JP3208785U - Shoehorn stand - Google Patents

Abstract

[PROBLEMS] To provide a compact shoehorn stand that can be used easily without taking a posture that gives stress to the body such as dropping or bending. SOLUTION: A shoehorn storage space S1 is formed in an upper part of a cylindrical body 1 and a bottom raising space S2 is formed in a lower part thereof. The cylindrical body 1 has a diameter R of 40 to 70 mm and a length A of 300 to 700 mm. 1 is fixed upright in the center of a circular pedestal 2 having a diameter 15 to 40 mm larger than that of the cylindrical body 1, and the bottom surface 3 a of the storage space S 1 is formed between the bottom surface 3 a and the opposed inner wall surface and the upper end of the cylindrical body 1. A rectangular diagonal angle α formed with the opening surface is formed at a depth C that is an angle smaller than 30 degrees with respect to the inner wall surface of the cylindrical body 1. [Selection] Figure 1

Description

  The present invention relates to a shoehorn stand for standing a long shoehorn.

So far, the vase-type shoehorn stand of the following Patent Document 1 and the vertical tube-type shoehorn stand of the following Patent Document 2 have been proposed, but these have the advantage that they can be easily moved and used. The place where the shoehorn is placed is low, and in use, the waist must bend and bend. For this reason, people who have problems with their legs and feet such as those who have problems with the legs, people with back pain, and elderly people with weak muscles of the legs and legs are in pain.
In addition, there is a problem that the shoehorn cannot be stood unless it is inserted carefully in order to return it to the stand.
On the other hand, long shoe horns are used without being bent, only when they are hung in a reachable position while standing on the wall of the entrance, etc., or hung on an umbrella stand with a high insertion frame. However, there is a problem that it is difficult to use because the place of the wall is limited because the scenery of the wall surface is damaged, and it is necessary to go to that place and use it.

JP-A-9-313330 JP 2002-345622 A

  In view of the above circumstances, an object of the present invention is to provide a compact shoehorn stand in which a shoehorn can be easily inserted and removed without taking a posture that gives stress to the body such as bending or bending the waist.

  In order to achieve the above object, the shoehorn stand of the present invention forms a shoehorn storage space in the upper part of the cylindrical body and a bottom raising space in the lower part, and the diameter of the cylindrical body is 40 to 70 mm and the length is 300 to 700 mm. The cylindrical body is fixed upright in the center of a circular pedestal having a diameter 15 to 40 mm larger than the cylindrical body, and the bottom surface of the storage space is formed by the bottom surface, the opposed inner wall surface of the cylindrical body, and the upper end opening surface. It is characterized in that the formed diagonal angle of the rectangle is formed to a depth that is smaller than 30 degrees with respect to the inner wall surface of the cylindrical body.

  According to a second aspect of the present invention, in the above device, the bottom surface of the shoehorn storage space is formed on the bottom surface body, and the depth from the upper end opening of the cylindrical body to the bottom surface of the shoehorn storage space is adjusted on the bottom surface body. The shoehorn stand according to claim 1, further comprising a depth adjusting means for enabling the shoehorn stand.

  According to a third aspect of the present invention, in the above-mentioned invention, the depth adjusting means is provided in a bottom-up space, and has a plurality of connections in which a concave portion and a convex portion are formed that can be fitted to each other between the upper end portion and the lower end portion. A plurality of rods are connected vertically below the bottom body, and the depth from the upper end opening to the bottom of the shoehorn storage space can be adjusted by increasing or decreasing the number of connections.

  The invention according to claim 4 is the above-mentioned invention, wherein the depth adjusting means is provided in a bottom-up space, and an unusual pipe that can be fitted and retracted on the upper side and the lower side is provided below the bottom body, The depth from the upper end opening to the bottom surface of the shoehorn storage space can be adjusted by the movement of the upper and lower pipes.

  According to a fifth aspect of the present invention, in the above-mentioned device, the depth adjusting means is provided with a vertically long slide hole having a plurality of locking grooves in the middle of the peripheral surface of the cylindrical body. A slider portion that can slide up and down in the vertically long slide hole and can be locked in the locking groove is provided on a side portion so as to protrude outward from the peripheral surface of the cylindrical body, and the slider portion is vertically moved in the vertically long slide hole. Then, the depth from the upper end opening to the bottom surface of the shoehorn storage space can be adjusted by being locked in the locking groove.

Since the present invention has the above-described configuration, when the length of the cylindrical body is set to 300 to 700 mm and the shoehorn is put inside the cylindrical body, the bottom of the upper shoehorn storage space is placed at a high position by the lower bottom raising space. Since the bottom is raised, the shoehorn is held at a high position where it is easy to remove.
At that time, the shoehorn mounted on the bottom surface of the shoehorn storage space is supported by the upper end opening of the cylindrical body at an inclination angle smaller than 30 degrees, and when the shoehorn is inserted from the upper end opening of the cylindrical body, The tip of the shoehorn slides down the inner peripheral surface of the cylindrical body and falls to the bottom to stand up. And the handle part of the long shoehorn placed on the bottom of the shoehorn storage space is close to the hand in a standing state, and there is no need to drop or bend it and remove it almost from the body. It can be used comfortably without giving stress.
In particular, it becomes possible to use a shoehorn with peace of mind with little pain for a person with low back pain or a weak person such as an elderly person with weak leg muscles.
In addition, the cylindrical body is long in length, but the pedestal does not take a width, and the whole is light and compact, so that it can be freely moved and placed in a place that can be reached when wearing shoes. And since the aperture of the cylindrical body is 40 to 70 mm, several shoehorns can be accommodated, and a plurality of people can use the shoehorn at a time.
In addition, the pedestal has a circular shape 15 to 40 mm larger than the cylindrical body, so that it can be placed on a flat surface such as the floor or soil, and can be used with peace of mind because it will not fall easily even if it comes into contact with people. .

According to the second aspect of the present invention, the depth from the upper end opening of the cylindrical body at the bottom position of the shoehorn storage space can be adjusted by the depth adjusting means, and according to the length of the shoehorn to be accommodated, It can be set as the state which the handle part protruded in the length which is easy to take out from the upper-end opening part of a cylindrical body.
That is, various sizes of shoehorns can be used in an optimal state.

According to the third aspect of the present invention, when adjusting the depth of the bottom surface of the shoehorn storage space by the depth adjusting means, the bottom surface of the shoehorn storage space can be easily removed from the upper end opening of the cylindrical body by increasing or decreasing the number of connecting rods. It becomes possible to adjust the depth.
And since this depth adjustment means is provided in bottom raising space, it becomes possible to adjust the depth of a bottom face body reliably, without impairing the appearance of a cylindrical body.

When adjusting the depth of the bottom surface of the shoehorn storage space by the depth adjusting means, the invention described in claim 4 moves from the upper end opening of the cylindrical body to the bottom surface of the shoehorn storage space by the movement of the upper and lower pipes. The depth of can be adjusted.
And since this depth adjustment means is provided in a bottom raising space, it becomes possible to adjust the depth of the bottom face of a shoehorn storage space reliably, without impairing the external appearance of a cylindrical body.

  According to the fifth aspect of the present invention, when adjusting the depth of the bottom surface of the shoehorn storage space by the depth adjusting means, the slider portion is moved up and down from the outside of the cylindrical body even with the shoehorn inserted, and the optimum stage is engaged. By engaging with the retaining groove, it is possible to easily adjust the depth from the upper end opening of the cylindrical body to the bottom surface of the shoehorn storage space.

It is a perspective view of the present invention. It is a perspective view which shows the use condition of this invention. (A) of the form provided with the depth adjustment means shows a state where the bottom surface is raised, and (b) is a vertical side view showing a state where the bottom surface is lowered. (B) of the depth adjustment means of another form shows the state which raised the bottom face, (b) is each vertical side view which shows the state which lowered the bottom face. FIG. 2 is a perspective view of the whole, (b) is a perspective view of a bottom surface body, and (c) is an enlarged side view of a main part of the depth adjusting means. (A) of the depth adjustment means of the form of FIG. 5 shows the state which raised the bottom face, (b) is each vertical side view which shows the state which lowered the bottom face. It is a vertical side view which shows the principal part of the fixed part of the base and cylindrical body of another form.

An embodiment of a shoehorn stand of the present invention will be described below with reference to the drawings.
The shoehorn to be used in the present invention does not include a small shoe of about 100 mm that can be carried in a pocket, for example, a long shoehorn having a width of about 50 mm and a length of about 200 to 500 mm.
In the shoehorn stand of the present invention, as shown in FIG. 1, the cylindrical body 1 is fixed upright in the center of a circular base 2.
The cylindrical body 1 has a diameter R of 40 to 70 mm so that several shoehorns can be inserted, and the interior is divided into an upper shoehorn storage space S1 and a lower bottom raising space S2 in the vertical direction.
The diameter of the pedestal 2 is 55 to 110 mm which is 15 to 40 mm larger than the diameter of the cylindrical body 1, and the cylindrical body 1 can stand upright and stably stand by this wide bottom surface.

As shown in FIG. 2, the height A from the pedestal 2 to the upper end opening 1a is placed on the bottom surface 3a of the shoehorn storage space S1 raised by the lower raised space S2 when the user stands. The shoehorn K is set to a height at which the handle portion k of the shoehorn K protrudes upward from the upper end opening 1a and the hand H naturally hits.
For example, in the case of an average height person with a height of 170 cm, the height position of the hand is as high as about 700 mm.
On the other hand, when sitting on an eaves, chair, rim, etc. at the entrance, the position where the hand can be reached easily by reaching forward is a low position of about 300 mm.
Therefore, considering these usages, the height A from the base 2 to the upper end opening 1a is set to 300 to 700 mm.
By setting the height in this way, when using it, you can take the shoehorn K while standing in a standing posture or sitting in a raised heel and put on the shoe in almost the same posture, so bend your waist It is possible to wear shoes easily without taking a posture that stresses the body.

In addition, the opening 1a at the upper end of the cylindrical body 1 is formed in a trumpet shape by widening the periphery 5 to 10 mm outward so that the shoehorn K can be inserted easily. spread.
The cylindrical body 1 can be made of a material such as plastic or metal, and the pedestal 2 can be made of a material such as plastic, wood or metal.

In FIG. 1, the base 2 and the cylindrical body 1 are fixed by immersing a columnar connecting material 9 such as wood or plastic having the same diameter as the cylindrical body 1 to the lower end edge of the cylindrical body 1. Although the aspect which fixed the lower end surface of the material 9 and the base 2 with the adhesive agent is shown, the fixing method of the base 2 and the cylindrical body 1 can be various, and is directly fixed with the adhesive agent without using the connecting material 9. You can also
Further, as shown in FIG. 7, a cylindrical connecting portion 2a having an outer diameter equal to the inner diameter of the cylindrical body 1 is integrally formed on the upper surface of a plastic circular pedestal 2, and the cylindrical connecting portion 2a has a cylindrical shape. It is also possible to fix the base 2 and the cylindrical body 1 by fitting the lower end portion of the body 1.

Then, the center of gravity is lowered so that the tall cylindrical body 1 standing on the pedestal 2 is unlikely to fall down.
For example, as shown in FIG. 7, in a mode in which a cylindrical connecting portion 2a is integrally formed on the upper surface of a plastic circular pedestal 2 and the pedestal 2 and the cylindrical body 1 are fixed, a weight 4 is provided on the pedestal 2. Can be fixed with an adhesive or a screw.
The weight 4 is made of a heavy material such as wood, plastic, ceramic, or metal.

In order to lower the center of gravity, as shown in FIG. 1, the cylindrical body 1 is fixed to the pedestal 2 via a heavy weight connecting material 9 which also functions as the weight 4, or the pedestal 2 itself. It is possible to adopt a mode in which the function of the weight 4 is combined with a large weight.
For example, as shown in FIG. 3, by using a thick iron plate for the pedestal 2 and increasing the weight of the pedestal 2 itself, the center of gravity can be lowered without using the weight 4 separately.

The bottom surface 3a of the upper shoehorn storage space S1 of the cylindrical body 1 is formed on the upper surface of the bottom surface body 3 disposed at a specific depth from the upper end opening 1a.
The installation depth from the upper end opening 1a of the bottom body 3 determines the depth C from the upper end opening 1a of the cylindrical body 1 to the bottom 3a of the shoehorn storage space, as shown in FIG.
The depth C is such that an angle α of a rectangular diagonal line formed by being surrounded by the bottom surface 3a of the shoehorn storage space, the opposed inner wall surface of the cylindrical body 1 and the upper end opening surface is relative to the inner wall surface of the cylindrical body 1. The depth is an angle smaller than 30 degrees.

  For example, when a cylindrical body having a diameter of 40 mm and a length of 680 mm is used for the longest 500 mm shoehorn, and the handle portion k of the shoehorn K is projected 50 mm upward from the upper end opening 1 a, the upper end opening 1 a of the cylinder 1 is To the bottom surface 3a of the shoehorn storage space is 450 mm, and the diagonal angle α is about 5 degrees. A bottom-up space S2 having a height of about 230 mm is formed below the bottom surface 3a.

The angle α of the rectangular diagonal is set to be smaller than 30 degrees because the tip of the shoehorn enters the cylindrical body 1 even if the shoehorn is inserted vertically from the top rather than vertically. This is because this is the limit angle of the angle that naturally falls to the bottom surface 3a of the shoehorn storage space S1.
For example, when the long shoehorn K is supported by the upper end opening 1a at the middle portion, the tip of the shoehorn is in contact with the inner wall surface of the cylindrical body 1, and the length of the handle portion k side from the support portion is longer, 45 degrees Once it is tilted at an angle and once stopped, the tip of the shoehorn K slides up the inner wall surface of the cylindrical body 1 and falls from the handle portion k side.
That is, if the depth C from the upper end opening 1a of the cylindrical body 1 to the bottom surface 3a of the shoehorn storage space is an angle at which the shoehorn is 45 degrees and is supported by the upper end opening 1a, the shoehorn is Since it cannot hold | maintain in storage space S1, it is unpreferable.

When the angle α of the diagonal line of the rectangle is smaller than 30 degrees, when the tip of the shoehorn is brought into contact with the inner wall surface of the cylindrical body 1 and the shoehorn K is supported by the upper end opening 1a, the upper end opening Even if the handle portion k side protrudes longer than the tip end side above 1a, the tip of the shoehorn K slides down the inner wall surface of the cylindrical body 1 and quickly falls down to the bottom surface 3a so as to be sucked into the cylindrical body 1. Go.
As a result, even if the user inserts the shoehorn K obliquely into the upper end opening 1a, the shoehorn K is stood and stored on the bottom surface 3a without falling off.

  For example, even when the diameter R of the cylindrical body 1 is set to 70 mm at the maximum, if the angle α of the diagonal line of the rectangle is 30 degrees, the depth position of the bottom surface 3a is about 115 mm. For this reason, a bottom raised space of about 175 mm is formed in the short cylindrical body 1 of 290 mm, and a bottom raised space S2 of 575 mm is formed in the long cylindrical body 1 of 690 mm.

The bottom surface 3a formed on the top surface of the bottom surface body 3 only needs to be supported so that the shoehorn K placed in the shoehorn storage space S1 falls downward from the shoehorn storage space S1, and the upper surface can be flat, net-like, or lattice-shaped. Yes, it is not limited to a planar shape.
Further, for example, FIG. 1 shows a bottom surface 3 having a flat upper surface of a disk, but a polygonal plate, a lattice, or the like can be used, and is not limited to a disk.
The bottom body 3 can be fixed to the inner surface of the cylindrical body 1 with an adhesive or the like.

The depth C of the bottom surface 3a is preferably set to a depth at which the protruding length B of the handle portion k from the upper end opening 1a of the cylindrical body 1 is 50 mm or more, and the protruding length is about 10 mm or less. It's too short to make it difficult to grab it with your hand. It should be noted that there is no problem because the ease of gripping by hand does not change even if it protrudes more than that.
For example, for a shoehorn having a length of 300 mm, if the depth C from the upper end opening 1 a to the bottom surface 3 a is 220 mm, the protruding length B of the handle portion k is obtained about 80 mm, so that the shoehorn can be easily taken out.

  As described above, the present invention is vertically long but light and compact as a whole, so it can be freely moved to a place where you can reach your shoes when you have a floor space of 2 minutes. be able to.

In the present invention, the depth from the upper end opening 1a of the cylindrical body 1 to the bottom surface 3a of the shoehorn storage space S1 can be adjusted so that shoehorns of various sizes can be used with a single shoehorn stand. A form in which the depth adjusting means 5 is provided is possible.
When the short shoehorn is inserted, the bottom surface body 3 fixed in the cylindrical body 1 cannot be hidden under the upper end opening 1a of the cylindrical body 1 and cannot be taken out. When the long shoehorn is inserted, the bottom body 3 cannot be removed from the upper end opening 1a. However, in the form in which the depth adjusting means 5 is provided, depending on the length of the shoehorn K, the upper end opening 1a of the cylindrical body 1 can be raised upward. The protruding length B of the handle portion k can be adjusted to a length that allows easy removal.
The depth adjusting means 5 can be in the form of a connecting rod connection type shown in FIG. 3, an in / out pipe type shown in FIG. 4, and an up / down slide type shown in FIGS. 5 and 6, which will be described below. .

First, the form of the depth adjusting means 5 shown in FIG. 3 will be described.
In this embodiment, the depth adjusting means 5 is provided in the bottom raising space S2 between the base 2 below the bottom surface body 3, and the concave portion 6b and the convex portion 6a that can be fitted to each other between the upper end portion and the lower end portion are formed. A plurality of connecting rods 6 are connected vertically below the rod connecting portion 7 provided on the lower surface of the bottom surface body 3, and the depth from the upper end opening 1a to the bottom surface body 3 can be adjusted by increasing or decreasing the number of connections. It is what.
The rod connecting portion 7 is for fitting the lower surface of the bottom surface body 3 and the convex portion 6a of the uppermost connecting rod 6 to keep the bottom surface 3a horizontal. Reference numeral 8 in FIG. The connecting rod 6 is constrained to the center of the cylindrical body 1, and a connecting rod connecting portion 8 a shown by reference numeral 8 a connects the disc 8 and the lowermost connecting rod 6.
In the form of the depth adjusting means 5, when adjusting the depth of the bottom surface 3 a, the number of connecting rods 6 is connected as shown in FIG. The depth from 1a to the bottom surface 3a is reduced so that the projection length B of the handle portion k of the short shoehorn K corresponds to an appropriate length, and in FIG. The depth from the upper end opening 1a of the cylindrical body 1 to the bottom surface 3a is increased by two from the number shown in FIG. 3 (a), and the protrusion length B of the handle portion k of the long shoehorn K is set to an appropriate length. The adjustment state corresponding to the above is shown.
In this embodiment, the bottom surface body 3 and the disk 8 formed with the bottom surface 3a are loosely fitted without being fixed to the cylindrical body 1, so that the bottom surface body 3, the connecting rod 6, and the disk 8 are turned upside down. After discharging from 1a and assembling the connecting rod 6 with the number of connections according to the length of the shoehorn on the outside of the cylindrical body 1, the cylindrical rod 1 is returned to the inside through the upper end opening 1a.
By increasing or decreasing the connecting rod 6 in this way, the depth from the upper end opening 1a of the cylindrical body 1 to the bottom surface 3a can be easily adjusted.
In this embodiment, since the depth adjusting means 5 is provided inside the cylindrical body, the product is a good-looking product without impairing the appearance of the cylindrical body 1.

Next, the form of the depth adjusting means 5 shown in FIG. 4 will be described.
In the form of the depth adjusting means 5, a small diameter upper pipe 11 and a large diameter which are provided in a bottom-up space S 2 between the bottom body 3 and the weight 4 (9) serving also as a connecting material can be fitted and retracted. The lower pipe 10 is connected to the lower surface of the bottom surface body 3, and the depth from the upper end opening 1 a to the bottom surface body 3 can be adjusted by projecting the upper and lower pipes 11, 10.
In the form of this depth adjusting means 5, for example, FIG. 4 shows an aspect in which the protruding and retracting position can be fixed by using a fixed wedge 12 having a pointed tip that can be inserted into the gap between the pipes 11 and 10. However, the pipes 11 and 10 can be fixed with pins or bolts in various ways.
In FIG. 4, reference numeral 11 a is a pipe connection portion 11 a that keeps the bottom surface 3 a horizontal and the lower surface of the bottom body 3 and the upper end of the pipe, and reference numeral 10 a is a disk that constrains the lower end to the center of the cylindrical body 1. It is the pipe connection part 8a provided with.
Also in this embodiment, the bottom surface body 3 and the pipe connection portion 8a are loosely fitted to the cylindrical body 1 so as to be loosely fitted, so that the bottom surface body 3, both pipes 11, 10, and the pipe connection portion 8a are placed at the upper end opening 1a. The pipes 11 and 10 are adjusted to appear and retract on the outside of the cylinder 1 and adjusted to the position corresponding to the shoehorn, and then returned to the inside through the upper end opening 1a of the cylinder 1 and easily adjusted. Is possible.
4A shows a state in which the bottom surface 3a is raised and the bottom body 3 is fixed at a shallow position with the fixed wedge 12 according to the length of the shoehorn K. FIG. 4B shows the bottom surface body with the bottom surface 3a lowered. 3 shows a state where 3 is fixed at a deep position by a fixed wedge 12.
Also in this embodiment, since the depth adjusting means 5 is provided inside the cylindrical body 1, it is possible to provide a good-looking product without impairing the appearance of the cylindrical body 1.

Next, the form of the depth adjusting means 5 shown in FIGS. 5 and 6 will be described.
In the form of the depth adjusting means 5, as shown in FIG. 5 (a), a vertically long slide hole provided with a plurality of symmetrical locking grooves 14 in the middle on both side circumferential surfaces of the cylindrical body 1 so as to face each other. As shown in FIG. 5B, the bottom body 3 has a slider portion 15 which can slide the vertically long slide hole 13 up and down on both sides and can be locked in the locking groove 14. Are provided so as to protrude outward from the peripheral surface of the cylindrical body 1.
Then, as shown in FIG. 5C, the depth from the upper end opening 1a to the bottom surface 3a is increased by moving the slider portion 15 up and down in the vertically long slide hole 13 and locking it in the locking groove 14. Adjustable.
In this embodiment, when adjusting the depth of the bottom surface 3 a by the depth adjusting means 5, the slider portion 15 is held up and down from the outside of the cylindrical body 1 by holding the knob 16 provided on the slider portion 15 to lock the optimum step. By engaging with the groove 14, the depth from the upper end opening 1a of the cylindrical body 1 to the bottom surface 3a can be easily adjusted.
6 (a) shows a state in which the bottom body 3 is raised and the slider portion 15 is inserted into the upper locking groove 14 to fix the position corresponding to the short shoehorn K, and FIG. 6 (b) is long. In correspondence with the shoehorn K, the bottom body 3 is lowered and the slider portion 15 is inserted into the lower locking groove 14 to fix the position.
In order to keep the bottom body 3 horizontal, as shown in FIG. 5C, the locking grooves 14 on both sides of the cylindrical body 1 form symmetrical longitudinal grooves having the same width as that of the longitudinal slide hole 13. The slider 15 is also a vertically long and rectangular plate having the same width, so that the slider 15 is non-rotatably restrained by the locking groove 14 and the bottom body 3 is kept horizontal. It becomes possible to be locked.
This configuration is convenient because the depth of the bottom surface 3a can be adjusted from the outside of the cylindrical body 1 even with the shoehorn K placed in the cylindrical body 1.

  Since the present invention can accommodate several shoehorns, it is suitable for business use such as hotels and restaurants where many people attach and detach shoes at the same time, but it can also be used at small entrances at home because it is compact. is there.

DESCRIPTION OF SYMBOLS 1 Cylindrical body 1a Upper end opening part 2 Base 2a Cylindrical connection part 3 Bottom face body 3a Bottom face 4 Weight 5 Depth adjustment means 6 Connecting rod 6a Convex part 6b Concave part 7 Rod connection part 8 Disc 8a Rod connection part 9 Connecting material 10 Lower pipe 10a Pipe connection portion 11 Upper pipe 11a Pipe connection portion 12 Fixed wedge 13 Long slide hole 14 Locking groove 15 Slider portion 16 Knob R Diameter of cylindrical body A Height from base to upper end opening of cylindrical body B Projection length of the handle portion of the shoehorn from the upper end opening C Depth from the upper end opening when the bottom surface is raised to the bottom surface of the shoehorn storage space D Bottom surface of the shoehorn storage space from the upper end opening when the bottom surface is lowered Depth to K Shoehorn k Shoehorn handle part α Angle of rectangular diagonal line formed by the bottom surface of the shoehorn storage space, the opposed inner wall surface of the cylindrical body and the top opening surface S1 Shoehorn storage space S2 Bottom raising space

Claims (5)

A shoehorn storage space is formed in the upper part of the cylindrical body, and a bottom raising space is formed in the lower part. The diameter of the cylindrical body is 40 to 70 mm, the length is 300 to 700 mm, and the diameter of the cylindrical body is 15 to 40 mm larger than the cylindrical body. Fixed upright in the center of a large circular pedestal,
The bottom surface of the storage space is formed at a depth such that an angle of a diagonal line formed by the bottom surface, the opposed inner wall surface of the cylindrical body, and the upper end opening surface is smaller than 30 degrees with respect to the inner wall surface of the cylindrical body. A shoehorn stand that is characterized by   The bottom surface of the shoehorn storage space is formed on the bottom surface body, and the bottom surface body is provided with a depth adjusting means capable of adjusting the depth from the upper end opening of the cylindrical body to the bottom surface of the shoehorn storage space. The shoehorn stand according to claim 1.   A plurality of connecting rods that are provided in the bottom-up space and that have recesses and protrusions that can be fitted to each other between the upper end and the lower end are connected to the depth adjustment means vertically below the bottom body. The shoehorn stand according to claim 2, wherein the depth from the upper end opening to the bottom surface of the shoehorn storage space can be adjusted by increasing or decreasing the number.   Depth adjusting means is provided in the bottom-up space, and a different type of pipe that can be fitted and retracted on the upper side and the lower side is connected to the bottom body, and the upper end opening is moved by the movement of the upper and lower pipes. The shoehorn stand according to claim 2, wherein the depth from the shoehorn storage space to the bottom surface of the shoehorn storage space is adjustable. The depth adjusting means is provided with a vertically long slide hole having a plurality of locking grooves in the middle of the peripheral surface of the cylindrical body, and the bottom surface body can slide the vertically long slide hole up and down on the side and A slider portion that can be locked in the locking groove is provided so as to protrude outward from the peripheral surface of the cylindrical body, and the upper end opening is formed by moving the slider portion up and down in the vertically long slide hole and locking it in the locking groove. The shoehorn stand according to claim 2, wherein the depth from the portion to the bottom surface of the shoehorn storage space is adjustable.

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