WO2009128165A1

WO2009128165A1 - Boot holder

Info

Publication number: WO2009128165A1
Application number: PCT/JP2008/057584
Authority: WO
Inventors: 功岡本
Original assignee: Okamoto Isao
Priority date: 2008-04-18
Filing date: 2008-04-18
Publication date: 2009-10-22
Also published as: JPWO2009128165A1

Abstract

A boot holder that joins a pair of boots together and holds them in a fashion preventing bending of the tubular trunk parts of the boots. The boot holder comprises opening/closing means (11) and operating means (12). The opening/closing means (11) is obtained by folding one flexible rod so as to provide a circular arc header part (14) with its downside open and a pair of leg parts (15,15) extending downward in a gradually departing direction from the two ends (14a,14a) of the header part facing open area (13). Clamp blocks (16) are fastened to the inferior ends (15a) of the leg parts. The operating means (12) is provided with a holding hole (18) through which the leg parts (15,15) are inserted in the state of being held so that the spacing therebetween is a given distance. In the state of having the leg parts inserted through the holding hole, the operating means (12) is slidable between a superior waiting position (P1) close to the header part (14) and an inferior working position (P2,P3) distant from the header part (14).

Description

Boot holder

The present invention relates to a boot holder that couples a pair of boots and holds a boot so that a cylindrical body portion of the boot is not bent.

Conventionally, a boot holder as shown in FIGS. 9 and 10 has been proposed. As shown in FIG. 9A, the boot holder 1 is made of a material having moderate elasticity, and includes a pair of

legs

3 and 3 extending downward from the arcuate header 2. At this time, the header portion 2 is elastically biased in a direction in which the

leg portions

3 and 3 are in contact with each other (in the direction of the arrow F in the drawing), and the whole is configured like a hairpin. Note that guide

portions

4 and 4 bent outwardly are formed at the ends of the

leg portions

3 and 3.

As is well known, the boot B extends the cylindrical body B2 upward from the shoe part B1, and includes an opening edge B3 at the upper end of the cylindrical body B2.

Therefore, as shown in FIG. 9B, the pair of

guides

4 and 4 of the boot holder 1 face the opening edges B3 and B3 with respect to the pair of boots B and B arranged side by side. When the

portions

3 and 3 are inserted into the boots B and B, the opening edges B3 and B3 are sandwiched by the elastic force of the

leg portions

3 and 3. Since the

elongated leg portions

3 and 3 are inserted into the cylindrical body portions B2 and B2, the cylindrical body portions B2 and B2 are held so as not to be bent.

However, in the normal form shown in FIG. 10 (A), such a hairpin-shaped boot holder 1 applies the predetermined elastic force F1 to the entire surfaces of the

legs

3 and 3 by the elasticity of the header 2. In the state where the boot holder 1 is inserted into the boots B and B and the cylindrical body portions B2 and B2 are sandwiched between the

leg portions

3 and 3, as shown in FIG. 3 are separated from each other so as to spread toward the tip, and only the opening edges B3 and B3 are locally sandwiched by only a part of the

legs

3 and 3 having the elastic force F2. For this reason, there is a problem that the boots B, B are slipped off when the header 2 is gripped and the boot holder 1 is lifted.

By the way, in order to solve the above problem, as shown in FIG. 10C, a boot holder 1a provided with fastening means 5 for fastening the

leg portions

3 and 3 has been proposed. The fastening means 5 is slidable up and down in a state where the

leg portions

3 and 3 are bound. Therefore, the

leg portions

3 and 3 are inserted into the boots B and B with the fastening means 5 moved to the upper position indicated by the chain line in the figure, and the

leg portions

3 and 3 open the opening edge B3 of the cylindrical body portions B2 and B2. After clamping B3, the fastening means 5 is slid downward to firmly clamp the opening edges B3 and B3 with the

legs

3 and 3 having increased elasticity F3.

Japanese Utility Model Publication No. 56-22847 Utility Model Registration No. 26005096

The conventional boot holder 1 has a hairpin shape, and always repels the

legs

3 and 3 so as to contact each other. For this reason, there are the following serious problems.
(1) Since the

legs

3 and 3 of the boot holder 1 are repelled in a direction in which they abut each other and the

legs

3 and 3 are always closed, it is difficult to insert them into the boots B and B. It is.
(2) When the

leg portions

3 and 3 are inserted into or pulled out from the boots B and B, the opening edge B3 of the cylindrical body portion B2 is rubbed against the leg portion 3, so that the opening edge B3 may be damaged. . In particular, when the insertion and withdrawal of the boot holder 1 are repeated, the opening edge B3 may be worn out.

And in the case of the boot holder 1a which clamps the

leg parts

3 and 3 strongly by the fastening means 5 as shown in FIG. 10C, the

leg parts

3 and 3 are the opening edges of the cylindrical body parts B2 and B2. Since it bites into B3 and B3, there is a problem that a deformed wrinkle is attached to the opening edge B3.

The present invention is based on the technical idea that the

conventional boot holder

1, 1a as described above applies the elastic force F so that the

legs

3, 3 are always in contact with each other. On the other hand, the pair of legs are always repelled in the direction of separating them, and the operating means is operated to move the legs in the direction of approaching the resilient force. In this configuration, the pair of boots is sandwiched from the inside.

According to the boot holder of the present invention, since the pair of leg portions are always open, the pair of leg portions can be inserted into each boot very easily and easily. Then, the leg is closed against the elastic force by the operating means. A clamping block is provided at each lower end of the leg portion, and when the leg portion is closed, the pair of clamping blocks strongly clamp the shoe portions of the pair of boots from the inside. Since the opening edge of the cylindrical body part of the boot is not strongly clamped, there is no risk of damage.

According to the present invention, a boot holder having the following configuration is provided (claim 1). That is, the boot holder is composed of an opening / closing means and an operating means in a boot holder that holds both boots from the inside with the cylindrical body portions of a pair of boots adjacent to each other. By bending the flexible rod, an arcuate header portion having an open lower side and a pair of leg portions extending downwardly away from both ends of the header portion facing the open portion are formed, and the legs A holding block is fixed to each lower end of the part, and the operating means forms a holding hole to be inserted in a state where the distance between the pair of leg parts is held to be a predetermined distance, and the leg is inserted into the holding hole. With the portion inserted, the holding hole is slidable between an upper standby position near the header portion and a lower operation position away from the header portion, and the holding holes are paired when the operating means is slid downward. Legs in close proximity to each other When the operating means is slid upward, the interlocking means is configured to open the pair of leg portions away from each other, and the pair of clamping blocks are mutually connected with the operating means positioned at the operating position. And a leg projecting means for accumulating an elastic force in a direction in which the pair of leg portions are separated from each other.

Moreover, according to this invention, the boot holder provided with the header bulleting means is provided (Claim 2). That is, the boot holder constitutes a header resilient means that accumulates a resilient force in a direction in which the header portion expands the opening portion in a state where the operation means is located at the standby position.

According to the present invention, the leg bullet emitting means is configured as follows (Claim 3). That is, the leg projecting means has a distance W2 between the pair of legs held in the holding hole of the operating means and a distance W3 between the lower ends of the legs when the holding blocks are in contact with each other. It is formed by setting W3.

According to the present invention, the header impact means is configured as follows. That is, the header elastic means is formed by setting W1> W2 so that the separation distance W1 between both ends facing the opening of the header section and the separation distance W2 between the pair of legs held in the holding holes of the operation means. Has been.

The boot holder of the present invention is preferably configured so that a stopper made of an elastic ring is slidably inserted in each leg portion, and the downward sliding position of the operating means is regulated by the stopper.

The boot holder according to the present invention has a spacer made of an elastic ring slidably inserted in each leg, and the spacer is inserted into the cylindrical body of the boot while the spacer is opened to the opening edge of the cylindrical body. It is preferable that it is configured so as to face.

These are perspective views which show embodiment of the boot holder of this invention. FIG. 3 is a perspective view showing the boot holder of the present invention in an exploded state. These are sectional drawings which show the effect | action of the boot holder of this invention. These are sectional drawings which show the effect | action of the header elastic means of the boot holder of this invention. These are sectional drawings which show the effect | action of the leg elastic means of the boot holder of this invention. FIG. 5 is a cross-sectional view showing a state in which the operating means is positioned at a standby position for an example in which the boot holder of the present invention is used for a long boot. FIG. 5 is a cross-sectional view showing a state in which the operating means is moved to the operating position for an example in which the boot holder is used for a long boot. These are sectional drawings which show the state which located the operation means in the operation position regarding the example which uses the boot holder of this invention for short boots. FIG. 4A shows a conventional technique, in which (A) is a perspective view showing a hairpin-shaped boot holder, and (B) is a perspective view showing a state in which the boot is held by the boot holder. Shows a conventional technique, (A) is a front view showing a hairpin shaped boot holder, (B) is a sectional view showing the action of the boot holder, (C) is a fastening member on the hairpin shaped boot holder. It is sectional drawing which shows the effect | action of the provided prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Boot holder 11 Opening / closing means 12 Operating means 13 Opening part 14 Header part 14a Bending part 15 Leg part 15a Lower end part 15b Upper end part 16 Holding block 16a Holding surface 18 Holding hole 19a Stopper 19b, 19c Spacer 20 Header elastic means 21 Leg Bullet means

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1 to 3, the boot holder 10 includes an opening / closing means 11 and an operation means 12.

The opening / closing means 11 is formed by bending a single flexible rod, thereby forming an arcuate header portion 14 having an open portion 13 on the lower side, and a pair of portions extending gradually away from the header portion 14 downward.

Leg portions

15 and 15 are formed, and a clamping block 16 is fixed to each lower end portion 15a of both leg portions. The header portion 14 is bent outward at both ends facing the opening portion 13 to form

bent portions

14a and 14a separated from each other by a separation distance W1, and the leg portions 15 are formed from the bent portions 14a and 14a. 15 extend linearly (see FIG. 3).

As shown in FIG. 2, the opening / closing means 11 has a pair of

leg portions

15 and 15 having an opening angle θ1 of 15 in a state where the header portion 14 and both

leg portions

15 and 15 are bent by a single rod. As shown in FIG. 1, the pair of leg portions 15 are opened at an angle selected from the range of 25 ° to 25 ° (preferably about 20 °), and the operating means 12 is attached to both the

leg portions

15 and 15. , 15 is widened so as to be an angle selected from the range of 4 ° to 10 ° (preferably about 6 °). Therefore, when the operating means 12 is attached, it is deformed so as to narrow the expansion angle such that θ2 <θ1, and the elastic forces R and R in the direction of expanding both the

leg portions

15 and 15 are accumulated. Such elastic forces R, R can be achieved by forming the opening / closing means 11 with an elastic rod or a flexible rod. For this reason, the rod may be formed of an elastic material such as steel, but in the case of the illustrated embodiment, for example, a metal wire such as an aluminum wire, a resin wire reinforced with carbon fiber or glass fiber, etc. Such a lightweight material is formed of a flexible material that accumulates an elastic force in a restoring direction from a state of being bent and deformed.

The sandwiching block 16 is formed of a block having a width T thicker than the outer diameter D of the rod constituting the opening / closing means 11. The mounting hole 17 is formed on the upper surface, and the lower end portion 15 a of the leg portion 15 is formed in the mounting hole 17. Insert and fix. At this time, the mounting hole 17 is provided at a position spaced apart from the opposing clamping surfaces 16a and 16a of the pair of clamping blocks 16 and 16 by a distance S. Therefore, when the clamping surfaces 16a and 16a of the clamping blocks 16 and 16 are brought into contact with each other, the

lower end portions

15a and 15a of the

leg portions

15 and 15 are formed so as to be separated from each other by a separation distance W3 (see FIG. 3). See W3). The sandwiching block 16 has an excellent design effect by forming a shoe shape as shown in the figure. At this time, if a pseudo shoelace (not shown) is attached, the design effect is further improved. The sandwiching block 16 may be made of wood by woodworking or made of synthetic resin.

The operating means 12 is composed of a thick plate member straddling a pair of

leg portions

15, 15, and has a holding hole 18 through which the

leg portions

15, 15 are inserted through the plate member. Yes. The operating means 12 is slidable in the vertical direction in a state where the

leg portions

15 and 15 are inserted into the holding hole 18, and the holding hole 18 is separated from the pair of

leg portions

15 and 15 by a separation distance W2. Hold from both sides (see W1 shown in FIG. 3). In order to enable such a separation distance W2, the holding hole 18 may be constituted by a long hole 18a such as the operation member 12a shown in FIG. 2, or a pair of holes 18b such as the operation member 12b, You may comprise by 18b. The operation means 12 may be made of wood by woodworking or may be made of synthetic resin.

The operating means 12 is slidable between an upper standby position P1 near the header portion 14 and lower operating positions P2 and P3 away from the header portion 14. When the operating means 12 is slid downward from the standby position P1 toward the operating positions P2 and P3, the holding hole 18 closes the

legs

15 and 15 in the mutually close direction, and the operating means 12 is moved from the operating positions P2 and P3. When sliding upward toward the standby position P1, the holding hole 18 constitutes interlocking means for opening the

legs

15 and 15 in the separating direction.

In the illustrated embodiment, a plurality of elastic rings 19 are slidably fitted on the pair of

leg portions

15, 15. The elastic ring arranged at the uppermost position constitutes a stopper 19a, and the elastic ring arranged at the lower side constitutes

spacers

19b and 19c.

The boot holder 10 has a pair of

leg portions

15 and 15 of the opening / closing means 11 inserted into the holding holes 18 of the operation means 12, and an elastic ring 19 is extrapolated to each leg portion 15. It is assembled by fixing and used as a product as shown in FIG.

The distance W1 between the

bent portions

14a and 14a of the header portion 14 (the width of the opening portion 13) and the distance W2 between the pair of

leg portions

15 and 15 held in the holding hole 18 of the operation means 12 are as follows. , W1> W2. Accordingly, as shown in FIG. 3, when the operating means 12 is positioned at the uppermost standby position P1 in the vicinity of the

bent portions

14a, 14a of the header portion 14, the header portion 14 is changed from a chain line state to a solid line. The elastic force is accumulated in the compressed state, and the distance between the

bent portions

14a and 14a is changed from W1 to W2. Thereby, the header part 14 comprises the header elastic means 20 which accumulates an elastic force in the direction which expands the open part 13. As shown in FIG.

As shown in FIG. 4, when the operating means 12 is moved from the standby position P1 to the operating positions P2 and P3, the pair of

leg portions

15 and 15 moves the

tip portions

15a and 15a from the posture of opening downward from the header portion 14. It is swung in the closing direction, and the clamping blocks 16 and 16 abut against each other. If the leg 15 swings in a state where the upper end fulcrum is fixed, the axis of the leg 15 with the tip open is inclined with respect to the axis of the holding hole 18 until the

legs

15, 15 become parallel. Therefore, the sliding of the operating means 12 is not smooth and requires a strong force for sliding. On the other hand, according to the configuration in which the header impacting means 20 is provided, when the operating means 12 is moved downward from the standby position P1, the opening portion 13 opens as shown by the solid line from the state shown by the chain line in the figure. Then, the swing fulcrum (folded portion 14a) at the upper end of the leg portion 15 is moved outward. Accordingly, the inclination angle of the leg portion 15 with respect to the axis of the holding hole 18 becomes small, and the sliding of the operating means 12 becomes smooth. In addition, by moving the swing fulcrum (folded portion 14a) of the leg portion 15 outward, the pair of

leg portions

15 and 15 held in the holding hole 18 are controlled to be in a parallel posture. This contributes to bring the clamping surfaces 16a, 16a of the clamping blocks 16, 16 into contact in a parallel state.

In a state where the operating means 12 is located at the standby position P1, the pair of

leg portions

15 and 15 extend gradually away downward, and the

lower end portions

15a and 15a are separated from each other as shown by a solid line in FIG. The pair of sandwiching

blocks

16 and 16 are separated as shown by a separation distance W5. When the operating means 12 is moved downward from the standby position P1, the pair of

leg portions

15 and 15 are gradually closed. When the operating means 12 is positioned at the operating position P2 indicated by the chain line in FIG. And the clamping surfaces 16a and 16a of the clamping blocks 16 and 16 are brought into contact with each other. In this state, the

legs

15 and 15 are deformed so that the distance between the lower ends 15a and 15a is reduced from W4 to W3. Therefore, when the operating means 12 is positioned at the operating position P2, the pair of

leg portions

15 and 15 constitutes a leg bullet means 21 that accumulates a resilient force in a direction away from each other. In the illustrated embodiment, the distance W3 between the narrowed lower ends 15a and 15a and the distance W2 between the

leg portions

15 and 15 held in the holding hole 18 of the operation means 12 are set so that W2 ≦ W3. Is formed.

As shown in FIG. 5, when the operating means 12 is moved to the operating positions P2 and P3, when the boots B and B are interposed between the sandwiching blocks 16 and 16, the lower ends 15a of the

legs

15 and 15 are provided. 15a is equal to W3 + 2t (2t is the thickness of the boots B and B). Therefore, the separation distance W2 between the

leg portions

15 and 15 held in the holding hole 18 of the operating means 12 is inevitably W2. <W3 + 2t. Accordingly, the

leg portions

15 and 15 are pressed so as to approach each other up to W2 against the leg elastic means 21, and the pressing force is transmitted to the sandwiching blocks 16 and 16, so that the reaction force of the leg elastic means 21 is As a result, the clamping force of the clamping blocks 16 and 16 is increased.

The boot holder 10 opens the pair of

leg portions

15 and 15 extending from the header portion 14 gradually downward while the operating means 12 is moved to the standby position P1, and separates the holding blocks 16 and 16 from each other. ing. Therefore, as shown in FIG. 6, the

leg portions

15 and 15 can be easily and easily inserted into the pair of boots B and B arranged side by side with the sandwiching blocks 16 and 16. Therefore, as shown in FIG. 7, when the operating means 12 is moved from the standby position P1 to the operating position P2, the

leg portions

15 and 15 are gradually closed, and the shoe blocks B1 and B1 of the boots B and B are moved by the sandwiching blocks 16 and 16. Clamp from inside. Since the operation means 12 is separated from the standby position P1, the header impacting means 20 causes the

upper end portions

15b and 15b of the

leg portions

15 and 15 to impact in the separating direction R1 while the opening portion 13 of the header portion 14 is slightly opened. Has been. The

lower end portions

15a and 15a of the

leg portions

15 and 15 are set as W2 ≦ W3 as described above. At this time, the shoe portions B1 and B1 (thickness 2t) are interposed between the sandwiching blocks 16 and 16. Therefore, it is inevitably deformed so that W2 <W3 + 2t, and the

lower end portions

15a and 15a are ejected in the separation direction R2 by the leg projecting means 21. The clamping blocks 16 and 16 are brought close to each other against the elastic forces in the separation directions R1 and R2, and the shoe parts B1 and B1 of the boots B and B are strongly clamped from the inside. Since the elastic force in the separating directions R1 and R2 acts on the

leg portions

15 and 15 above and below the operation means 12, even if an impact or the like is applied to the boot holder 10, the operation means 12 does not move easily, Place at a predetermined operating position P2.

As shown in FIG. 7, if the stopper 19a is installed at a predetermined position according to the height of the cylindrical body B2 of the boot B, when the operating means 12 is moved downward from the standby position P1, a predetermined value is obtained. It can be stopped at the operating position P2. Further, if the

spacers

19b and 19c are installed at predetermined positions according to the height of the cylindrical body B2, the cylindrical body B2 can be held so as not to sway.

Thus, the boot holder 10 connects the shoe parts B1 and B1 by being clamped by the clamping blocks 16 and 16, and the

leg parts

15 and 15 hold the cylindrical trunk parts B2 and B2 so that they cannot be bent. Accordingly, the boot holder 10 can hold the boots B and B in a state of being placed on the floor, and the boots B and B can be displayed and displayed at a store or the like by suspending the header portion 14 with a hook or the like.

When the boot holder 10 is removed from the boots B, B, the operating means 12 may be moved from the operating position P2 to the standby position P1 contrary to the above. Accordingly, the pair of

leg portions

15 and 15 are automatically opened in the separating directions R1 and R2 and the sandwiching blocks 16 and 16 are separated from each other, so that the boot holder 10 can be easily removed from the boots B and B.

6 and 7 show a long boot having a tall cylindrical body B2, but the boot holder 10 is a short boot having a short cylindrical body B2 as shown in FIG. It can also be used in the same way. In this case, the boot holder 10 inserts the

leg portions

15 and 15 together with the holding blocks 16 and 16 into the boots B and B, and then moves the operating means 12 from the standby position P1 to the opening edge B3 of the short cylindrical trunk B2. The actuator is moved to a nearby operating position P3. Accordingly, the stopper 19a is installed at a position where the operation means 12 is stopped at the operating position P3.

As in the case of the long boots, when the operating means 12 is moved from the standby position P1 to the operating position P3, the

legs

15 and 15 are gradually closed, and the shoe blocks B1 and B1 of the boots B and B are moved inside by the sandwiching blocks 16 and 16. Hold from. Since the operation means 12 is separated from the standby position P1, the header impacting means 20 opens the opening portion 13 of the header portion 14, and the

upper end portions

15b and 15b of the

leg portions

15 and 15 are impacted in the separation direction R1. Since the operation position P3 is low, the

upper end portions

15b and 15b are deformed so as to have an arcuate shape on the outside by receiving the elastic force of the header elastic means 20. Since the

lower end portions

15a and 15a of the

leg portions

15 and 15 satisfy W2 ≦ W3 as described above, they are repelled in the separation direction R2. Also in this case, since the shoe portions B1 and B1 are interposed between the sandwiching blocks 16 and 16, inevitably W2 <W3 + 2t (2t is the thickness of the boots B and B). The

parts

15a and 15a are deformed so as to form an arcuate shape inside. The clamping blocks 16 and 16 are brought close to each other against the elastic forces in the separation directions R1 and R2, and the shoe parts B1 and B1 of the boots B and B are strongly clamped from the inside.

According to the boot holder 10 of the present invention, since the pair of

leg portions

15 and 15 are normally open, the pair of

leg portions

15 and 15 can be inserted into the boots B and B very easily and easily. . Then, by moving the operating means 12 from the standby position P1 to the operating position P2 or P3, the

leg portions

15 and 15 are closed against the elastic force of the leg elastic means 21, and the pair of sandwiching

blocks

16 and 16 are closed. Therefore, even if the boot holder 10 is lifted, the boot B does not slip off. Therefore, it is possible to display the boots B and B at a store or the like by suspending the header portion 14 with a hook or the like.

Further, when removing the boot holder 10, the

leg portions

15 and 15 are automatically opened by the elastic force of the leg elastic means 21, just by moving the operating means 12 from the operating position P2 or P3 to the standby position P1. Since the holding blocks 16 and 16 are separated from each other, the boot holder 10 can be extracted from the boots B and B very easily and easily.

In particular, according to the present invention, the boot holder 10 rubs the cylindrical body portions B2 and B2 when the boot holder 10 is inserted into or removed from the boots B and B. Therefore, there is an advantage that there is no fear of damaging the boot B.

By the way, the boot holder 10 of the present invention has a leg portion in a state where the separation distance W2 between the pair of

leg portions

15 and 15 held in the holding hole 18 of the operation means 12 and the sandwiching blocks 16 and 16 are in contact with each other. The leg projecting means 21 is configured by setting the distance W3 between the lower ends 15a and 15a to be W2 ≦ W3. Therefore, when the operating means 12 is moved to the operating position P2 or P3, the boots B and B can be strongly held by the holding blocks 16 and 16. That is, at this time, since the boots B and B are interposed between the sandwiching blocks 16 and 16, inevitably W2 <W3 + 2t (where 2t is the thickness of the boots B and B). Are pressed so as to be close to each other up to W2, thereby transmitting the pressing force to the clamping blocks 16 and 16.

Furthermore, the boot holder 10 according to the present invention has a separation distance W1 between both ends 14a and 14a facing the opening portion 13 of the header portion 14 and a separation distance between the pair of

leg portions

15 and 15 held in the holding hole 18 of the operation means 12. By setting W2 to W1> W2, the header bullet ejecting means 20 is configured. Therefore, both ends 14a and 14a of the header portion 14 accumulate the elastic force in the separating direction with the operating means 12 positioned at the standby position P1. Therefore, when the operating means 12 is moved to the operating position P2 or P3, the both ends 14a and 14a move in the separating direction. Accordingly, when the posture of the pair of

leg portions

15 and 15 is changed from the posture in which the lower ends are opened to the direction in which the lower ends are closed by the downward sliding of the operating means 12, the posture is simultaneously changed in the direction in which the upper ends of the

leg portions

15 and 15 are opened. Since the change is made, the sliding of the operating means 12 is smooth, and the clamping surfaces 16a and 16a of the clamping blocks 16 and 16 can be controlled to be in a parallel posture.

In the present invention, a stopper 19a made of an elastic ring is preferably slidably fitted on each leg 15 of the opening / closing means 11. If the stopper 19a is installed at the operation position P2 or P3 corresponding to the height of the cylindrical body B2 of the boot B, the user moves the operating means 12 downward from the standby position P1 in order to close the

legs

15, 15. When sliding, the operating means 12 can be stopped at the operating position P2 or P3 by the stopper 19a.

In the present invention, preferably,

spacers

19b and 19c made of an elastic ring are slidably fitted on each leg portion 15 of the opening / closing means 11. If the

spacers

19b and 19c are installed at predetermined positions corresponding to the height of the cylindrical body B2 of the boot B, the

legs

15 and 15 of the boot holder 10 are inserted into the cylindrical body B2 and B2. The

spacers

19b and 19c face the inner side of the cylindrical body B2, and can hold the cylindrical body B2 so as not to shake sideways.

Claims

In a boule holder that holds both boots from the inside with the cylindrical body portions of a pair of boots adjacent to each other, it comprises an opening / closing means (11) and an operating means (12),
The opening / closing means (11) is formed by bending one flexible rod so that the arcuate header portion (14) opened at the lower side and both ends of the header portion facing the opening portion (13) (14a) forming a pair of legs (15) (15) extending in a direction gradually separating downward from (14a), and fixing the clamping block (16) to each lower end (15a) of the legs,
The operating means (12) forms a holding hole (18) that is inserted in a state in which the distance between the pair of leg portions (15) and (15) is held at a predetermined distance, and the leg portion is formed in the holding hole. Is inserted between the upper standby position (P1) near the header section (14) and the lower operation position (P2) (P3) away from the header section (14).
The holding hole (18) closes the pair of legs (15) and (15) close to each other when the operating means (12) is slid downward, and the operating means (12) is slid upward. When the pair of leg portions (15) and (15) are configured to be interlocking means for opening them apart from each other,
With the operating means (12) positioned at the operating position (P2) (P3), the pair of clamping blocks (16), (16) are brought into contact with each other, and the pair of legs (15), (15) A boot holder characterized by comprising a leg bullet means (21) for accumulating a resilient force in a direction away from each other.
With the operating means (12) positioned at the standby position (P1), the header resilient means (20) for accumulating the resilient force in the direction in which the header part (14) opens the opening part (13) is provided. The boot holder according to claim 1, wherein the boot holder is constructed.
The leg projecting means (21) includes a separation distance W2 between the pair of leg portions (15) (15) held in the holding hole (18) of the operation means (12) and a clamping block (16) (16). The boot holder according to claim 1 or 2, wherein a distance W3 between the lower ends (15a) and (15a) of the leg portions in contact with each other is set such that W2≤W3.
The header impacting means (20) is held by a separation distance W1 between both ends (14a) and (14a) facing the opening part (13) of the header part (14) and a holding hole (18) of the operating means (12). The boot holder according to claim 2 or 3, wherein a distance W2 between the pair of legs (15) and (15) is set such that W1> W2.
A stopper (19a) made of an elastic ring is slidably inserted in each leg portion (15), and the downward sliding position of the operating means (12) is regulated by the stopper (19a). The boot holder according to claim 1, 2, 3 or 4.
Spacer (19b) (19c) consisting of an elastic ring is slidably inserted into each leg (15), and the spacer (19b) is cylindrical with each leg inserted into the cylindrical body of the boot. 6. The boot holder according to claim 1, wherein the boot holder is configured to face the opening edge (B3) of the trunk portion.