JP3205416U - Anti-vibration decompression buffer structure at the bottom of the shoe - Google Patents

Abstract

An anti-vibration pressure-reducing buffer structure for a bottom portion in a shoe is provided. SOLUTION: A shoe body 1 having a recess 111 at the bottom of a shoe, and a recess 111 at an inner bottom of the shoe body, comprising an upper layer plate 21, a lower layer plate 22, and a plurality of internal springs. 23 and a shock absorber 2 including a plurality of external springs 24. Upper and lower connection blocks 210 and 220 are provided in the middle of the lower layer plate 21 and the lower layer plate 22, respectively. The lower sleeve blocks 211 and 221 are provided in the front and rear of the lower plate 21 and the lower plate 22, and lower sleeve blocks 211 and 221 are provided. Provided in the fixed space and outside. The shock absorber 2 provided on the inner bottom of the shoe body is raised and lowered at different heights according to various different reaction forces, and different pressures are immediately dispersed and absorbed to generate air convection at the bottom of the shoe. . [Selection] Figure 1

Description

  The present invention relates to a shock-absorbing structure, and in particular, a shock absorber provided on the inner bottom of a shoe main body is raised and lowered at different heights according to various different reaction forces, and walking, running and jumping around the foot. The present invention relates to a bottom vibration-proof pressure-reducing buffer structure in a shoe that immediately disperses and absorbs various different pressures received at the time, and generates air convection at the bottom of the shoe.

In general, people wear shoes to protect their feet so that they are not injured, but because of the weight of the body itself, when walking, running or jumping, The force transmitted from the head to the knee is one to several times. However, in the conventional shoe structure, in order to achieve the purpose of comfort and flexibility when wearing, at most, a cushion is placed on the bottom of the shoe, and when the user wears the shoe, Because the structure is incompressible, the shoe sole cannot be adjusted up and down with the force received during walking, running, jumping, and the reaction force generated from the ground cannot be dispersed or absorbed. It cannot be said that it has buffering and protective properties, and the reaction force is transmitted directly from the foot to the knee, causing severe injury. Later, the air cushion sole was invented, but the air cushion sole structure is only an air-filled air chamber, and the two shoes lose their function when broken by small stones or other foreign objects. Also, when the shoe sole of this structure receives a force applied from the foot, its height is also fixed and cannot be compressed, and the shoe sole varies according to various different reaction forces received by the foot. When the shoe cannot be adjusted and the shoe sole is subjected to various different reaction forces, the shoe and the knee cannot be dispersed or absorbed. In addition, none of the bottoms in conventional shoes can generate air convection, and the hot air in the feet cannot generate air convection with the outside world. Practicality has deteriorated, and this is where the person skilled in the art and consumers want to improve the most. In consideration of this, the present inventors raise and lower the shock absorber provided on the inner bottom portion of the shoe main body at different heights according to various different reaction forces, and perform walking, running and jumping around the foot. Disperses and absorbs various different pressures received from time to time, generating air convection at the bottom of the shoe, effectively improving its anti-vibration buffer and comfort and breathability when wearing the shoe body Let

  In order to solve the deficiencies of the prior art, the main object of the present invention is to provide a bottom anti-vibration decompression buffer structure in the shoe, and the shock absorber provided on the inner bottom of the shoe body can be installed in various different reaction forces. The problem of the prior art is solved by moving up and down at different heights depending on the situation.

A secondary object of the present invention is to provide a bottom anti-vibration decompression buffer structure in the shoe, which immediately disperses and absorbs various different pressures received during walking, running and jumping around the foot. It is possible to do.
Another object of the present invention is to provide a bottom anti-vibration decompression buffer structure in a shoe and generate air convection in the bottom of the shoe.
Another object of the present invention is to provide a bottom vibration-proof pressure-reducing buffer structure in a shoe, and to effectively improve the vibration-proof pressure-reducing buffer and comfort and breathability when the shoe body is worn.

The problems to be solved by the present invention are as follows. In general, people wear shoes to protect their feet so that they are not injured, but the body itself has weight, so when walking, running or jumping, the relationship with the reaction force with the ground Thus, the force transmitted from the foot to the knee is one to several times. However, in the conventional shoe structure, in order to achieve comfort and flexibility when wearing, at most, a cushion is placed on the bottom of the shoe, and the shoe sole is compressed when the user wears the shoe. Because it is a structure that cannot be done, when walking, running, jumping, the shoe sole cannot be adjusted up and down with the force received, and the reaction force generated from the ground cannot be dispersed and absorbed, so buffering The reaction force is transmitted directly from the foot to the knee, causing severe injury. Although the air cushion sole was invented, the air cushion sole structure is only an air-filled air chamber, and the two shoes lose their function when cracked by small stones or other foreign objects. In addition, when the shoe sole of this structure receives a force applied from the foot, its height cannot be fixed and compressed, and the sole can be adjusted differently with different reaction forces received by the foot. Therefore, when the shoe sole is subjected to various reaction forces, the shoe cannot be dispersed or absorbed, so that the foot and knee are easily damaged by impact, and the bottom of the conventional shoe has air convection. , The hot air in the foot cannot generate air convection with the outside world, the ventilation is poor, the odor is likely to be generated, and the practicality is deteriorated.

To achieve the above object, the present invention provides a bottom anti-vibration vacuum buffer structure in a shoe. Comprising a shoe body provided with a recess in the inner bottom, and a shock absorber;
The shock absorber is provided in a recess in the inner bottom portion of the shoe body and includes an upper layer plate, a lower layer plate, a plurality of internal springs, and a plurality of external springs,
Here, the upper layer plate is provided with an upper connection block at the lower center thereof, and a plurality of upper sleeve blocks each having a center forming a fixed space are provided on the front and rear sides thereof,
The lower layer plate is provided below the upper layer plate, the lower connection block corresponding to the upper connection block of the upper layer plate is provided at the upper center, and the center corresponds to the upper sleeve block of the upper layer plate before and after that, and the center has a fixed space. A plurality of formed lower sleeve blocks are provided,
The plurality of internal springs are provided in the fixed spaces of the corresponding upper sleeve block and lower sleeve block in the upper layer plate and the lower layer plate,
The plurality of external springs are provided outside the corresponding upper sleeve block and lower sleeve block in the upper layer plate and the lower layer plate.

Furthermore, in the present invention, the upper layer plate is provided with a plurality of through holes.
The shape of the upper sleeve block of the upper layer plate of the present invention preferably exhibits a cylindrical shape, an arc shape, or a shape having a similar function.
Further, the lower layer plate of the present invention is provided with a plurality of through holes.
The shape of the lower sleeve block of the lower layer plate of the present invention preferably exhibits a cylindrical shape, a circular arc shape, or a shape having a similar function.
Further, a cushion with a through hole is provided above the shock absorber of the present invention.

  Under this structure, the shock absorber provided on the inner bottom of the shoe body can be raised and lowered at different heights against different reaction forces, and different pressures received during walking, running and jumping around the foot. Is immediately dispersed and absorbed, and air convection is generated at the bottom of the shoe, effectively improving the anti-vibration pressure-reducing buffer and the comfort and breathability when the shoe body is worn.

It is a three-dimensional exploded view of the present invention. The solid combination figure of this invention. The combined sectional view of the present invention. The Example figure by which the cushion was added to the buffer of this invention. The present invention is an embodiment diagram (1) that works with the foot. This invention is an embodiment diagram (2) that works with the foot. This invention is the embodiment figure (3) which acts with the foot.

  In order to facilitate understanding of the features, contents, advantages and achievable effects of the present invention, the present invention will be described in detail with reference to the drawings and embodiments of the embodiments will be described in detail. However, the scope of protection of the present invention is not limited by the proportionality and arrangement of the additional drawings.

As shown in FIG. 1, FIG. 2, FIG. 3 and FIG. 4, it is a three-dimensional exploded view, a three-dimensional combination diagram, a combination sectional view of the present invention, and an embodiment diagram in which a cushion is added to a shock absorber. The bottom bottom anti-vibration vacuum buffer structure includes a shoe body 1 and a shock absorber 2 in two optimal embodiments.
The shoe body 1 is provided with a recess 111 in the inner bottom 11 thereof.

  The shock absorber 2 is provided in the recess 111 of the inner bottom portion 11 of the shoe body 1, and the shock absorber 2 includes an upper layer plate 21, a lower layer plate 22, a plurality of internal springs 23, and a plurality of external springs 24. The upper layer plate 21 is provided with an upper connection block 210 at the lower center thereof, and an upper sleeve block 211 having a plurality of centers forming fixed spaces 2110 at the front and rear of the upper connection block 210, respectively. It is preferable that the shape of the upper sleeve block 211 of the upper layer plate 21 of the present invention is a cylindrical shape or an arc shape, but the present invention is not limited to this, and even if the shape of the same function is The lower layer plate 22 is provided below the upper layer plate 2 and belongs to the protection range of the present invention, and a lower connection block 220 corresponding to the upper connection block 210 of the upper layer plate 21 is provided at the upper center thereof. A plurality of lower sleeve blocks 221 each having a fixed space 2210 at the center thereof corresponding to the upper sleeve block 211 of the upper layer plate 21 are provided on the front and rear sides thereof. Although the hole 222 is provided and the shape of the lower sleeve block 221 of the present invention is preferably a cylindrical shape or an arc shape, the present invention is not limited to this, and the shape of the same function may be used. The plurality of internal springs 23 are provided in the corresponding upper sleeve block 211 and lower sleeve block 221 in the fixed spaces 2110 and 2210 of the upper layer plate 21 and the lower layer plate 22, and the plurality of external springs 24 are connected to the upper layer plate 21 and the lower layer plate 22. The lower sleeve 22 is provided outside the corresponding upper sleeve block 211 and lower sleeve block 221. In the present invention, in order to perform different functions according to various different forces, the diameters of the plurality of internal springs 23 are smaller than the plurality of external springs 24, and the wire diameters of the plurality of internal springs 23 are the plurality of external springs 24. The number of coils of the plurality of internal springs 23 is smaller than that of the plurality of external springs 24, and a cushion 3 with a through hole 31 is provided above the shock absorber 2 of the present invention (as shown in FIG. 4). .

  As shown in FIGS. 5, 6, and 7, the present invention works with a foot (1), the present invention works with a foot (2), and the present invention works with a foot. FIG. 3 is an embodiment of the present invention. The assembly of the present invention is simple and easy. The shock absorber 2 may be placed in the concave portion 111 of the inner bottom portion 11 of the shoe main body 1. Since it is provided in the inner bottom part 11 and the shock absorber 2 is located therein and cannot be seen from the outside of the shoe body 1, the appearance is not affected. When used, the foot 4 directly steps on the upper layer plate 21 (as shown in FIGS. 1 to 3 and 5) above the shock absorber 2 or the cushion 3 (as shown in FIG. 4) provided thereon. When the front stage of the foot 4 receives a force (as shown in FIG. 6), the front stage of the upper layer plate 21 is compressed downward, and at this time, according to the magnitude of the received reaction force, When a small reaction force causes a compression action from a plurality of internal springs 23 having a smaller wire diameter, a larger number of coils, and a smaller diameter, and compressed to a certain degree, the wire diameter is similarly compressed. A plurality of external springs 24 with a larger number of coils, a smaller number of coils and a larger diameter produce a relatively large acting force and act with a compressed internal spring 23 to produce a strong buffer. Accordingly, different reaction forces generated in various different stages are adjusted as needed, and when the rear stage of the foot 4 receives a force, the rear stage of the upper layer plate 21 is similarly compressed downward (as shown in FIG. 7). 6), when the shock absorber 2 of the present invention is operated, the upper layer plate 21 and the lower layer plate 22 are provided with through holes 212 and 222, respectively. When raising and lowering compression occurs, air convection is generated in the shoe 1 (as shown in FIGS. 5, 6, and 7).

  Under this structure, the shock absorber 2 provided on the inner bottom portion 11 of the shoe body 1 is moved up and down at different heights according to various different reaction forces, and walking, running and jumping around the foot portion 4 The different pressures received at the time are immediately dispersed and absorbed, and air convection is generated in the bottom portion 11 of the shoe, effectively improving the vibration-proof pressure-reducing buffer and the comfort and breathability when the shoe body 1 is worn. . As described above, the present invention breaks through the structure of the prior art and reliably achieves the effect desired to be strengthened and cannot be easily conceived by those skilled in the art.

  The above-described embodiments are merely for explaining the technical idea and features of the present invention, and the purpose thereof is that those skilled in the art can understand and implement the contents of the present invention. The present invention is not limited thereto, and various omissions, replacements, and changes can be made without departing from the scope of the present invention. These equivalent variations and modifications are included in the claims of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Shoe body 11 ... Inner bottom part 111 ... Recessed part 2 ... Shock absorber 21 ... Upper layer board 210 ... Upper connection block 211 ... Upper sleeve block 2110 ... Fixed space 212 ... Through hole 22 ... Lower layer plate 220 ... Lower connection block 221 ... Lower sleeve block 2210 ... Fixed space 222 ... Through hole 23 ... Internal spring 24 ... External spring 3 ... Cushion 31 ... Through hole 4 ... Foot part

Claims (10)

A bottom anti-vibration decompression buffer structure in the shoe,
A shoe body provided with a recess at the bottom;
Provided in a recess in the inner bottom portion of the shoe body, and comprising a shock absorber including an upper layer plate, a lower layer plate, a plurality of internal springs, and a plurality of external springs,
here,
The upper layer plate is provided with an upper connection block at the lower center thereof, and a plurality of upper sleeve blocks in which the center forms a fixed space at the front and rear thereof,
The lower layer plate is provided below the upper layer plate, the lower connection block corresponding to the upper connection block of the upper layer plate is provided at the upper center, and the center corresponds to the upper sleeve block of the upper layer plate before and after that, and the center has a fixed space. A plurality of formed lower sleeve blocks are provided,
The plurality of internal springs are provided in the fixed spaces of the corresponding upper sleeve block and lower sleeve block in the upper layer plate and the lower layer plate,
A bottom vibration-proof pressure-reducing buffer structure in a shoe, wherein a plurality of external springs are provided outside corresponding upper sleeve blocks and lower sleeve blocks in an upper layer plate and a lower layer plate.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 1, wherein a cushion with a through hole is provided above the shock absorber.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 1 or 2, wherein the upper layer plate is provided with a plurality of through holes.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 1 or 2, wherein a plurality of through holes are attached to the lower layer plate.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 3, wherein the lower plate is provided with a plurality of through holes.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 1 or 2, wherein the upper sleeve block of the upper layer plate has a cylindrical shape, an arc shape, or a shape having an equivalent function.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 3, wherein the upper sleeve block of the upper layer plate has a cylindrical shape, an arc shape, or a shape having an equivalent function.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 4, wherein the shape of the upper sleeve block of the upper layer plate is a cylindrical shape, an arc shape, or a shape having an equivalent function.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 5, wherein the upper sleeve block of the upper layer plate has a cylindrical shape, an arc shape, or a shape having an equivalent function.   The bottom vibration-proof pressure-reducing buffer structure in a shoe according to claim 9, wherein the shape of the lower sleeve block of the lower layer plate is a cylindrical shape, an arc shape, or a shape having an equivalent function.