WO2010085032A2 - Shoe sole structure - Google Patents

Abstract

The present invention relates to a shoe sole structure, and more particularly, to a shoe sole structure comprising a main sole with a receiving space selectively formed at a front foot portion or a rear foot portion such that the receiving space becomes deeper as it goes toward the end of the front foot portion or toward the end of the rear foot portion, and an auxiliary sole which has a coupling surface with a slope identical to that of the bottom of the receiving space, and which is accommodated in the receiving space by enabling the coupling surface to be brought into contact with and coupled to the bottom of the receiving space. The auxiliary sole contracts during walking in order to selectively provide wearers with the effect of walking on an uphill or downhill road, or with the rolling effects of Masai walking, in accordance with the coupled location of the auxiliary sole.

Description

Brush structure of shoes

The present invention relates to a sole structure of a shoe, and more particularly, the present invention relates to a sole structure of a shoe. In particular, when standing, the heel is lowered so that the posture can be corrected, and when walking, on a flat surface. It can be implemented to have various effects such as climbing uphill or walking uphill and causing rolling, such as Masai walking, and it has excellent shock absorbing ability to protect joints and ankles and circulate air. It relates to the sole structure of the shoe that can implement a variety of functions to keep the interior of the shoe in a comfortable state.

Shoes are worn to protect the user's feet from external impacts caused by walking and driving. The shoes are different in appearance and structure depending on their purpose and place of use. In other words, when you go out lightly, you wear sandals, sneakers and shoes for everyday life, and special sports shoes for the sport.In recent years, various functional shoes have been widely used for special functions. to be.

In particular, in recent years, the public's interest in health has been increased, so that the walking on the flat surface and walking on the slope can be implemented to realize an effect such as walking by the wearing of specific shoes. In addition, functional shoes were being developed that can naturally produce rolling effects such as masai walking.

Such conventional functional shoes had a problem in that the structure was complicated and difficult to manufacture, and the function was simple as compared to the complicated configuration. Particularly, in the case of shoes for implementing Masai walking, shoes have been proposed to form the soles of the shoes with convex bottoms to implement the functions, but as the floors are convex, the ground area is small, so that the uphill or the downhill is especially When walking up and down stairs, it was difficult to walk properly, and there was a disadvantage that the appearance was quite unique, which attracted the attention of people, and thus, there was a problem that it was inconvenient to wear during daily life.

Furthermore, various configurations have been proposed to keep the interior of the shoe in a comfortable state by naturally supplying air into the shoe while walking. In order to implement a configuration capable of supplying air into the shoe in the conventional functional shoe as described above, Since a separate configuration such as a pocket was to be added, this caused additional problems such as complexity and difficulty in manufacturing.

The present invention is to solve the problems with the conventional functional shoes as described above, by forming the auxiliary sole in a specific form and then by placing it attached to the main sole in a variety of ways to walk flat and naturally walking uphill or downhill slopes Different effects and rolling effects,

In addition, by effectively absorbing the shock generated when walking or standing, it is possible to walk safely by distributing weight, and when walking, the auxiliary brush is compressed to naturally generate air and supply this air to the inside of the shoe. The purpose is to get a sole structure of the shoe to keep the shoes always comfortable.

The present invention implements a variety of effects, such as walking uphill or downhill while walking flat, and various effects such as rolling and rolling effects, and effectively absorb shocks when walking and circulate air to keep the interior of the shoe in a comfortable state To get the sole of the shoe,

A main sole for selectively forming a receiving space deeper toward the ends of the forefoot and the forefoot portion;

The auxiliary surface is formed in the receiving space is coupled to the bottom slope of the receiving space and the coupling surface is coupled to the bottom of the receiving space by being coupled to the receiving space;

According to the position where the auxiliary brush is coupled, the auxiliary sole contracts when walking, and thus the sole structure of a shoe that can selectively implement various effects such as walking uphill or downhill slopes and a rolling effect.

According to the invention,

By arranging and attaching an auxiliary brush with an air flow path to the main sole in various ways, it can realize various effects such as walking on an uphill or downhill slope while rolling flat and effectively absorbing the shock generated when walking. You will be able to get a shoe sole.

In addition, it is possible to obtain the sole of the shoe that can generate air naturally while walking and supply the inside of the shoe to keep the inside of the shoe in a comfortable state at all times.

In addition, by adjusting the placement position of the auxiliary sole, it is possible to easily implement the effect and the rolling effect, such as walking uphill or downhill slope, it is possible to easily manufacture the shoe sole according to the application by the assembly method.

1 and 2 is an exemplary view showing the configuration of a shoe sole for implementing the effect of climbing uphill slope by the present invention,

3 and 4 is an exemplary view showing a configuration according to another embodiment of the shoe sole for implementing the effect of climbing the uphill slope by the present invention,

5 and 6 is an exemplary view showing the configuration of a shoe sole for implementing the effect of walking downhill slope by the present invention,

7 and 8 is an exemplary view showing a configuration according to another embodiment of a shoe brush for implementing the effect of walking downhill slope by the present invention,

9, 10, 11, 12, 13 is an exemplary view showing the configuration of a shoe sole for implementing a rolling effect by the present invention,

14, 15, 16 is an exemplary view showing a configuration according to another embodiment of a shoe brush to implement the rolling effect by the present invention.

<Explanation of symbols for the main parts of the drawings>

100: main sole, 102: euro,

110: accommodation space, 200: auxiliary brush,

202: euro, 210: mating surface,

300: insole, 400: outsole.

Shoes sole according to the present invention is the main sole 100 and the elastic material accommodated in the accommodating space 110 is formed in the receiving space 110 in the forefoot or the forefoot. ) As the basic configuration. Here, the auxiliary brush 200 is formed by using a soft material compared to the main sole 100, so that it is easy to shrink when a load is applied when walking.

The accommodating space 110 is formed in such a manner that its depth is increased toward the forefoot or the forefoot from the middle foot of the main sole 100, and the bottom is inclined. In this case, the inclination of the bottom of the accommodation space 110 may be linearly constant, and may be formed by changing as necessary.

The auxiliary brush 200 has a coupling surface 210 having the same slope as the bottom slope of the receiving space 110, the coupling surface 210 is received by being coupled to the bottom of the receiving space 110 It is accommodated in the space 110. When the auxiliary brush 200 is accommodated as described above, the surface exposed to the outside forms the same plane as the upper or lower surface of the main sole 100 so that no protruding portion is provided to enable smooth walking.

On the other hand, the coupling surface 210 of the auxiliary brush 200 can form a space that can accommodate a certain degree of air. The space may also be formed in the form of a flow path 202. In the present invention, the flow path 202 is formed.

As the space to accommodate the air is formed on the coupling surface 210 as described above, when the auxiliary brush 200 is contracted under the load during walking, the air is supplied into the shoe along the flow path 202. In order for the air formed in the flow path 202 formed in the auxiliary brush 200 to be naturally supplied into the shoe, the main flow path 102 connected to the flow path 202 formed in the auxiliary brush 200 also in the main sole 100. It is necessary to form).

When the shoe sole according to the present invention configured as described above is applied to the shoe is attached to a separate outsole (outsole, 400) formed with a tread on the lower surface, it can be laid a separate insole 300 on the upper surface. When the insole 300 is laid, it is necessary to form a hole for supplying the insole 300 to the upper surface and the configuration in which air can flow.

Hereinafter, the configuration of the shoe sole according to the present invention configured as described above will be described for each embodiment.

Example 1 Implementation of Walking Uphill Slope

1 and 2 is an exemplary view showing a configuration of a shoe sole for implementing the effect of climbing the uphill slope according to the present invention, Figures 3 and 4 according to another embodiment of the shoe sole for implementing the effect of climbing uphill slope by the present invention An illustration showing the configuration.

As shown in the drawing, the accommodation space 110 is formed in the rear portion of the main sole 100 to realize an effect such as walking uphill. In this case, the accommodation space 110 may be selectively formed on the upper or lower surface of the rear portion.

1 and 2 when the receiving space 110 is formed on the upper surface of the rear portion of the main sole 100, the flow path 102 formed in the main sole 100 is the upper surface of the main sole 100 It will be formed in.

The auxiliary space 200 is accommodated in the accommodation space 110, the contact surface 210 in which the flow path 202 is formed to face downward to be coupled to the accommodation space 110.

When the auxiliary brush 200 is received and coupled to the receiving space 110 as described above, the contact surface 210 is in contact with the bottom of the receiving space 110, the flow path 202 formed in the auxiliary brush 200 and the main brush ( The flow paths 102 formed in the 100 are connected to each other to supply air generated when walking to the inside of the shoe.

In contrast to the above, as shown in FIGS. 3 and 4, the receiving space 110 may be formed on the lower surface of the main sole 100. In this case, the flow path 102 formed in the main sole 100 is formed to have a lower surface. The flow path 102 penetrates the upper surface of the main sole 100 so that the air can be supplied into the shoe.

When the receiving space 110 is formed on the lower surface of the main sole 100 as described above, the auxiliary brush 200 is coupled to the receiving space 100 with the contact surface 210 facing upward.

When the shoe brush according to the present invention configured as described above is applied to a shoe, when the load is applied to the rear portion of the foot when walking, the auxiliary brush 200 contracts and the heel becomes lower than the front heel, walking uphill slope. You will achieve the same effect.

Example 2 Implementing the Effect of Walking Downhill Slope

5 and 6 is an exemplary view showing the configuration of the shoe sole for implementing the effect of walking downhill slope by the present invention, Figures 7, 8 are in another embodiment of the shoe sole for implementing the effect of walking downhill slope by the present invention It is an exemplary view showing the configuration according to.

As shown, in order to implement an effect such as walking downhill slope, the receiving space 110 is formed in the forefoot portion of the main sole 100. In this case, the accommodation space 110 may be selectively formed on the upper or lower surface of the forefoot portion.

As shown in FIGS. 5 and 6, when the accommodation space 110 is formed on the upper surface of the forefoot of the main sole 100, the flow path 102 formed on the main sole 100 is disposed on the upper surface of the main sole 100. Will be formed.

The auxiliary space 200 is accommodated in the accommodation space 110, the contact surface 210 in which the flow path 202 is formed to face downward to be coupled to the accommodation space 110.

When the auxiliary brush 200 is accommodated and coupled to the receiving space 110 as described above, the contact surface 210 is in contact with the bottom of the receiving space 110, the flow path 202 formed in the auxiliary brush 200 and the main brush ( The flow paths 102 formed in the 100 are in communication with each other to supply air generated when walking into the shoe.

On the contrary to the above, as shown in FIGS. 7 and 8, the accommodation space 110 may be formed on the lower surface of the main sole 100. In this case, the flow path 102 formed in the main sole 100 is formed to have a lower surface. The flow path 102 penetrates the upper surface of the main sole 100 so that the air can be supplied into the shoe.

When the receiving space 110 is formed on the lower surface of the main sole 100 as described above, the auxiliary brush 200 is coupled to the receiving space 100 with the contact surface 210 facing upward.

When the shoe brush according to the present invention configured as described above is applied to a shoe, when the load is applied to the forefoot portion during walking, the auxiliary brush 200 contracts and the heel is lower than the heel, and walking downhill slope. The same effect is achieved.

Example 3 Rolling Effect

9, 10, 11, 12, 13 is an exemplary view showing a configuration of a shoe sole for implementing a rolling effect according to the present invention, Figures 14, 15, 16 is another embodiment of a shoe sole for implementing a rolling effect according to the present invention It is an exemplary view showing a configuration according to.

As shown, in order to implement a rolling effect by generating a natural roll when walking, the receiving space 110 is formed in both the forefoot portion and the rear portion of the main sole 100. In this case, the accommodation space 110 may be selectively formed on the upper or lower surface of the forefoot portion.

9, 10, and 11, when the receiving space 110 is formed on the lower surface of the forefoot portion and the forefoot portion of the main sole 100, the flow path 102 formed in the main sole 100 is the main sole ( It is formed on the lower surface of 100).

The auxiliary space 200 is accommodated in the accommodation space 110, the contact surface 210 in which the flow path 202 is formed faces upward and is coupled to the accommodation space 110.

When the auxiliary brush 200 is received and coupled to the receiving space 110 as described above, the contact surface 210 is in contact with the bottom of the receiving space 110, the flow path 202 formed in the auxiliary brush 200 and the main brush ( The flow paths 102 formed in the 100 are in communication with each other to supply air generated when walking into the shoe.

Here, the same rolling effect may be realized even if the formation position of the accommodation space 110 is different from that described above.

That is, as shown in FIGS. 12 and 13, the accommodation spaces 110 may be formed in diagonal directions with each other. More specifically, as shown in FIG. 12, the accommodation space 110 may be formed on the bottom surface of the forefoot portion of the main sole 100 and on the top surface of the rear foot portion. In this case, in the forefoot part, the contact surface 210 faces upward, and in the forefoot part, it is inserted into the accommodation space 110 to be coupled.

On the contrary, as shown in FIG. 13, the accommodating space 110 may be formed on the upper surface of the forefoot portion of the main sole 100 and on the lower surface of the rear portion of the main sole 100. In all cases, the same rolling effect can be realized.

14 and 15, the auxiliary brush 200 coupled to the receiving space 110 formed in the forefoot and the forefoot may be connected to each other. In this case, it is possible to form the position where the accommodation space 110 is formed on the bottom surface of the main sole 100 and on the top surface.

In the case where the position of the receiving space 110 is formed on the lower surface of the main sole 100, the main sole 100 is formed in the flow path 202 formed in the auxiliary brush 200 by forming a hole penetrated upwardly. When the air is directly supplied into the shoe, and when the position of the receiving space 110 is formed on the upper surface of the main sole 100, the flow path 202 is formed by forming a hole penetrating upward through the auxiliary brush 200. The air in) is fed directly into the shoe.

When the shoe brush according to the present invention configured as described above is applied to a shoe, the foot comes in contact with the ground in turn from the heel to the heel in turn. By doing so, Masai walking is naturally implemented.

According to the present invention described above, the receiving space 110 is formed in the main sole 100, the position is formed in various ways as needed, and the auxiliary brush 200 is inserted into the receiving space 110 is cut By assembling, you will be able to easily and easily implement the effect of walking uphill and downhill slopes and the rolling-inducing composition as you do with Masai Walking.

Claims (6)

1. The main sole 100 is formed in the receiving space 110 is deeper toward the end in one of the forefoot and the forefoot portion;

   A coupling surface 210 having the same slope as the bottom slope of the accommodation space 110 is formed so that the coupling surface 210 is coupled to the bottom of the accommodation space 110 to be accommodated in the accommodation space 110 Brush 200; consists of,

   The sole structure of the shoe, characterized in that configured to implement an effect such as walking the uphill or downhill slope by walking the auxiliary brush 200 according to the position where the auxiliary brush 200 is coupled.
2. According to claim 1,

   The accommodating space 110 is a sole structure of a shoe, characterized in that formed in one of the upper and lower surfaces of the forefoot and rearfoot.
3. A main sole 100 having an accommodating space 110 having a deeper depth toward the ends of the forefoot and the forefoot portion;

   Auxiliary brush is formed in the receiving space 110 is formed by the coupling surface 210 having the same slope as the bottom slope of the receiving space 110 is coupled to the bottom of the receiving space 110 in contact with the receiving space 110 200, consisting of

   Sole structure of the shoe, characterized in that configured to implement a rolling effect around the midfoot as the auxiliary brush 200 is contracted during walking.
4. The method of claim 3, wherein

   The accommodating space 110 is a sole structure of a shoe, characterized in that formed on the same side up and down from the forefoot portion and the rear portion of the main sole 100.
5. The method of claim 3, wherein

   The accommodating space 110 is a sole structure of a shoe, characterized in that formed on the opposite surface up and down from the forefoot and the rear portion of the main sole 100.
6. The method according to any one of claims 1 to 5,

   The coupling surface 210 of the auxiliary brush 200 is formed by the air flow path 202 is connected to the flow path 102 formed in the main sole 100 to generate air when walking to supply the inside of the shoe The sole structure of the shoe characterized by.

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