KR20180062613A - Shoe Insole Using Graphite Sheet - Google Patents

Abstract

The present invention relates to a shoe insole using an expansion graphite sheet which can facilitate blood circulation of a foot. The shoe insole includes a heat conduction sheet (20) inserted between an EVA sponge (10) and FE fiber and restoration sponge (30) to affix the heat conduction sheet (20). The heat conduction sheet (20) has a fluorine film (22) affixed to both sides of an expansion graphite sheet (also referred to as graphite) (21). A seam (221) of the heat conduction sheet (20) is backstitched along an edge by a sewing line (222). The seam (21) is finished in a C-shape and then sewn on a middle portion by polytetrafluoroethylene (PTFE) yarn to form the sewing line (222). Another embodiment of the heat conduction sheet (20) may be manufactured in a multi-layer structure by inserting a carbon fiber sheet (23) between two expansion graphite sheets to which a fluorine film (22) is affixed.

Description

{Shoe Insole Using Graphite Sheet}

The present invention relates to a shoe insole such as a shinto shoe, ladies shoe, boots, combat shoes, hiking boots, running shoes and the like. More specifically, the present invention relates to a shoe insole capable of maintaining the temperature difference between the front and the heel of the foot as uniform as possible, thereby improving the blood circulation of the foot.

The foot consists of 52 bones, 66 joints, 40 muscles, and 82 ligaments. It is the foundation stone of the human body, which is delicately harmonized with numerous nerves and blood vessels. If one of them is wrong, the foot feels painful and the gait becomes strange. In addition, many nerves are distributed in the foot. If you stimulate the nerves in your feet, you will feel that your head is clear and your stress is relieved. For this reason, foot massage therapy is widely used worldwide for its treatment.

We can preserve our healthy feet if we pay little attention to our feet in our everyday lives. It is very important for healthy body to calibrate the foot to fit your feet to keep your weight to fit your health so that your feet are not crowded and to keep your feet from falling. When walking, feet take 80% of their weight, so they weigh about 16 t when walking 1 km. On the other hand, feet and legs are called 'second heart' because they act to raise blood to the heart when walking. The foot supports weight and provides the driving force and direction required to move the body. Thereby absorbing physical impact, maintaining balance in response to adaptation to the ground and body center of gravity, and at the same time maintaining the safety of the foot.

If the blood circulation is worse because it is the farthest from the heart, cold blood circulation, cold hands and feet. In addition, the foot plays an important role in moving the body to the bottom of the human body, and often the management is neglected because it is not the exposed part or the body has to bend.

Especially for women, feet are associated with female specific physiological causes, such as a slow heart rate and slow blood circulation. Almost all women have low abdominal coldness and hands and feet are cold feet. Clinical observations show that women have many varicose veins associated with pregnancy. Even among women and men who are not pregnant, fewer varicose veins are found to be caused by poor blood circulation because they do not exercise normally. In addition, women prefer high-heeled heels because they attach importance to appearance and fashion. In the case of high heels, the heel of the back part is high and the temperature difference is 4-5 ℃ below the front foot temperature.

There are many men who sweat a lot on foot, and women who have a lot of feet. It does not mean that a man does not have a foot, but his foot is related to the heart. If you look at people with warm hands and feet, there is no other disease in the heart and blood circulation is good. However, it is difficult for modern people to devote time to exercise because of work life and business.

The present inventor has developed a winter footwear which can be applied to shoes such as combat boots, hiking boots, sneakers, etc., and can keep warm feet by blocking cold air from the ground during winter season. Filed on August 8).

In the present invention, the shoe insole of the present invention has been developed for the purpose of improving the circulation of the feet in walking, driving, and the like in the workplace, commuting route, and the like. The results showed that the temperature of the front part of the foot and the heel differed by about 2 ~ 5 ℃ when wearing most shoes including the shrine. Generally, the front part of the foot is about 2 ~ 5 ℃ higher than the heel. It is presumed that the temperature difference of these feet is due to the poor circulation of blood. Therefore, the inventor of the present invention has developed a new shoe insole of the present invention which can improve the health by reducing the temperature difference between the front and the heel of the foot by improving the blood circulation of the foot by adding a heat conduction function to the shoe insole, ).

SUMMARY OF THE INVENTION It is an object of the present invention to provide a new shoe insole which can improve the circulation of the foot by making the temperature difference between the front part and the heel of the shoe uniform.

Another object of the present invention is to provide various shoe insole with a simple manufacturing process and an inexpensive manufacturing cost so that foot circulation can be improved by using heat conduction to keep feet warm.

These and other objects of the present invention can be achieved by the present invention which is described in detail below.

Most of the shoe insole is made of EVA (Ethylene Vinyl Acetate Copolymer) sponge, PE (polyethylene) fiber and restoration sponge. The shoe insole of the present invention is formed by inserting and bonding a thermally conductive sheet 20 between an EVA sponge 10 and a PE fiber and a restoration sponge 30. The thermally conductive sheet 20 is an expanded graphite sheet (also referred to as graphite) And a fluorine film 22 is adhered to both surfaces of the substrate 21.

The heat conductive sheet 20 is stuck to the sewing line 222 along the edge thereof. The seam part 21 is closed in a " C " shape, and then sewed with a thread of PTFE (Polytetrafluoro Ethylene) at an intermediate portion to form a sewing line 222.

As another specific example of the heat conduction sheet 20, a carbon fiber sheet 23 may be inserted between two sheets of expanded graphite sheet to which the fluorine film 22 is adhered to produce a multilayer structure. The heat conductive sheet 20 in this case is also stitched to the sewing line 222 along the edge thereof. The seam portion 21 is closed in a " C " shape, and then sewed in a PTFE chamber in the middle portion to form a sewing line 222.

The expanded graphite sheet 21 has a low thermal conductivity in the Z axis and a high thermal conductivity in the X and Y axes, that is, a high thermal conductivity in the plane direction, thereby eliminating the temperature difference between the front and the heel of the shoe, thereby improving the circulation of the foot. Can be manufactured. The heat conductive sheet 20 is inserted between the EVA sponge 10 of the shoe insole 100 and the PE fiber and the restoration sponge 30 so that the thermal conductivity as the characteristic of the expanded graphite is used, And it is possible to improve the health of the foot by improving the circulation of the feet by eliminating the temperature difference between the front part and the heel of the shoe by utilizing the fact that the thermal conductivity transmitted through the X axis and the Y axis becomes larger and the specific resistance value becomes smaller.

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

The present invention provides an insole capable of improving the health by improving the blood circulation of the foot by eliminating the temperature difference by the isothermal effect according to the temperature environment change of the front and back of the shoe, The present invention has the effect of providing an insole for various shoes such as shoes, hiking boots, running shoes and the like.

1 is a schematic perspective view of an insole 100 used in a shoe.
FIG. 2 is a schematic exploded perspective view of FIG. 1, illustrating the internal structure of the shoe insole 100 according to the present invention.
Fig. 3 is a perspective view of a shoe insole 100 according to the present invention, in which a seam base 21 is closed in a " C " FIG.
4 is a schematic cross-sectional view showing the cross-sectional structure of the heat conduction sheet 20 of the present invention.
5 is a schematic cross-sectional view showing a cross-sectional structure of a thermally conductive sheet of another embodiment having a multilayer structure by inserting a carbon fiber sheet 23 between two sheets of expanded graphite sheets to which a fluorine film 22 is bonded.

The present invention relates to an insole of a shoe such as a shrine, a ladies boots, a long boots, a combat boots, a hiking boots, a sneaker, and the like, and reduces the temperature difference between the front and the back of the foot to improve the health by smoothly circulating the foot. The present invention provides a shoe insole for inserting a heat conductive sheet (20) using an expanded graphite sheet (21) in the middle of an insole of a shoe to provide a shoe insole for reducing ignition, walking, It is to improve health by improving blood circulation.

Most of the shoe insole is made by bonding EVA (Ethylene Vinyl Acetate Copolymer) sponge, PE fiber and restoration sponge, and it is bonded to the bottom of shoe to complete shoes. The shoe insole of the present invention is formed by inserting and bonding a thermally conductive sheet 20 between an EVA sponge 10 and a PE fiber and a restoration sponge 30. The thermally conductive sheet 20 is an expanded graphite sheet (also referred to as graphite) And a fluorine film 22 is adhered to both surfaces of the substrate 21. Fig. 1 is a schematic perspective view of an insole 100 used in a shoe, and Fig. 2 is a schematic exploded perspective view of Fig. 1, illustrating an internal structure of a shoe insole 100 according to the present invention.

Fig. 3 is a perspective view of a shoe insole 100 according to the present invention, in which a seam base 21 is closed in a " C " FIG. The heat conductive sheet 20 is stuck to the sewing line 222 along the edge thereof. The seam portion 21 is closed in a " C " shape, and then sewn into a thread of PTFE at an intermediate portion to form a sewing line 222. [ 4 is a schematic cross-sectional view showing the cross-sectional structure of the heat conduction sheet 20 of the present invention.

As another specific example of the heat conduction sheet 20, a carbon fiber sheet 23 may be inserted between two sheets of expanded graphite sheet to which the fluorine film 22 is adhered to produce a multilayer structure. 5 is a schematic cross-sectional view showing a cross-sectional structure of a thermally conductive sheet of another embodiment having a multilayer structure by inserting a carbon fiber sheet 23 between two sheets of expanded graphite sheets to which a fluorine film 22 is bonded. The heat conductive sheet 20 in this case is also stitched to the sewing line 222 along the edge thereof. The seam portion 21 is closed in a " C " shape, and then sewed in a PTFE chamber in the middle portion to form a sewing line 222.

The expanded graphite sheet 21 has a low thermal conductivity in the Z axis and a high thermal conductivity in the X and Y axes, that is, a high thermal conductivity in the plane direction, thereby eliminating the temperature difference between the front and the heel of the shoe, thereby improving the circulation of the foot. Can be manufactured. The heat conductive sheet 20 is inserted between the EVA sponge 10 of the shoe insole 100 and the PE fiber and the restoration sponge 30 so that the thermal conductivity as the characteristic of the expanded graphite is used, And it is possible to improve the health of the foot by improving the circulation of the feet by eliminating the temperature difference between the front part and the heel of the shoe by utilizing the fact that the thermal conductivity transmitted through the X axis and the Y axis becomes larger and the specific resistance value becomes smaller.

The expanding graphite sheet has a low thermal conductivity in the Z axis and has a high thermal conductivity in the X and Y axes, that is, in the plane direction. Thus, the body heat of the front part of the foot and the heat due to the gait operation are transferred to the heel of the foot, The temperature difference between the front and the back of the foot is reduced by the isothermal effect formed by the thermal conduction repetitive motion for moving the heat forward, thereby improving the blood circulation.

The expanded graphite sheet (21) used in the present invention can be purchased commercially, and has a thickness of 0.2 mm, 0.5 mm or 1.0 mm. The physical properties of the expanded graphite sheet having a thickness of 0.2 mm and 0.5 mm preferably satisfy the following ranges.

It is preferable that the expanded graphite sheet has a plane direction thermal conductivity of 200 to 300 w / mk, a thermal conductivity in the thickness direction of 5 to 9 w / mk, a plane direction specific resistance of 6 to 7 μΩm and a thickness direction specific resistance of 1000 to 1300 μΩm Do.

The insole-shaped heat conductive sheet 20 made of the expanded graphite sheet 21 is inserted between the EVA sponge 10 of the insole of the shoe and the PE fiber and the restoration sponge 30 to integrally adhere thereto but is deformed or torn It is easy to get rid of. Since the shoe always receives a large load by its weight, such deformation or rupture can easily occur, and the expanded graphite sheet 21 generally has a weak brittleness. In order to compensate for this, the fluorine film 22 is further adhered to both surfaces of the expanded graphite sheet 21.

The fluorine film 22 may be a commercially available film having a thickness of about 10 탆. The fluorine film can be easily adhered to the expanded graphite sheet 21 using an adhesive. The fluorine film has high compressive and tensile strength and good flexibility to reinforce the brittleness of the expanded graphite sheet 21 and prevent deformation.

Further, in the present invention, the carbon fiber sheet 23 may be inserted between two sheets of the expanded graphite sheet to which the fluorine film 22 is adhered to form a multilayer structure. 5 is a schematic cross-sectional view showing a cross-sectional structure of a cold-weather sheet of another embodiment made of a multilayer structure by inserting a carbon fiber sheet 23 between two sheets of expanded graphite sheet to which a fluorine film 22 is adhered.

The carbon fiber sheet 23 is preferably woven carbon fiber, and preferably has a thickness of 0.1 to 0.12 mm. The carbon fiber sheet is used to complement the flexibility and brittleness of the expanded graphite sheet and reinforce durability.

The present invention can be better understood by the following examples, and the following examples are for illustrative purposes only and are not intended to limit the scope of protection of the claims.

Example

The temperature measured at the front part of the left foot wearing socks at 20.9 ℃ was 32.1 ℃ ~ 31.4 ℃ and the temperature of the back part was 29.8 ℃ ~ 29.6 ℃ and the temperature difference was 2.3 ℃ ~ 1.8 ℃. The left side and the right side of the ready-made article were prepared. The left side was fitted with a conventional myth and the right side was fitted with an insole having a thermally conductive sheet inserted 0.5 mm between the EVA sponge and the PE fiber and the restoration sponge.

Temperature measurement : The temperature of the front and rear surfaces of the insole was measured 10 times by infrared thermometer before and after walking for 30 minutes. The average temperature of the front of the insole was 31.9 ℃ 27.6 ° C, the average temperature at the rear part was 27.3 ° C to 26.3 ° C, the average temperature at the front part of the right side where the expanded graphite sheet was bonded was 30.7 ° C to 27.7 ° C and the average temperature at the rear part was 30.4 ° C to 27.8 ° C Respectively. That is, in the embodiment of the present invention, when the expanded graphite sheet, which is a thermally conductive sheet, is attached to the insole, when the expanded graphite sheet is not adhered, the temperature difference between the front and back of the insole is? 0.3 ° C to 0.1 ° C. It was confirmed that the temperature difference between the front and rear of the insole was small due to the heat conduction. This is because the heat generated by the friction between the insole and the foot is thermally transferred from the high temperature part to the low temperature part by the heat conductive sheet and from the low part to the high part again by the heat conductive sheet, that is, by the isothermal effect, The temperature difference is reduced and the blood circulation motion of the foot is promoted.

The present invention provides a shoe insole that can be applied to shoe insole such as shinshu, ladies shoes, boots, battle shoes, boots, shoes, and so on to maintain the temperature difference between the front part and the heel of the foot as uniform as possible to improve the circulation of the foot. The shoe insole of the present invention may be integrally attached to the body of the shoe to complete the shoe, or may be inserted into the finished shoe.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (6)

The shoe insole is manufactured by bonding an EVA (Ethylene Vinyl Acetate Copolymer) sponge with polyethylene (PE) fiber and a restoration sponge. The shoe insole is used for a shoe sole. The shoe insole includes an EVA sponge 10, a PE fiber, and a restoration sponge 30 And the heat conductive sheet (20) is inserted between the heat conductive sheet (20) and the heat conductive sheet (20).
The shoe sole according to claim 1, wherein the thermally conductive sheet (20) is formed by adhering a fluorine film (22) to both sides of an expanded graphite sheet (or graphite) (21).
The heat conductive sheet according to claim 2, wherein the thermally conductive sheet (20) has the seam base (221) stuck to the sewing line (222) along the corner, the seam base (21) Wherein the sewing line (222) is formed by sewing a thread of PTFE (Polytetrafluoro Ethylene).
2. The shoe soles according to claim 1, wherein the heat conductive sheet (20) has a multilayer structure by inserting a carbon fiber sheet (23) between two sheets of expanded graphite sheet to which a fluorine film (22) is bonded.
5. The heat conductive sheet according to claim 4, wherein the thermally conductive sheet (20) is formed such that a corner portion (221) of the thermally conductive sheet (20) is stitched with a sewing line (222) Wherein the sewing line (222) is formed by sewing a thread of PTFE (Polytetrafluoro Ethylene).
The shoe sole according to claim 1, wherein the heat conductive sheet (20) has a thickness of 0.2 to 0.5 mm.

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