KR102611926B1 - Shoes with thermal module - Google Patents

Abstract

The present invention relates to a shoe equipped with a heating module that can increase thermal insulation in the shoe by using a low-power resistive heating method to heat the extension hose through which the air in the shoe is discharged and circulate the heated air.

Description

Shoes with thermal module applied {SHOES WITH THERMAL MODULE}

The present invention relates to a shoe to which a heating module is applied. More specifically, the present invention relates to a shoe using a low-power resistance heating method to heat the extension hose through which air is discharged in the shoe, thereby allowing the heated air to circulate, thereby increasing the thermal insulation in the shoe. This is about shoes with a heating module applied.

In general, heated shoes are basically composed of a heating means and a power source, and have the function of preventing frostbite in the winter and removing moisture inside the shoes in the summer.

However, in the case of a conventional heating means, a large-area planar heating element is applied so that the heat generated from the planar heating element is applied locally and directly to the sole or instep of the user through the insole.

In this case, if the user frequently runs or performs strenuous exercise for a long time while wearing shoes, the planar heating element is pressed or deformed by the wearer's weight, causing problems such as the metal conductor in the planar heating element being broken.

In addition, even if the planar heating element is designed for low power, there is a limit to maintaining the heating operation for a long time due to the length of the metal conductor that makes up the planar heating element and the structural characteristics of the resistor accordingly. Therefore, in order to increase the duration, the battery capacity and battery size must be increased accordingly. It must be raised, resulting in an increase in the weight of the shoe and a decrease in wearability.

Korean Patent No. 10-2341250

In order to solve the above problems, the present invention uses a low-power resistive heating method to heat the extension hose through which the air in the shoe is discharged, allowing the heated air to circulate, thereby providing a shoe with a heating module that can increase thermal insulation in the shoe. We would like to provide.

A shoe to which a heating module according to an embodiment of the present invention is applied is provided with a shoe body 110, an insole 120 provided in the shoe body 110, and an inside of the insole 120, and the shoe body 110 It may include a heating module 130 that heats and circulates the air inside.

In one embodiment, the present invention may further include a battery 140 that is electrically connected to the heating module 130 and supplies power to the heating module 130.

In one embodiment, the heat generating module 130 includes a power terminal 131 electrically connected to the battery 140, a motor 132 connected to the power terminal 131, and a propeller connected to the motor 132. (133), a housing 134 that accommodates the motor 132 and the propeller 133 and is provided to allow intake and discharge of air in the shoe body 110 through rotation of the propeller 133, the housing An extension hose 135 is connected to one side of (134) and allows discharged air to be supplied to one side of the insole 120, and the extension hose 135 generates heat while in close contact with the extension hose 135. It may include a resistance module 136 that heats the air passing through.

In one embodiment, the power terminal 131 may be provided to contact the power terminal of the battery 140 through magnetic force.

In one embodiment, the motor 132 and the resistance module 136 are connected to the power terminal 131 through a Y-shaped cable, and a detachable connection connector may be provided on one side of the Y-shaped cable. .

In one embodiment, the housing 134 may include first and second housings 134-1 and 134-2 that are engaged and coupled to each other in a symmetrical manner.

In one embodiment, the resistance module 136 may include one or more resistors 136a that generate heat through power supplied from the battery 140.

In one embodiment, the resistance module 136 may further include an insulating cover covering an area of the extension hose 135 where the one or more resistors 136a are in close contact.

In one embodiment, a space for accommodating the housing 134 and the extension hose 135 may be engraved on the lower side of the insole 120.

In one embodiment, an air discharge hole 120a connected to the receiving space and formed in a vertical direction is formed on one side of the insole 120, so that air supplied through the extension hose 135 is discharged. It may be discharged toward the top of the insole through the hole 120a.

According to one aspect of the present invention, heat retention in the shoe can be increased by heating the extension hose through which air is discharged in the shoe and allowing the heated air to circulate, as well as using a low-power resistive heating method rather than a direct heating method using a planar heating element. By using , the usage time can be significantly increased, and it has the advantage of ensuring excellent wearability because it occupies a smaller volume within the shoe compared to the planar heating element structure.

Figure 1 is a diagram showing the configuration of a shoe 100 to which a heating module is applied according to an embodiment of the present invention.
Figure 2 is a diagram showing the insole 120 in more detail.
Figure 3 is a diagram showing the heat generation module 130 in more detail.
Figure 4 is a diagram showing a state in which the heat generating module 130 is accommodated on the lower side of the insole 120.
Figure 5 is a diagram showing a state in which air is introduced and discharged into the housing 134 through the rotation of the propeller 130.
Figure 6 is a diagram showing the resistance module 136 in more detail.

Below, preferred embodiments are presented to aid understanding of the present invention. However, the following examples are provided only to make the present invention easier to understand, and the content of the present invention is not limited by the examples.

Figure 1 is a diagram showing the configuration of a shoe 100 to which a heating module is applied according to an embodiment of the present invention.

Looking at Figure 1, the shoe 100 to which the heating module according to the present invention is applied includes a shoe body 110, an insole 120 provided in the shoe body 110, a heating module 130 provided in the insole 120, and It may be configured to include a battery 140 that supplies power to the heating module 130.

The shoe body 110 has a general shoe shape, and a battery storage means (not shown) capable of storing the battery 140 is located on one side. The outside of the shoe body 110 may be treated with a waterproof coating to protect the heating module 130 and the battery 140 capable of conducting current from electric leakage.

The battery storage means has an opening and closing structure that can be opened when the stored battery 140 needs to be charged or replaced, and can be waterproofed to protect the stored battery 140.

The insole 120 is provided on the inner lower part of the shoe body 110, and the heating module 130 is accommodated on the lower side. Looking at this in more detail, it is as follows.

Figure 2 is a diagram showing the insole 120 in more detail.

Looking at Figure 2, the insole 120 has a general insole shape, and an air discharge hole 120a is formed in the vertical direction in the area where the toes are located. The air discharge hole 120a is an area for discharging heated air supplied through the heating module 130, which will be described later, and is connected to the extension hose 135 within the heating module 130, which will be described later.

Looking at the lower side of the insole 120, a receiving space for housing the housing 134 and the extension hose 135 of the heating module 130 may be formed in a negative manner. Accordingly, even if the wearer steps on the housing 134 and the extension hose 135, interference from the housing 134 and the extension hose 135 can be eliminated and the wearer will not feel discomfort.

Among the accommodating spaces of the insole 120, in particular, the space accommodating the housing 134 has an open shape on one side, which corresponds to an area to secure a space for easy intake of air within the shoe body 110. do.

The material of the insole 120 may be specified so that it can easily support the wearer's weight and have appropriate strength to prevent the housing 134 and the extension hose 135 from being damaged by being pressed by the body weight.

In the case of the air discharge holes 120a discussed above, three are shown in the drawing, but the number is not limited, and in some cases, when the extension hose 135 is in a multi-branched form, the insole 120 is formed correspondingly. It may be formed in several places to correspond to the positions of the multi-pronged ends of the extension hose 135 in the entire area.

The heat generation module 130 is located in the receiving space below the insole 120 as seen above, and sucks air in the shoe body 110 and discharges it through the air discharge hole 120, and at the same time extends the hose by generating heat from the resistor. By causing (135) to be heated, the air passing through the extension hose (135) is heated and then discharged. This will be examined through Figures 3 to 6.

Figure 3 is a diagram showing the heating module 130 in more detail, Figure 4 is a diagram showing the heating module 130 accommodated on the lower side of the insole 120, and Figure 5 is a diagram showing the air generated through the rotation of the propeller 130. This is a diagram showing the state of being injected and discharged into the housing 134, and FIG. 6 is a diagram showing the resistance module 136 in more detail.

First, looking at FIG. 3, the heat generation module 130 may be largely comprised of a power terminal 131, a motor 132, a propeller 133, a housing 134, an extension hose 135, and a resistance module 136. there is.

The power terminal 131 is electrically connected to the battery 140 to supply power to the motor 132 and the resistance module 136. At this time, the power terminal 131 is connected to the power terminal of the battery 140 through magnetic force. It has a structure that can be easily contacted.

The cable extending from the power terminal 131 is a Y-shaped cable, and both end portions of the Y-shaped cable can be branched and connected to the motor 132 and the resistance module 136, respectively. At this time, since a detachable connection connector is provided on one side of the Y-shaped cable, if the cable in the area adjacent to the motor 132 and the resistance module 136 is damaged or broken, the connection connector can be separated even if the entire cable is not replaced. Only the cables in the area adjacent to the motor 132 and the resistance module 136 can be replaced or repaired.

The length of the cable may be sufficient to reach the battery 140 stored in the battery storage means on one side of the shoe body 110 as discussed above, and to prevent interference with the cable while the wearer is wearing the shoes. The cable may be formed to be connected to the battery 140 while being in close contact with the inner wall of the instep area of the shoe body 110. Additionally, in one embodiment, the cable may be formed to be connected to the battery 140 while being completely inserted into the inner wall of the shoe body 110.

Motor 132 and propeller 133 are accommodated within housing 134. The motor 132 rotates at high speed through power supplied from the battery 140, and the propeller 133 rotates at high speed through the rotational force of the motor 132 to induce air flow.

At this time, an accommodating space for accommodating the motor 132 and the propeller 133 is formed inside the housing 134. Among these, the accommodating space where the propeller 133 is accommodated is where air in the shoe body 110 is sucked. An air intake port is provided, and an air discharge port is an area through which the sucked air is discharged.

This is a structure in which air is naturally sucked into the air intake port by the air pressure difference generated by the rotation of the propeller 133 and then discharged through the air discharge port. Meanwhile, the angles of the air intake port and the air discharge port can be basically formed to be 90 degrees to each other, but if necessary, the angle of the air intake port and the air discharge port can be 120 degrees or more.

This housing 134 may be formed of first and second housings 134-1 and 134-2 that are symmetrically coupled to each other, so that when the motor 132 fails or the propeller 133 is damaged, By separating the first and second housings 134-1 and 134-2 from each other, the motor 132 or propeller 133 can be replaced or repaired.

An extension hose 135 is connected to the air outlet of the housing 134, and the distal end of the extension hose 135 extends to the air outlet hole 120a of the insole 120. Accordingly, the air discharged from the air discharge port of the housing 134 is discharged to the upper side of the toe area in the shoe body 110 through the air discharge hole 120a of the insole 120 through the extension hose 135.

The extension hose 135 may be made of soft rubber or silicone. Therefore, even if the extension hose 135 is partially pressed and crushed by the wearer's weight, it is not damaged and can regain its shape.

Meanwhile, since the air supplied to the air discharge hole 120a through the extension hose 135 is not yet heated, one side of the extension hose 135 is connected to the resistance module 136 in order to keep warm and increase the temperature in the shoe. It is heated, and as a result, the air passing through the extension hose 135 is warmed.

The resistance module 136 is located adjacent to the area where the extension hose 135 and the housing 134 are connected to each other, and is in close contact with the outer side of the extension hose 135.

Referring to FIG. 6, the resistance module 136 corresponds to a state in which one or more resistors 136a that generate heat through power supplied from the battery 140 are connected in series, and the extension hose is heated by the heat generated by each resistor 136a. The corresponding close contact area of 135 is heated, and as a result, the air passing through the extension hose 135 is naturally warmed, and the heated warm air can be discharged from the air discharge port 120a. At this time, the number of resistors 136a is not limited.

In addition, in one embodiment, the resistance module 136 may further include a temperature control module (not shown) that can sense the temperature of the air outside the shoe body 110 and then adjust the heating temperature of the resistor 136a based on this. there is.

For example, the temperature control module causes the four resistors 136a connected in series to generate heat when the air temperature outside the shoe body 110 falls below a preset temperature, and if the temperature suddenly exceeds the preset temperature, the temperature increases further. In the case of falling, the air can be further warmed by additionally generating heat in the four resistors 136a connected in series with each other and an additional plurality of resistors 136a connected in parallel.

In this case, a plurality of bundles of four resistors 136a shown in the drawing may be provided in series, and each of the plurality of bundles may be connected in parallel to each other. Therefore, the temperature control module can control the heating temperature by selectively generating heat in each bundle.

Although the present invention has been described above with reference to preferred embodiments, those skilled in the art may make various modifications and changes to the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. You will understand that you can do it.

100: Shoes with heat module applied
110: shoe body
120: insole
120a: air discharge hole
130: Heat module
131: power terminal
132: motor
133: propeller
134: housing
135: extension hose
136: resistance module
136a: resistor
140: battery

Claims (10)

shoe body 110;
Insole 120 provided in the shoe body 110;
A heating module 130 provided inside the insole 120 and heating and circulating air within the shoe body 110; and
It includes a battery 140 that is electrically connected to the heating module 130 and supplies power to the heating module 130,
The heat generating module 130 includes a power terminal 131 electrically connected to the battery 140, a motor 132 connected to the power terminal 131, a propeller 133 connected to the motor 132, and the A housing 134 that accommodates the motor 132 and the propeller 133 and is provided to allow intake and discharge of air in the shoe body 110 through rotation of the propeller 133, one side of the housing 134 It is connected to an extension hose 135 that allows the discharged air to be supplied to one side of the insole 120, and the air passing through the extension hose 135 through heat generation while in close contact with the extension hose 135. It includes a resistance module 136 that heats,
The power terminal 131 is provided to be in contact with the power terminal of the battery 140 through magnetic force,
The motor 132 and the resistance module 136 are connected to the power terminal 131 through a Y-shaped cable, and a detachable connection connector is provided on one side of the Y-shaped cable,
The housing 134 includes first and second housings 134-1 and 134-2 that are separated and coupled to each other in a symmetrical form,
The resistance module 136 includes one or more resistors 136a that generate heat through power supplied from the battery 140,
The resistance module 136 further includes an insulating cover covering an area of the extension hose 135 to which the one or more resistors 136a are in close contact,
On the lower side of the insole 120, the housing 134 and the extension hose 135 form a concave accommodation space,
As an air discharge hole (120a) is formed on one side of the insole (120), which is connected to the receiving space and is formed in a vertical direction, the air supplied through the extension hose (135) passes through the air discharge hole (120a). It is discharged toward the top of the insole through
A battery storage means capable of storing the battery 140 is located on one side of the shoe body 110, and the battery storage means has an opening and closing structure that can be opened to enable replacement of the battery 140, and the stored It is waterproofed to protect the battery (140),
The resistance module 136 includes a temperature control module that adjusts the heating temperature of the resistance body 136a based on the result of sensing the external air temperature of the shoe body 110,
The temperature control module causes the four resistors 136a connected in series to generate heat when the external air temperature of the shoe body 110 falls below a preset temperature, and when the temperature further falls below the preset temperature, Shoes to which a heating module is applied, characterized in that additional heat is generated through four connected resistors (136a) and a plurality of resistors (136a) connected in parallel. delete delete delete delete delete delete delete delete delete