KR102030530B1 - Midsole with improved dynamic stability - Google Patents

Abstract

The present invention relates to a midsole with improved restoring force and, more specifically, to a midsole with improved restoring force, which improves pressure dispersion and shock absorbing force by a crossing arrangement structure of polygonal prism bodies having elastic restoring force, improves restoring force of the polygonal prism bodies, and circulates air by connecting an air path to an elastic restoring layer formed of the polygonal prism bodies. To achieve the purpose of the present invention, the midsole comprises: a first elastic restoring layer arranged on an upper part of an outsole, having a plurality of first polygonal prism bodies with open upper and lower parts, which come in contact with each other, and having elastic restoring force; and a second elastic restoring layer arranged between the upper part of the first elastic restoring layer and the uppers, having a plurality of second polygonal prism bodies with open upper and lower parts, which come in contact with each other, and having elastic restoring force by alternately arranging the first polygonal prism bodies and the second polygonal prism bodies.

Description

Midsole with improved dynamic stability

The present invention relates to a midsole having improved restoring force, and more particularly, to improve pressure dispersion and impact absorption by an intersecting arrangement of a polygonal column body having elastic restoring force, and to improve the restoring force of the polygonal column body, The air passage is connected to the elastic restoration layer made of a sieve and relates to a midsole having improved restoring force through which air is circulated.

In general, shoes are worn to protect the feet of the human body and are manufactured and marketed in a wide variety of shapes and types. However, shoes are usually covered by covering the instep of the foot and the ankle, and the sole is protected from the ground. It is composed of a shoe sole to improve the walking force by increasing the friction force, and to mitigate the impact on the sole of the foot during walking.

In the case of the conventional shoes as described above, insoles are placed on the inner bottom surface of the shoes to absorb shocks transmitted from the ground to the soles when walking, or the soles and the heel portions are made of rubber and foam sponge material having excellent buffering capacity. It has been known that an elastic restoration such as an air bag or a spring is incorporated in a shoe sole.

As described above, when the sole is manufactured from rubber or foam sponge, or an elastic restoring body such as an air bag or a spring is installed in the sole, only a simple shock absorbing function can be performed, from the heel of the pedestrian to the toe. When based on a walking path that is in contact with the ground while having a rough arc shape, the conventional general shoe has a problem that hardly contributes to the aspect to perform a natural and efficient walking.

In particular, the number of people who enjoy outdoor activities is increasing due to the improvement of living standard and the spread of five-day work week. As a result, people feel better fit than those who enjoy outdoor activities, and do not put stress on the joints and soles of the wearer's knees and feet, and contribute to health promotion by simply wearing shoes and walking. Footwear manufacturers are investing a lot of time and effort in the development of functional footwear.

In the past, Korean Patent Publication No. 10-1059393 has been known as "sole midsole having a shock dispersion function and a cloud walking function". Here, the shoe sole (midsole) is attached to the support pad on the bottom surface of the cushion pad to be a cushion material, the support pad is to be formed to protrude the support so that the pressure is dispersed during walking.

However, since the support sole of the shoe sole is protruded in a single layer, the insertion groove into which the support bar is inserted into the cushion pad is deformed by repeated loads while walking, thereby preventing the original restoration function.

In addition, due to the structure of the shoe sole, air does not circulate, causing sweat on the foot for a long time, causing an unpleasant smell or moisture to occur inside the shoe, thereby causing a problem of deteriorating the user's fit.

In the related art, a difficulty arises in that the rigidity of the support bar at the corresponding point is different from each other according to the pressure range of the foot pressure of the user.

Republic of Korea Patent Publication No. 10-1059393

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and improves the pressure dispersion and impact absorption by the intersecting arrangement structure of the polygonal pillar having elastic restoring force, and aims to improve the restoring force of the polygonal pillar. have.

In addition, the inner space of the elastic restoring layer is circulated with the outside air to improve breathability has another purpose to increase the user's fit.

In addition, there is another object to provide a midsole that can be used for walking correction by mounting a pressure support having a different hardness according to the user's plantar pressure.

In order to achieve the above object, the present invention is disposed on the top of the outsole, a plurality of first polygonal pillars of which the upper and lower portions are open to contact each other, the first elastic restoring layer having an elastic restoring force; and the first elastic restoring A second elastic restoration disposed between the upper layer and the upper, and having a plurality of second polygonal pillars having upper and lower portions contacted with each other, and having the first polygonal pillar and the second polygonal pillar intersected and having elastic restoring force; The first polygonal pillar and the second polygonal pillar, including; a first compression facet formed to be inclined from the front to the rear outward, erected symmetrically; It is connected to the left and right rear ends of the first compressed polyhedron, the support surface is standing vertically; And a second compressed polyhedron which is connected to the left and right rear ends of the support polyhedron and is inclined rearward, and is symmetrically erected. A first pressing point at which the first compressed polyhedron intersects; a second pressing point at which the second compressed polyhedron of the first polygonal pillar intersects with a second compressed polyhedron of the second polygonal cylinder; It is characterized by being formed.

In addition, disposed between the outsole and the first elastic restoring layer, the lower surface film layer of the light transmissive material; and the second elastic restoring layer and the upper is disposed between the upper surface film layer of the light transmissive material; Characterized in that.

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The first polygonal pillar and the second polygonal pillar may be arranged to cross each other so that air passages connected to each other in the vertical direction, the horizontal direction, and the front-rear direction are formed.

In addition, the pressure support is disposed in a position corresponding to the pressure point detected in accordance with the plantar pressure analysis of the user, made of a hard material, the pressure support is inserted into the inner space of the first polygonal pillar and the second polygonal pillar; It is characterized by including.

The midsole with improved restoring force according to the present invention by the means for solving the above problems is minimized the area of the pressure point where the pressure load is transmitted by the intersecting arrangement structure of the polygonal column body having elastic restoring force, the pressure load of the user is dispersed There is an advantage in that the shock absorbing power is improved.

In addition, the air passage is formed so that the inner space of the elastic restoring layer circulates with the outside air, thereby improving breathability, thereby removing moisture in the shoe, thereby increasing the user's wearing comfort.

In addition, according to the plantar pressure of the user can be used for walking correction by mounting the pressure support body of various hardness on the polygonal column body, it can be used for a long time because the wear life is extended, Due to user Walking correction shoes can be made and worn.

1 is a block diagram of a midsole with improved restoring force according to an embodiment of the present invention.
2 is a front view of an improved midsole in accordance with one embodiment of the present invention.
Figure 3 is an enlarged perspective view of the elastic restoring layer of the improved midsole according to an embodiment of the present invention.
Figure 4 is a block diagram of a polygonal pillar of the midsole improved restoring force according to an embodiment of the present invention.
5 is an enlarged front view of an elastic restoring layer of a midsole having improved restoring force according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in the following description of the present invention, a description of a known function or configuration will be omitted to clarify the gist of the present invention.

In addition, in describing the present invention, terms indicating directions are described to enable those skilled in the art to clearly understand the present invention and indicate relative directions, and thus, the scope of rights is not limited thereto.

1 and 2, the midsole 1 having improved restoring force according to an embodiment of the present invention includes a lower surface film layer 100, a first elastic restoring layer 210, a second elastic restoring layer 220, and an upper portion. It consists of a surface film layer 300, the pressure supporting member 400, the pressure supporting member 500.

In general, the shoe is composed of the upper (3) and the sole, the sole is divided into a midsole (2) and outsole (1). The present invention relates to the midsole (2) disposed between the upper (3) and the outsole (1), the detailed description of the upper (3) and the outsole (1) will be omitted.

The lower surface film layer 100 and the upper surface film layer 300 are disposed above and below the elastic restoring layer 200 to reduce the heterogeneity when wearing shoes equipped with the elastic restoring layer 200 to increase the feeling of wearing. The lower surface film layer 100 and the upper surface film layer 300 is preferably made of a transparent material of a transparent material such as a TPU film.

At this time, the lower surface film layer 100 is disposed on the top of the outsole (1), the user visually differentiates the structural features of the elastic restoring layer 200 through the outsole (1) exposed inside using the characteristics of the material As it can be confirmed, there is an advantage that can be utilized in marketing.

The elastic restoring layer 200 has a structure in which the first elastic restoring layer 210 and the second elastic restoring layer 220 are stacked, and the plurality of first elastic restoring layers 210 and the second elastic restoring layer 220 are formed. ) Can be alternately stacked to further improve the restoring force. The elastic restoring layer is formed such that a plurality of polygonal pillars having upper and lower portions in contact with each other, and made of an elastic material, has a function of absorbing shock and restoring by repulsive material due to pressure load.

The first elastic restoring layer is disposed on the lower surface film layer 100, and the plurality of first polygonal pillars 211 having upper and lower portions contact each other. In this case, the first polygonal pillar 211 may be formed in a hexagonal or quadrangular shape, it is preferable that the first polygonal pillar 211 is formed in a symmetrical regular hexagon or square shape in order to balance to increase the shock absorption and repulsive force due to the pressure load.

In particular, when the first polygonal pillar 211 is formed in a hexagonal shape, the first polygonal pillar 211 includes six elastic surfaces 201 having a set thickness and six corners 202 where the neighboring elastic surfaces 201 meet. At this time, the edge 202 of the first polygonal pillar 211 may be sharply disposed in the front-rear direction, thereby minimizing the length deformation by such an arrangement structure to have a robust structural feature.

On the other hand, the first polygonal pillar 211 is composed of a first compression face 211a, a support face 211b, a second compression face 211c according to the structural features.

The first compression face 211a is formed to be inclined from the front to the rear outside, and is symmetrically arranged so that the pressure load of the user is balanced while balancing the left and right pressures.

The support surface 211b is disposed at the rear end of the first compression body 211a and is erected vertically, and supports the first compression body 211a and the second compression body 211c to be compressed by the user's pressure load. The restoring force of the first compressed polyhedron 211a and the second compressed polyhedron 211c is improved.

The second compression face 211c is disposed at the rear end of the support face 211b, and is formed to be inclined rearward, and is disposed to be symmetrical with the first compression face 211a so that the pressure load of the user is balanced back and forth, left and right. While being distributed and compressed.

As shown in FIGS. 3 and 4, the second elastic restoring layer 220 is disposed on the first elastic restoring layer 210 so that the plurality of second polygonal pillars 221 having upper and lower portions contact each other. Is done. In this case, the second polygonal pillar 221 is preferably formed in the same shape as the first polygonal pillar 211. The second polygonal pillar 221 is disposed to intersect with the first polygonal pillar 211 so that the pressure load of the user is distributed from the second polygonal pillar 221 to the first polygonal pillar 211, and the load The cross-sectional area of the first polygonal pillar 211 and the second polygonal pillar 221 that is transmitted is minimized to maximize the repulsive force, thereby improving the restoring force. In addition, the first polygonal pillar 211 and the second polygonal pillar 221 are arranged to cross each other to form an air passage 205a connected to each other in the vertical direction, the left and right directions, and the front and rear directions. The outside air flows into the inner space of the first polygonal pillar 211 and the second polygonal pillar 221 by the air passage 205a so that the air is circulated by the air passage 205a.

The second polygonal pillar 221 is formed in the same structure as the first polygonal pillar 211, and is composed of a first compressive surface 221a, a support surface 221b, and a second compressive surface 221c. Since the structure is the same as the first polygonal pillar 211, the structural description thereof will be omitted.

As illustrated in FIG. 5, the first compression face 221 a of the second polygon pillar 221 is disposed to intersect the first compression face 211 a of the first polygon pillar 211, and thus, the first pressing point ( 203 is formed.

The second compression face 221c of the second polygonal pillar 221 is disposed to intersect the second compression face 211c of the first polygonal pillar 211 to form a second pressing point 204. The second pressing point 204 is formed symmetrically to balance the first pressing point 203.

1 and 3, the upper surface film layer 300 is disposed between the second elastic restoring layer 220 and the upper 3, and a plurality of upper surface film layers 300 communicate with the internal space of the second polygonal pillar 221. An air vent 205 may be formed. In addition, the air vent 205 communicates with the air passage 205a of the first polygonal pillar 211 and the second polygonal pillar 221 so that the outside air is circulated into the shoe, and the moisture inside the shoe is transferred to the outside. It can be discharged to increase the fit.

1 and 2, the pressure supporting member 400 is formed to correspond to the inner space of the second polygonal pillar 221, and the inner space of the second polygonal pillar 221 of the upper surface film layer 300. It is inserted into the plurality of insertion holes 206 communicated with. At this time, the pressing support 400 is formed to protrude to the upper surface of the upper film layer 300 to the user's foot is acupressure, the user can be directly inserted into or replaced at a desired point can be increased acupressure satisfaction. .

2 and 5, the pressure support 500 is disposed at a position corresponding to the pressure point detected according to the plantar pressure analysis of the user, and is made of a hard material, such that the first polygonal pillar 211 and the second It is inserted into the inner space of the polygonal column body 221. The pressure support 500 is preferably provided to have respective hardness corresponding to the pressure at the point according to the pressure range of the plantar pressure. In addition, the pressure support 500 can be easily mounted and manufactured, it is possible to extend the shoe replacement period.

As described above, the basic technical idea of the present invention is to improve pressure dissipation and shock absorption by the intersecting arrangement structure of the polygonal pillar having elastic restoring force, to improve the restoring force of the polygonal pillar, and to restore the elastic pillar of the polygonal pillar. It can be seen that the air passage is connected to the midsole to provide improved restoring force through which air is circulated.

Of course, various modifications are possible by those skilled in the art within the basic technical scope of the present invention, and therefore, the scope of the present invention should be interpreted within the claims made to include various modifications. will be.

1: outsole
2: midsole
3: upper
100: lower surface film layer
200: elastic restoring layer
201: elastic surface
202: corner
203: first pressing point
204: second pressure point
205: air vent
205a: air passage
206: insertion hole
210: first elastic restoring layer
211: first polygonal column
211a: first compressed polyhedron
211b: support
211c: second compressed polyhedron
220: second elastic restoring layer
221: second polygonal column
221a: first compressed polyhedron
221b: support surface
221c: second compressed polyhedron
300: upper surface film layer
400: pressure support
500: pressure support

Claims (5)

A first elastic restoring layer disposed on the outsole and having a plurality of first polygonal pillars having upper and lower portions contacting each other and having elastic restoring force; and
A plurality of second polygonal pillars disposed between the upper and upper portions of the first elastic restoring layer and the upper and lower portions thereof are in contact with each other, and the first polygonal pillar and the second polygonal pillar are arranged to cross each other to provide elastic restoring force. Including; a second elastic restoring layer;
The first polygonal pillar and the second polygonal pillar,
A first compression facer formed to be inclined from the front to the rear outside and erected symmetrically;
It is connected to the left and right rear ends of the first compressed polyhedron, the support surface is standing vertically; And
It is connected to the left and right rear end of the support surface is formed to be inclined inward rearward, the second compression surface is symmetrically erected;
A first pressing point at which the first compressive face of the first polygonal body and the first compressive face of the second polygonal body cross each other; and
And a second pressing point at which the second compressed polyhedron of the first polygonal body and the second compressed polyhedron of the second polygonal body cross each other; symmetrically formed to balance the midsole. The method of claim 1,
A lower surface film layer disposed between the outsole and the first elastic restoring layer and having a light transmissive material; and
The midsole of the restoring force is improved, characterized in that it further comprises; an upper surface film layer of the light transmissive material disposed between the second elastic restoring layer and the upper. delete The method of claim 1,
A midsole having improved restoring force, characterized in that the first polygonal pillar and the second polygonal pillar are arranged to cross each other so that air passages connected to each other in the vertical direction, the horizontal direction, and the front-rear direction are formed. The method of claim 1,
A pressure support disposed at a position corresponding to the pressure point detected according to the plantar pressure analysis of the user and made of a hard material and inserted into an internal space of the first polygonal pillar and the second polygonal pillar; Midsole with improved resilience, characterized in that.

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