KR100641278B1 - Functional insole and manufacturing method - Google Patents

Abstract

Provided is a functional insole designed three-dimensionally in consideration of ergonomic and kinematical aspects to maximize wearing sensations and to thereby minimize fatigue of feet. The functional insole comprises a woven layer(11) absorbing sweat and preventing skid; a sub-cushion layer(12) absorbing shock or impact on the heel; a main synthetic resin layer(15) consisting of a first main synthetic resin layer(13) of low hardness(about C35 or lower) and a med-hardness second main synthetic resin layer(14) of medium hardness(about C3 to C65) for supporting a foot; a sub-synthetic resin layer(16); and a main cushion layer(19) consisting of a front sole main cushion layer(17) and a heel main cushion layer(18) for absorbing impact upon the front sole portion and the heel. The main and the sub synthetic resin layers(15,16) have protrusions(13a,14a,16a) providing massage stimuli to a user for relieving fatigue of feet.

Description

Functional insole and its manufacturing method {FUNCTIONAL INSOLE AND MANUFACTURING METHOD}

1, 2 is a perspective view of a functional insole in accordance with the present invention.

3 is a perspective view of a functional insole separating the main shock absorbing layer from the main synthetic resin layer and the sub synthetic resin layer of FIG.

4 is a front view of a functional insole in accordance with the present invention.

5 is a rear view of the functional insole in accordance with the present invention.

6 is an exploded perspective view of a functional insole in accordance with the present invention.

7 is a flow chart showing a process for producing a functional insole according to the present invention.

* Explanation of symbols for main parts of the drawings

10: functional insole 11: weaving layer

12: sub shock absorbing layer 13: the first main synthetic resin layer

14: second main synthetic resin layer 15: main synthetic resin layer

16: sub synthetic resin layer 17: the forefoot main shock absorbing layer

18: heel main shock absorbing layer 19: main shock absorbing layer

13a, 14a, 15a: protrusion 15a: seating groove

16b: grid pattern 16c: seating hole

The present invention relates to a functional insole and a method for manufacturing the same, and more particularly, to a functional insole and a method for manufacturing the same in consideration of the anatomical characteristics and kinematic aspects of the foot.

Insoles used in shoes are suitable for the characteristics required for each part of the foot according to walking or movement characteristics in order to normally perform functions such as cushion, support, and rebounding. It is necessary to manufacture by laminating at least 4 to 5 layers using the material. However, most conventional insoles have a problem in that they are manufactured not in conformity with the actual shape of the foot as a planar form of two-dimensional shape stacked in two to three layers without considering the anatomical features of the foot.

Meanwhile, with the recent increase in income levels and well-being trends, increasing interest in health has led to an increase in the number of people who enjoy jogging, marathon, golf, and mountaineering. It's growing. However, the conventional method for manufacturing a high functional insole has a problem in that the production cost is complicated by the production process is complicated by injection molding and foaming a variety of different layers to increase the production cost.

Accordingly, the present invention has been made to solve the above problems, and an object thereof is to provide a functional insole designed in three dimensions in consideration of ergonomic and kinematic aspects.

Another object of the present invention is to provide a method for producing a functional insole that can lower the production cost by stacking a variety of different layers by press molding.

Functional insole used in the shoe according to the present invention to achieve the above object, the woven layer to prevent the absorption and slip of sweat, the main synthetic resin layer laminated on one surface of the woven layer to support the foot, and Sub synthetic resin layer laminated on one side of the main synthetic resin layer to support the foot arch area of the foot, and forefoot main shock absorbing layer laminated on one surface of the sub synthetic resin layer to absorb the impact applied to the forefoot region of the foot and the heel portion of the foot. The paper is characterized in that it comprises a main shock absorbing layer having a heel main shock absorbing layer to absorb the impact.

Here, a sub-shock absorbing layer for absorbing the impact applied to the foot and heel portion of the foot between the woven layer and the main synthetic resin layer may be further laminated, and the sub-shock absorbing layer and the main shock absorbing layer is a polyurethane or polyethylene-based It may be formed of a material.

The main synthetic resin layer is made of one layer formed of a low hardness (C35 or less) EVA material, or each of two layers formed of a low hardness (C35 or less) EVA material and a medium hardness (C35 ~ C65) EVA material Can be done. In addition, the sub-synthetic resin layer may be formed of a comb-toothed fan-shaped grid pattern using grooves to support smooth foot movement while supporting the foot arch as a medium material (C35 to C65) or high hardness (C65 or more). Can be.

The main synthetic resin layer and the sub-synthetic resin layer may be formed with a protrusion for pressing the front portion of the foot arch portion of the foot. And, the main synthetic resin layer is formed with a seating groove for seating the main shock absorbing layer of the forefoot of the main shock absorbing layer, the sub-synthetic resin layer is formed with a mounting hole for the seat of the heel main shock absorbing layer of the main shock absorbing layer Can be.

On the other hand, the method for producing a functional insole used in the shoe according to the present invention in order to achieve the above object, the first synthetic resin layer for supporting the foot on one side of the woven layer to prevent sweat absorption and slipping A first step, and a second step of laminating a sub-synthetic resin layer supporting the foot arch portion of the foot on one surface of the laminated body laminated through the first step, and the forefoot of the foot on one surface of the laminated body laminated through the second step And a third step of laminating the main shock absorbing layer to absorb the impact applied to the portion and the heel portion.

Here, in the first step, the main synthetic resin layer may be laminated on one surface of the laminate after laminating a sub-shock absorbing layer that absorbs the impact applied to the foot and heel portions of the foot on one surface of the weave layer. The sub-shock absorbing layer may be laminated after the gauge through sublimation transfer is made to select the stacking position of the sub-impact absorbing layer on the woven layer.

The second step may be laminated by a method of press molding after inserting the sub-synthetic resin layer and the laminated body laminated through the first step into a lamination press mold, and the sub-synthetic resin layer may be a press for cutting After press molding in a mold and cutting to fit the shape of the gauge, it can be inserted into the lamination press mold.

In the third step, after the laminate laminated through the second step is cut to fit the gauge shape and size, the main shock absorbing layer may be laminated on one surface of the laminate.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 and 2 are perspective views of the functional insole according to the present invention, Figure 3 is a perspective view of the functional insole separated from the main shock absorbing layer in the main synthetic resin layer and the sub synthetic resin layer of Figure 2, Figure 4 is a functional insole according to the present invention 5 is a rear view of the functional insole according to the present invention, and FIG. 6 is an exploded perspective view of the functional insole according to the present invention.

As shown in the figure, the functional insole 10 absorbs sweat and prevents slippage, and is laminated on one surface of the weave layer 11 to absorb shocks applied to the foot and heel portions of the foot. It is laminated on one surface of the sub-shock absorbing layer 12 and the sub-shock absorbing layer 12, and consists of a low hardness first main synthetic resin layer 13 and a medium hardness second main synthetic resin layer 14 to support the foot. A main synthetic resin layer 15, a sub synthetic resin layer 16 laminated on one surface of the main synthetic resin layer 15 to support the foot arch portion of the foot, and a sub synthetic resin layer 16 laminated on one surface of the forefoot main The shock absorbing layer 17 and the heel main shock absorbing layer 18 are provided to include a main shock absorbing layer 19 for absorbing the shock applied to the forefoot portion and the heel portion of the foot.

The hardness is the hardness of the object, which means the local resistance that appears when indenting the surface of the object under a constant load. Thus, elastic and plastic resistance is indicative of the strength of the material. In the present invention, low hardness means about C35 or less, medium hardness means about C35 to C65, and high hardness means about C65 or more.

The woven layer 11 absorbs sweat and prevents slipping as a woven material. The antimicrobial, anti-odor, and PCM (Phase Change Material) coating can control the temperature of the foot.

The sub-shock absorbing layer 12 is a material such as polyurethane or polyethylene-based material is disposed in the foot arch area and the heel area to primarily absorb the impact on the foot during the landing of the foot. In particular, by using a soft, low-hard material, it is possible to adjust the temperature of the foot by the air flow inside by improving the air permeability by the role of the air cushion (circulation structure of the air by the action of the pump by the landing of the foot).

The main synthetic resin layer 15 is a foamed EVA (Ethylene Vinyl Acetate) material in which a synthetic resin material is copolymerized with ethylene and vinyl acetate, and the first main synthetic resin layer 13 having a low hardness and the second main synthetic resin having a medium hardness Layer 14 to support the foot as a whole. Here, when the degree of supporting the foot is relatively weak, only the first main synthetic resin layer 13 may be laminated except for the second main synthetic resin layer 14.

The sub-synthetic resin layer 16 is a medium hardness (C35 ~ C65) or high hardness (C65 or more) of the EVA material to support the foot of the three-dimensional foot arch, the hardness according to the cushion and movement characteristics, foot height and shape of the foot It can be applied differently. In addition, the sub-synthetic resin layer 16 may be formed with a comb-tooth fan-shaped grid pattern 16b using grooves so as to support the foot arch portion more effectively while smoothly moving the foot.

In this case, even when used for a long time, the three-dimensional structure for supporting the foot portion is not easily collapsed so that the high hardness synthetic resin is applied to enable continuous support. However, when the high-hard synthetic resin is applied, the foot arch of the foot can not be flexibly responded to moving up and down like a spring, and the foot can be tired because it cannot effectively absorb the impact on the foot. Therefore, the grid pattern structure is formed to effectively support the foot arch area of the foot and to flexibly move according to the vertical movement of the foot arch.

The main shock absorbing layer 19 is made of a material such as polyurethane or polyethylene-based, and consists of a forefoot main shock absorbing layer 17 and a heel main shock absorbing layer 18 on the forefoot part and the heel part having the highest load distribution. Absorbs the shocks applied. In other words, the foot is walked by the heel part touching the ground first, supported by the footbow area, and repulsion by the forefoot part when walking. Therefore, it absorbs the impact on a heel part and a forefoot part.

In the main synthetic resin layer 15 and the sub synthetic resin layer 16, predetermined protrusions 13a, 14a, and 16a for pressing the front part of the foot arch area of the foot where various nerves are present are formed. Can be. Therefore, fatigue can be released by applying a constant stimulus through the protrusions 13a, 14a, 16a.

In addition, the main synthetic resin layer 15 is provided with a seating groove 15a having a shape capable of correctly seating and stacking the main shock absorbing layer 17 of the forefoot of the main shock absorbing layer 19, and the sub synthetic resin layer 16 ) Has a good cushioning function and a shape in which the heel main shock absorbing layer 18 of the main shock absorbing layer 19 can be properly seated and stacked, that is, a hole having a hole except for an adhesive part with the main shock absorbing layer 18. 16c may be formed.

7 is a flowchart illustrating a process of manufacturing a functional insole according to the present invention. As shown, first, a gauge through sublimation transfer is created to select a stacking position of a sub-shock absorbing layer that absorbs the shock applied to the foot and heel portions of the foot on the woven layer that prevents sweat absorption and slipping, and then weaves The sub shock absorbing layer is laminated on one surface of the layer to be bonded and bonded (S11) (S12).

Here, the sub-shock absorbing layer needs to be cut into a predetermined shape and sharply processed at the edges so as to increase the adhesion with the soles before lamination.

Subsequently, the main synthetic resin layer supporting the feet is laminated and bonded and bonded to one surface of the laminated body laminated through the steps S11 and S12 (S13).

Subsequently, the sub-synthetic resin layer supporting the foot arch portion of the foot in the lamination press mold and the laminated body laminated through the step S13 are inserted and press-molded to laminate and bond the sub-synthetic resin layer to the laminate (S14). At this time, the laminate and the sub-synthetic resin layer are adhered to each other by press bonding to the sub-synthetic resin layer in advance.

Here, the sub-synthetic resin layer is required to be cut in accordance with the shape of the gauge after inserting and pressing the cutting into the cutting press mold before inserting into the lamination press mold. At this time, the sheet is inserted into the lamination press die in accordance with the guide pin hole of the sub-synthetic resin layer formed at the time of insert press, and is positioned at the time of molding.

Finally, after the laminate laminated in step S14 is cut to fit the gauge shape and size, the main shock absorbing layer absorbs the shock applied to the forefoot portion and the heel portion having the highest load distribution on one surface of the laminate. Laminating and bonding (S15).

Meanwhile, although the functional insole and the manufacturing method thereof according to the present invention have been described according to the limited embodiments, the scope of the present invention is not limited to the specific embodiments, and is obvious to those skilled in the art in connection with the present invention. Various alternatives, modifications and changes can be made within the implementation.

According to the present invention, it is possible to minimize the fatigue of the foot by improving the fit of the foot by designing in three dimensions. In addition, by stacking and producing a plurality of layers by press molding, it is possible to secure the competitiveness by reducing the production cost by simplifying the production process.

Claims (14)

In insoles used in shoes, A woven layer for preventing sweat absorption and slipping; A main synthetic resin layer laminated on one surface of the woven layer to support the foot; A sub-synthetic resin layer laminated on one surface of the main synthetic resin layer to support the foot arch portion of the foot; A main shock absorbing layer laminated on one surface of the sub-synthetic resin layer and having a main shock absorbing layer for absorbing the impact applied to the forefoot portion of the foot and a heel main shock absorbing layer for absorbing the impact applied to the heel portion of the foot. Functional insole, characterized in that. The method of claim 1, Functional insole, characterized in that further laminated between the woven layer and the main synthetic resin layer to absorb the impact applied to the foot and heel portion of the foot. The method of claim 2, The sub shock absorbing layer and the main shock absorbing layer is a functional insole, characterized in that formed of a polyurethane or polyethylene-based material. The method according to any one of claims 1 to 3, The main synthetic resin layer is functional insole, characterized in that consisting of one layer formed of a low hardness (C35 or less) EVA material. The method according to any one of claims 1 to 3, The main synthetic resin layer is functional insole, characterized in that each consisting of two layers formed of a low hardness (C35 or less) EVA material and a medium hardness (C35 ~ C65) EVA material. The method according to any one of claims 1 to 3, The sub-synthetic resin layer is formed of an EVA material of medium hardness (C35 to C65) or high hardness (C65 or more) to form a comb-toothed fan-shaped grid pattern using grooves to support smooth foot movement while supporting the foot arch area. Functional insole. The method according to any one of claims 1 to 3, Functional insole, characterized in that the main synthetic resin layer and the sub-synthetic resin layer is formed with a protrusion for pressing the front portion of the foot portion of the foot arch. The method according to any one of claims 1 to 3, The main synthetic resin layer has a seating groove for seating the main shock absorbing layer of the front foot of the main shock absorbing layer is formed, the sub-synthetic resin layer is characterized in that the seat hole for seating the main shock absorbing layer of the heel of the main shock absorbing layer is formed. Functional insole. In the method of manufacturing the insole used in shoes, A first step of laminating the main synthetic resin layer supporting the foot on one surface of the woven layer to prevent sweat absorption and slipping; A second step of laminating a sub-synthetic resin layer supporting the foot arch area of the foot on one surface of the laminated body laminated through the first step; And a third step of laminating a main shock absorbing layer on one surface of the laminated body laminated through the second step to absorb the impact applied to the forefoot portion and the heel portion of the foot. The method of claim 9, In the first step, the functional insole is manufactured by laminating a main impact absorbing layer on one surface of the woven layer to absorb the impact applied to the foot and heel portions of the foot, and then laminating the main synthetic resin layer on one surface of the laminate. Way. The method of claim 10, And a sub shock absorbing layer is laminated on the woven layer after creating a gauge through sublimation transfer to select the stacking position of the sub shock absorbing layer. The method of claim 9, The second step is a method for manufacturing a functional insole, characterized in that the press molding after inserting the sub-synthetic resin layer and the laminated body laminated through the first step in the lamination press die. The method of claim 12, The sub-synthetic resin layer is press-molded in a cutting press mold and cut to fit the shape of the gauge and then inserted into the lamination press mold. The method of claim 9, In the third step, after the laminated body laminated through the second step according to the shape and size of the cut to the main shock absorbing layer characterized in that to laminate the main shock absorbing layer on the surface.

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