means 133, the contact portion 148 of the projection contact portion 182 comes into contact with the projection portion 180 formed on the frame 130, and the stress is received. .

Also in the case of the positional relationship modification example 6, when the body member 144 is not provided, as shown in FIG. 146 is set lower than the position of the shaft support means 133 and on the front side of the frame 130, and furthermore, the position of the contact portion 148 is set lower than the position of the shaft support means 133 and in line with the frame 130. You may set it to the position which overlaps.

In this case, a projection 180 projects from a position corresponding to the contact portion 148 on the surface of the frame 130, and the armrest main body 132 has a projection contact portion 182 that contacts the projection 180 from the left side in the figure. is formed.

As a result, when the armrest body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 of the frame 130, The contact portion 148 of the protrusion contact portion 182 contacts the protrusion 180 formed on the frame 130 to receive the stress.

(Positional relationship modification 7)
The positional relationship between the pivot means 133, the receiving portion 146, and the contact portion 148 according to this modified example is determined, as shown in FIG. , the position of the receiving portion 146 is set lower than the position of the shaft support means 133 and on the front side of the frame 130, and the position of the contact portion 148 is set higher than the position of the shaft support means 133. , and may be set on the rear side of the frame 130 .

As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, It is attempted to rotate counterclockwise in the figure about the shaft support means 133 , but the frame 130 receives a part of this stress via the shaft support means 133 , and the contact portion 148 abuts against the frame 130 . Residual stress is taken up.

Also in the case of the positional relationship modification example 7, when the body member 144 is not provided, as shown in FIG. The position of 146 may be set lower than the position of the pivot means 133 and on the front side of the frame 130 , and the position of the contact portion 148 may be set at the same position as the receiving portion 146 .

As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the tip of the armrest main body 132 further downward, the receiving rod 147 contacts the receiving portion 146 on the surface of the frame 130 . At the same time, the contact portion 148 at the same position on the frame 130 receives the stress.

(Positional relationship modification 8)
The positional relationship between the pivot means 133, the receiving portion 146, and the contact portion 148 according to this modified example is determined, for example, by using a bracket (not shown) to position the pivot means 133 on the front side of the frame 130, as shown in FIG. , the position of the receiving part 146 and the position of the contacting part 148 may be set higher than the position of the pivotal support means 133 and on the rear side of the frame 130, which are at the same position.

In this case, the receiving rod 147 attached to the armrest main body 132 is also arranged higher than the position of the pivot means 133 and on the back side of the frame 130 when the armrest main body 132 is in the deployed position. As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to further rotate the distal end portion of the armrest main body 132 downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144. , the stress is received by the contact portion 148 at the same position.

Also in the case of the positional relationship modification 8, when the body member 144 is not provided, as shown in FIG. The position of 146 and the position of the contact portion 148 may be set higher than the position of the pivot means 133 and on the rear side of the frame 130, which are the same positions.

Further, the receiving rod 147 attached to the armrest body 132 is also arranged higher than the position of the pivot means 133 and on the rear side of the frame 130 when the armrest body 132 is in the unfolded position. As a result, when armrest main body 132 is in the unfolded position and the user applies a force to further rotate the tip of armrest main body 132 downward, receiving rod 147 comes into contact with receiving portion 146 on the surface of frame 130 . The stress is received by the contacting portion 148 which is in contact with and in the same position.

(Positional relationship modification 9)
As shown in FIG. 53, the positional relationship between the shaft support means 133, the receiving portion 146, and the contact portion 148 according to this modified example is adjusted to the position of the shaft support means 133 on the front side of the frame 130 using, for example, a bracket (not shown). , the position of the receiving part 146 is set higher than the position of the pivot means 133 and on the back side of the frame 130, and the position of the contact part 148 is set higher than the position of the pivot means 133 , and lower than the receiving portion 146 , and may be set at a position overlapping the frame 130 .

In this case, a projecting portion 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and the body member 144 is, for example, as shown in the drawing, the receiving portion 146 is reversed in the figure by the receiving rod 147. Since it is pressed clockwise, the body member 144 is formed with a protrusion contact portion 182 that contacts the protrusion 180 from the right side in the figure so as to receive this pressing force. In addition, the shape of the protrusion contact portion 182 is not limited to a linear shape as shown in the figure. corresponds to the protrusion contact portion 182 .

As a result, when the armrest main body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest main body 132 further downward, the receiving rod 147 comes into contact with the receiving portion 146 of the main body member 144, An attempt is made to rotate the body member 144 counterclockwise in the drawing around the pivotal support means 133, but the projection contact portion 182 comes into contact with the projection portion 180 formed on the frame 130, and the stress is received. .

Also in the case of the positional relationship modification example 9, when the body member 144 is not provided, as shown in FIG. 146 is set higher than the position of the pivot means 133 and on the rear side of the frame 130, and furthermore, the contact part 148 is positioned higher than the position of the pivot means 133 and the receiving part 146. It may also be set at a position lower than that and overlapping with the frame 130 .

A projection 180 is projected from a position corresponding to the contact portion 148 on the surface of the frame 130, and a pair of mounting portions 138 of the armrest main body 132 has a projection that contacts the projection 180 from the right side in the figure. A contact portion 182 is formed.

As a result, when the armrest body 132 is in the unfolded position and the user applies a force to rotate the distal end portion of the armrest body 132 further downward, the receiving rod 147 abuts on the receiving portion 146 of the frame 130, The protrusion contact portion 182 contacts the protrusion 180 formed on the frame 130 to receive the stress.

(Other Modifications of Armrest 24)
Throughout all variations regarding the construction of the armrest 24 described so far, the pivot means 133 may be set to a length that passes through the frame 130, or alternatively, the pivot means 133 may be set short. Then, the axial support means 133 may be in a state in which they are not connected to each other at the portion corresponding to the central portion of the cross section of the frame 130 .

Similarly, the receiving rod 147 may be set to a length equal to or greater than the diameter of the frame 130, except for the case where the receiving portion 146 overlaps the frame 130, or alternatively, the length may be set shorter. In addition, the receiving rods 147 may not be connected to each other at the portion corresponding to the central portion of the cross section of the frame 130 .

Further, the number of shaft support means insertion holes 142 formed in the frame 130 is not limited to one, and a plurality of holes may be formed in the vertical direction of the frame 130 . By forming a plurality of shaft support means insertion holes 142 in the vertical direction of the frame 130 in this way, it is possible to select which shaft support means insertion hole 142 the shaft support means 133 is to be inserted into, and to move the armrest 24 in the height direction. position can be adjusted.

Also, in the above-described embodiment, the armrest body 132 was attached to the frame 130 extending above the seat portion 16 of the front leg 12. A frame 130 may be extended and an armrest body 132 may be attached to the frame 130 from the rear leg 14 .

It should be considered that the embodiments disclosed this time are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the scope of the claims rather than the above description, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.

DESCRIPTION OF SYMBOLS 10... Folding chair (chair), 12... Front leg, 14... Rear leg, 16... Seat part, 18... Link connection bar, 20... Link bar, 21... Reinforcement bar, 22... Backrest, 24... Armrest, 26... Backrest support Portion 28 Horizontal portion 30 Front leg 32 Leg rubber (of front leg 12) 34 Backrest mounting portion 36 Outer pipe (of front leg 12) 38 Height adjustment hole (of front leg 12) 40... inner pipe (of front leg 12), 42... height adjustment pin (of front leg 12), 44... seat support part, 46... rear leg part, 48... leg rubber (of rear leg 14), 50... (rear) Outer pipe of leg 14 52 Height adjustment hole (rear leg 14) 54 Inner pipe (rear leg 14) 56 Height adjustment pin (rear leg 14) 58 Front leg side pivot Hole 60... Rear leg side support hole 62... Support pin 63... Front leg support portion 64... Seat support pin 65... Front leg support member 66... Seat support hole 68... Seat shaft Support pin hole 70 Stopper 72 Engagement claw 74 Support projection 76 Fitting groove 78 Bracket 79 Pivot pin 80 Bracket plate 81 Pivot pin insertion hole 82 end portion 84 central portion 86 link bar main body member 88 link connection bar clamping member 90 recess 92 recess 94 screw 96 bearing pin insertion hole 98 armrest Mounting portion 100 Front leg-side pivot hole 102 Seat support bar 104 Protruding portion 106 Protruding portion 110 Rotating biasing member 112 Coil portion 114 First arm portion 116 Second arm portion 120 --- Fixing hole 122 --- Arm locking pin 130 --- Frame (of front leg 12) 132 --- Armrest body 133 --- Pivot means 134 --- Rotation restricting means 138 --- Mounting portion 140 --- Support means insertion hole 141 Second support means insertion hole 142 Support means insertion hole 144 Main body member 145 Main body member piece 146 Receiving portion 147 Receiving rod 148 Hitting portion DESCRIPTION OF SYMBOLS 150... Cover 160... Disc-shaped member 162... Shaft member 164... Knob 166... Disc-shaped member 168... Shaft member 172... Shaft pressing member 174... Shaft pressing member biasing member 176... Shaft member fitting Hole 180 Projection portion 182 Projection contact portion 184 Receiving rod contact portion 186 Notch 190 Bracket

Claims (1)

A pair of front legs, a pair of rear legs rotatably supported with respect to the front legs, and a seat rotatable with respect to the front legs and the rear legs between a horizontal state and a flipped state. A folding chair comprising:
The rear legs are arranged inside the front legs,
The seat portion is rotatably supported by the rear leg as a pivot leg,
The position at which the rear leg is pivotally supported with respect to the front leg is forward of the position at which the seat portion is pivotally supported with respect to the pivot leg,
A support shaft provided on the support shaft leg has an extension portion extending outward from the rear leg, and the extension portion supports the front leg when the folding chair is unfolded. .

Images