KR200326251Y1 - A shoe liner with air ventilation function - Google Patents

Abstract

The present invention relates to a shoe insole having a ventilation function, the first air storage tank formed in the heel portion; A suction pipe connected to the first air storage tank and configured to suck external air; A second air storage tank formed at the big toe portion; A plurality of first discharge pipes connected to the second air storage tank to discharge air into the shoes; It includes a connecting pipe for connecting the first air storage tank and the second air storage tank, the suction pipe and the connection pipe is provided with a check valve for controlling the flow direction of air.

According to the present invention, it is possible to provide higher air circulation efficiency as compared to the prior art because the outdoor air is discharged in both the case when the load is applied to the heel and when it is not. In addition, even when sitting in the seat can use the big toe to compress the second air storage tank can not only maintain the inside of the shoe comfortably but also provides an effect that can be used as a simple exercise equipment. In addition, since the counter is installed inside the insole, it is possible to visually check the number of exercises.

Description

A shoe liner with air ventilation function

The present invention relates to a shoe insole having a ventilation function, and more particularly to a shoe insole for forming an air storage tank in the insole and inhaling the outside air and then discharging it into the shoe to keep the inside of the shoe comfortable.

Conventionally, a number of techniques have been proposed that can supply fresh air from the inside of a shoe for the purpose of removing foot odor and preventing athlete's foot. In other words, the product is used to keep the inside of the shoe more clean by using the insole made of a material with good ventilation, and recently, more aggressively install a kind of air pump in the inside of the insole can supply the outside air directly into the shoe. Techniques are being proposed.

1 and 2 show a shoe insole having a conventional ventilation function, but the heel portion of the shoe insole body (1) is made slightly higher, the middle portion thereof is a trim (3a), a plurality of cushioning jaw on the left and right sides The air compression chamber 2 is formed to face each other at regular intervals (3), and a pair of air discharge passages having a plurality of air discharge holes 10 on left and right sides of the air passage 4 connected thereto. ) Is connected, and the bottom surface of the body (1) is adhesively fixed to the sealing cover (6), the upper surface of the body (1) a fabric fabric (7) formed with a plurality of acupressure protrusions (8) on the surface at regular intervals A), an air discharge hole 10 communicating with the air discharge passage 5 is formed at the front side of the surface thereof, and a plurality of the communication chambers 2 are communicated with the compression chamber 2 at the rear of the surface of the body 1; The air suction hole 9 is formed.

That is, the above technique is to discharge the contaminated air in the shoe as the compressed air in the air compression chamber is discharged to the discharge hole (10) by the weight applied to the heel of the human body when walking, and applied to the heel As the weight is lost, the outside air is introduced. Through this, the air in the shoe can be kept clean.

However, this technique has the disadvantage of exerting an air circulation function only when walking. In reality, most people spend longer time sitting than walking, but the technique is difficult to provide the intended effect for the salarymen who have long time. In addition, acupressure protrusions are formed on the surface of the insole to serve as a health aid, but as described above, there is a problem that is limited to walking.

The present invention is devised to overcome the disadvantages of the prior art as described above, the shoe insole having a ventilation function that can be used as a simple exercise equipment as well as to exhibit the air circulation function when walking as well as sitting on a chair. The technical challenge is to provide.

The present invention is also another technical problem to provide a shoe insole that can numerically check the amount of exercise.

1 is a perspective view showing a conventional shoe insole.

Figure 2 is a perspective view showing the internal structure of the shoe shelf shown in FIG.

3 is a partial cutaway view showing an embodiment of a shoe insole according to the present invention.

4 is an enlarged cross-sectional view of an end portion of the first discharge pipe of the embodiment shown in FIG. 3.

5 is a cross-sectional view showing another embodiment of the opening degree adjusting device for adjusting the opening degree of the first discharge pipe.

6 is a cross-sectional view showing a state in which the embodiment shown in FIG. 3 is mounted on a shoe.

7 is an enlarged cross-sectional view of a check valve part of the embodiment shown in FIG. 3.

8 is a cross-sectional view showing another embodiment of the check valve shown in FIG.

In order to achieve the above technical problem, the present invention, the first air storage tank formed in the heel portion; A suction pipe connected to the first air storage tank and configured to suck external air; A second air storage tank formed at the big toe portion; A plurality of first discharge pipes connected to the second air storage tank to discharge air into the shoes; And a connection pipe connecting the first air storage tank and the second air storage tank, wherein the suction pipe and the connection pipe are provided with a check valve for controlling the flow direction of air.

That is, the present invention forms a second air storage tank on the big toe part in addition to the first air storage tank formed on the heel portion, and when the weight is loaded on the heel, the outside air flows into the first air storage tank from the outside through the suction pipe. When the weight is loaded on the front of the foot, the second air reservoir is compressed to discharge air into the shoe through the first discharge pipe. In addition, when sitting on a chair or the like to directly press the second air reservoir using the big toe to artificially discharge the air.

Through this, it is possible to exert a ventilation function even when sitting in the seat as well as walking, it is to enable the foot movement naturally by pressing the second air reservoir using the big toe. Here, a check valve is installed in the suction pipe, the first discharge pipe, and the connection pipe to prevent backflow of air.

Here, it is preferable to install an auxiliary discharge pipe which is directly communicated between the upper surface of the second air storage tank and the surface of the insole. Air is injected directly through the big toe through this can further increase the cooling feeling.

In addition, in order to enable the wearer to adjust the exercise intensity, it is preferable to add an opening degree adjusting device that can adjust the opening degree of the first discharge pipe. That is, if the outlet of the first discharge pipe is narrowed, the resistance increases when the second air reservoir is pressed with the big toe, and the exercise intensity is increased. When the outlet is widened, the resistance is decreased and the exercise intensity is reduced.

The opening degree adjusting device may be used in various forms, for example, may be provided by installing a stopper at the end of the first discharge pipe. That is, when a part of the plurality of first discharge pipes is blocked using a stopper, the total area through which the air can be discharged through the second air reservoir is reduced, thereby increasing resistance. Preferably, it is preferable to form a ventilating hole in the stopper to more precisely control the exercise intensity.

In addition, the opening degree can be adjusted by installing an auxiliary conduit inside the first discharge pipe. That is, the inner diameter can be reduced by inserting an auxiliary conduit having a diameter smaller than that inside the first discharge pipe, and the reduction degree can be adjusted by the number of auxiliary conduits inserted therein.

Preferably, in order to further enhance the air circulation function during walking, the apparatus further includes a plurality of second discharge pipes directly connected to the first air storage tank and discharging air into the shoes, wherein the air is discharged inside the second discharge pipe. It is recommended to install a check valve to control the flow direction.

In this way, during walking, a part of the outside air sucked into the first air storage tank may be directly discharged through the second discharge pipe without passing through the second air storage tank, thereby enhancing the air circulation function.

Preferably, the free end of the suction pipe is extended to the upper portion is preferably in direct communication with the outside of the shoe. This allows not only fresh air to be inhaled, but also extends the suction pipe to the upper side, thereby effectively preventing water accumulated on the road surface from penetrating into the shoe.

On the other hand, it is preferable that an additional counter for counting the number of times the second reservoir is pressed in the second air reservoir. Through this, the user can visually check the number of times of pressing the second reservoir by using the big toe to check the amount of exercise.

Hereinafter, with reference to the accompanying drawings to be described in detail an embodiment of a shoe insole having a ventilation function according to the present invention.

3 to 6, one embodiment 100 of the shoe insole according to the present invention has a first air storage tank 102 in the heel portion. The first air reservoir 102 has a shape close to a rectangle when viewed in a plan view, and has a shape in which a central portion protrudes convex when viewed in a side view. Through this, when a load is applied to the heel of the wearer, it is possible to inhale or discharge the outside air more efficiently. However, the shape of the first air storage tank 102 is not necessarily limited thereto, and may be formed in various shapes such as a circle, an ellipse, a rhombus, and the side shape may also be manufactured in various forms.

One end of the suction tube 104 is connected to the rear surface of the first air storage tank 102, and the other end of the suction tube 104 extends upward along the rear wall of the shoe as shown in FIG. 4. . For this reason, fresher air may be introduced into the shoe, but there is a concern that the feeling of wearing may be reduced. Thus, unlike the illustrated embodiment, the suction pipe may be placed only inside the insole and its end may protrude into the side wall of the heel portion of the insole. In this case, the outside air suction efficiency is lowered, but does not damage the fit, and if a thin cloth is attached to the end to act as a filter, the suction pipe can be prevented from clogging. The inner diameter of the suction pipe can be changed as necessary, but preferably about 5 mm.

In addition, although not shown, a check valve is installed inside the suction pipe 104 to block air from moving from the first air reservoir 102 to the suction pipe 104.

On the other hand, the second air storage tank 110 is formed in a portion corresponding to the wearer's big toe. The second air reservoir 110 has a shape similar to a convex lens, but is not necessarily limited thereto. In addition, a concave groove may be formed in a part of the surface of the second air reservoir 110 so that the wearer can confirm the position of the second air reservoir 110 by a tactile sense. A plurality of auxiliary discharge pipes 114 are formed between the upper surface of the second air storage tank 110 and the surface of the insole. Therefore, when the wearer presses the second air reservoir using the big toe, the air is directly injected to the big toe part through the auxiliary discharge pipe, so that a more comfortable feeling can be obtained and the operation state can be confirmed by the touch. Here, the inner diameter of the first discharge pipe is preferably 1 to 4mm, the inner diameter of the auxiliary discharge pipe can be formed to about 0.2mm, but this can be changed as necessary.

One end of four first discharge pipes 112 is connected to the second air storage tank 110, and the other end of the first discharge pipe 112 communicates with the outside through the surface of the insole. In addition, a stopper 116 is attached to the other end of the first discharge pipe 112 to adjust the opening degree of the first discharge pipe 112. Ventilation hole 117 is formed in the stopper 116, the opening degree is different when the stopper is opened and the stopper is closed, so the opening degree can be adjusted individually for each of the first discharge pipes, thereby controlling the exercise intensity. Will be. In addition, the opening degree can be adjusted according to the number of discharge pipes which covered the cap about all four first discharge pipes. That is, the kinetic intensity is higher than when covering two first discharge pipes than when only one first discharge pipe is covered.

On the other hand, it is possible to use a dog opening adjustment device such as shown in FIG. That is, the inner diameter of the first discharge pipe can be changed by inserting a plurality of auxiliary conduits 112a and 112b into the first discharge pipe 112 without using a stopper. In FIG. 5, two auxiliary conduits are shown to be inserted, but the number can be changed as necessary.

When the second air reservoir 110 is compressed by the wearer's own weight or the big toe, outside air is supplied to the surface of the insole through the first discharge pipe 112. The number of the first discharge pipes 112 and the position on the insole surface are not limited to those shown, and those skilled in the art can easily change the number and position on the insole surface.

In this case, when the load applied to the second air storage tank 110 is removed and expanded, air inside the shoe may be absorbed again through the second discharge pipe, and a check valve is installed in each of the first discharge pipes 112. This can be prevented. In this case, the manufacturing cost of the insole may be higher, but the circulation efficiency of the air is further increased.

A first connection pipe 120 is installed between the second air storage tank 110 and the first air storage tank 102 to communicate with each other, and a check valve 122 is installed in the first connection pipe 120. To block the flow of air from the second air reservoir 110 to the first air reservoir 102. The configuration of the check valve 122 will be described later.

In addition, the second connecting pipe 130 is disposed on the side of the first connecting pipe 120 in communication with the first air reservoir (102). In addition, a plurality of second discharge pipes 132 are connected to the middle portion of the second connection pipe 130 to discharge the outside air stored in the first air storage tank 102. Here, the check valve 134 is installed in the second connection pipe 130 in the same manner as the first connection pipe 120. On the other hand, it is also possible to consider an embodiment in which the second connection pipe is omitted and the first air storage tank and the second discharge pipe are directly connected.

In addition, a counter may be installed in the second air storage tank. In this case, after embedding the switch portion of the counter inside the second air reservoir, the number plate of the counter may be installed to be exposed to the surface or the back of the insole.

Referring to Fig. 6, the operation of the above embodiment will be described. When a load is applied to the first air reservoir 102 by the heel during walking, the first air reservoir 102 is compressed so that outside air flows through the first connection pipe 120 and the second connection pipe 130. do. At this time, all the outside air inside the first air storage tank 102 flows only to the first connection pipe or the second connection pipe by the check valve installed in the suction pipe 104.

The outside air passing through the first connecting pipe 120 temporarily stays inside the second air storage tank 110, and the outside air passing through the second connecting pipe 130 goes into the shoe through the second discharge pipe 132. Discharged. On the other hand, when the wearer lifts the heel, the first air reservoir 102 expands and sucks the outside air through the suction pipe 104, and the second air reservoir 110 is compressed and air through the first discharge pipe 112. Will be discharged into the shoe. Accordingly, when walking, the outdoor air is discharged into the shoe in both the case where the load is applied to the heel and the case where the heel is canceled, thereby providing much improved circulation efficiency.

When the wearer sits in place, pressing the second air storage tank 110 using the big toe repeats the above-described process while introducing outside air. At this time, the flow rate is relatively reduced in the second connecting pipe 130 when walking.

7 illustrates the internal structure of the check valves 122 and 134. The check valve may be a conventionally known one, but since the volume should be minimized in order to be mounted on the shoe insole, it is preferable to use a form in which a tube having an end portion 123 is inserted into the tube as shown in FIG. 7. good. Here, the collar end 123 is made of a flexible material and a hole is formed in the center to allow air to flow. Therefore, when pressure is applied in the left direction in FIG. 7, the end 123 is contracted to block the flow of air, and when pressure is applied in the right direction, the air flows while the end 123 is expanded. do.

8 shows another form of the check valve. The embodiment shown in FIG. 8 is basically similar in shape, but forms a stopper 123 'at the end of the tube, which is connected to the end of the tube with a flexible material. The stopper 123 'has a conical shape. When the pressure acts in the left direction, the pressure is applied to the bottom surface of the cone, thereby blocking the pipe. When the pressure acts in the right direction, the pressure is applied to the vertex of the cone. Will open.

According to the present invention having the configuration as described above, it is possible to provide a higher air circulation efficiency compared to the prior art because the outdoor air is discharged both when the load is applied to the heel and when it is not.

In addition, even when sitting in the seat can use the big toe to compress the second air storage tank can not only maintain the inside of the shoe comfortably but also provides an effect that can be used as a simple exercise equipment. In addition, since the counter is installed inside the insole, it is possible to visually check the number of exercises.

Claims (9)

A first air reservoir formed on the heel portion; A suction pipe connected to the first air storage tank and configured to suck external air; A second air storage tank formed at the big toe portion; A plurality of first discharge pipes connected to the second air storage tank to discharge air into the shoes; And a connection pipe connecting the first air storage tank and the second air storage tank, wherein the suction pipe and the connection pipe are provided with a check valve for controlling the flow direction of air. The method of claim 1, And a plurality of second discharge pipes directly connected to the first air storage tank to discharge air into the shoes, and a check valve is installed in the second discharge pipe to control the flow direction of air. Shoe insole. The method of claim 1, Shoe insole characterized in that the free end of the suction pipe is extended to the upper portion is in direct communication with the outside of the shoe. The method of claim 1, A shoe insole characterized in that the direct communication from the upper surface of the second air reservoir to the surface of the insole, a plurality of auxiliary discharge pipe having a diameter smaller than the first discharge pipe is additionally formed. The method of claim 1, The shoe insole, characterized in that the first discharge pipe further comprises an opening degree adjustment device. The method of claim 5, The opening adjustment device is attached to the end of the discharge pipe, insole characterized in that the stopper covering the outlet of the discharge pipe. The method of claim 6, Shoe insole, characterized in that the vent is formed in the stopper. The method of claim 5, The opening control device is a shoe insole, characterized in that a plurality of auxiliary conduit inserted into the first discharge pipe. The method according to any one of claims 1 to 8, The shoe insole, characterized in that the counter is further installed in the second air reservoir to count the number of times the second reservoir is pressed.