KR-102962723-B1 - LOCAL HOT AND COLD STEAMING SYSTEM USING THERMOELECTRIC ELEMENT BY HEAT TRANSFER FLUID DISSIPATION

Abstract

The present invention relates to a local hot and cold compress system using a thermoelectric element by heat dissipation of a thermoelectric element, which has good heat exchange efficiency by deviating from the conventional air-cooling method to maximize the heat transfer efficiency of the thermoelectric element, and by providing a thermoelectric liquid with high specific heat, low viscosity, and low freezing point, a water jacket module through which the thermoelectric liquid passes, a thermoelectric element combined with the water jacket module, and a heat absorption and dissipation exchange device that absorbs and dissipates heat from the thermoelectric liquid, and enabling continuous hot and cold compress treatment of a local area by means of a hot and cold compress module that comes into contact with the local area.

Inventors

• 안성욱
• 김선수

Assignees

• 주식회사 쉬프트베리

Dates

Publication Date

20260512

Application Date

20230519

Claims (8)

1. A local hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid, comprising a hot and cold facial massager including a head portion and a handle, and a heat absorption and dissipation exchange device connected to the hot and cold facial massager, The above head part is, A front case having a front handle and a protrusion, which are the front parts of the above-mentioned handle; A rear case having a rear handle, which is the rear part of the above-mentioned handle; Water jacket module interposed between the front case and the rear case above: A thermoelectric element interposed between the front case and the water jacket module, which absorbs heat from the water jacket module or dissipates heat through the water jacket module; A far-infrared emitting tip interposed between the front case and the thermoelectric element and assembled by press-fitting into the protrusion; A heating and cooling plate interposed between the far-infrared emitting tip and the water jacket module, positioned behind the far-infrared emitting tip to transfer heat from the thermoelectric element absorbed from the water jacket module to the far-infrared emitting tip; and A function control circuit comprising a switch that is press-fitted and assembled inside the rear case and switches the +/- direction of the power supply to cool or heat the heating plate, and The above water jacket module is, A water jacket with an internal channel formed for the flow of thermal fluid; A sealing pad positioned in close contact with the rear of the water jacket to prevent leakage of the thermal liquid; and A water jacket cover located at the rear of the sealing pad and having a plurality of fastening holes; comprising, The above far-infrared emitting tip is a localized hot and cold compress system using a thermoelectric element by thermoelectric liquid heat dissipation that is operated by the thermoelectric element that absorbs heat from the water jacket module and emits far-infrared rays.
2. In claim 1, The above far-infrared emitting tip is a local hot and cold steam system using a thermoelectric element formed from at least one of jade, red clay, ceramic, pyrophyllite, and olivine.
3. In claim 1, A thermoelectric element is interposed between the above-mentioned hot and cold heating plate and the above-mentioned water jacket module, and By blocking the outside air in contact with the thermoelectric element, the formation of condensation around the thermoelectric element due to the moisture in the outside air is suppressed. A local hot and cold steam system using a thermoelectric element by thermoelectric liquid heat dissipation, further comprising an insulating liner that blocks radiative heat transfer between the above hot and cold plates and the above water jacket.
4. In claim 1, The above thermoelectric element is a local hot and cold steam system utilizing a thermoelectric element by heat dissipation of a thermoelectric liquid, comprising a thermoelectric element surrounding an insulating material for insulating the surroundings of the thermoelectric element.
5. In claim 1, An insulating pad interposed between the water jacket cover and the rear case, positioned at the rear of the water jacket cover to block heat generated in the water jacket; An elastic pressure plate interposed between the insulation pad and the rear case, positioned at the rear of the insulation pad, and having a plurality of fastening holes; A plurality of water jacket cover fastening bolts for joining the water jacket, the sealing pad, and the water jacket cover, which are inserted into a plurality of fastening holes formed in the water jacket cover; and It further includes elastic pressure plate fastening bolts that are inserted into a plurality of fastening holes formed in the elastic pressure plate to connect the insulation pad and the elastic pressure plate to the water jacket cover, A localized hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid, wherein the sealing pad adheres to the flow path of the water jacket by the elasticity of the elastic pressure plate to prevent leakage of the thermoelectric liquid.
6. A local hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid, comprising a hot and cold massager and an absorption and dissipation heat exchanger connected to the hot and cold massager, The above hot and cold massager is, Gel tube filled with gel inside; A heating and cooling plate positioned in contact with the lower side of the gel tube and having a plurality of fastening holes formed therein; A gel tube liner that is press-fitted and fitted from above the gel tube and the hot/cold plate to fix the gel tube and the hot/cold plate; A thermal insulation pad for a thermoelectric plate, positioned in contact with the lower side of the above-mentioned hot and cold heating plate and having an insertion hole into which a thermoelectric element is inserted; A thermoelectric element located below the above-mentioned thermal insulation pad and inserted into the above-mentioned insertion hole; A water jacket module positioned in contact with the lower side of the above thermoelectric element; An insulation pad positioned to be in contact with the lower side of the above-mentioned water jacket module; An elastic pressure plate positioned to abut the lower side of the insulation pad; and It includes a case that engages with the gel tube liner and accommodates the hot/cold heating plate, heating plate insulation pad, thermoelectric element, water jacket module, insulation pad, and elastic pressure plate inside, and has a plurality of fastening nut holes to be inserted on the outer side opposite to where this is inserted. The above water jacket module is, A water jacket with an internal channel formed for the flow of thermal fluid; A sealing pad positioned in close contact with the rear of the water jacket to prevent leakage of the thermal liquid; and A water jacket cover located at the rear of the sealing pad and having a plurality of fastening holes; comprising, The gel tube liner has a protrusion hole for the gel tube to protrude, and A local hot and cold compress system using a thermoelectric element through heat dissipation of a thermoelectric liquid in which a gel tube protruding through the above-mentioned protruding hole comes into contact with the human body.
7. In claim 6, The above case has a fixing band for securing it to the human body; A local hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid, comprising a plurality of fastening nut holes formed on the outer side opposite to where the above-mentioned hot and cold heating plate is inserted.
8. In claim 7, A localized hot and cold steam system using a thermoelectric element by thermoelectric liquid heat dissipation, wherein a plurality of fastening bolts are inserted into a plurality of fastening holes formed in the hot and cold plate and fastened by a plurality of fastening nuts inserted into a plurality of fastening nut holes formed in the case, and the hot and cold plate, a heat plate insulation pad, a thermoelectric element, a water jacket module, an insulation pad, and an elastic pressure plate, which are located below the hot and cold plate and accommodated within the case, are fastened and assembled with the case.

Description

Local Hot and Cold Steaming System Using Thermoelectric Element by Heat Transfer Fluid Dissipation The present invention relates to a local hot and cold compress system using a thermoelectric element by heat dissipation of a thermoelectric liquid, and more specifically, to a local hot and cold compress system using a thermoelectric element by heat dissipation of a thermoelectric liquid that has good heat exchange efficiency by deviating from the conventional air cooling method to maximize the heat transfer efficiency of the thermoelectric element, and by providing a thermoelectric liquid with high specific heat, low viscosity, and low freezing point, a water jacket module through which the thermoelectric liquid passes, a thermoelectric element combined with the water jacket module, and an absorption and dissipation heat exchanger that absorbs and dissipates heat from the thermoelectric liquid, and enabling continuous hot and cold compress treatment of the local area by means of a far-infrared emitting tip that comes into contact with the local area. Generally, the face can be considered the most aesthetically important part of the human body. Because it is constantly exposed to the outside environment, dust and other impurities accumulate in microscopic pores such as pores and sweat glands. Furthermore, if the face becomes dry, the skin cracks, loses elasticity, sags, and wrinkles, making it the part of the body where aging occurs most rapidly. For this reason, various facial massagers have been developed in the past to provide tension and elasticity to the facial skin to prevent sagging or wrinkles, while simultaneously gently relaxing stiff facial muscles to create vibrant skin. However, conventional facial massagers included those utilizing roller-type, ballpoint pen-type, or rotating plates, but they were very cumbersome to use. In addition, there was a conventional cool massager using a thermoelectric element that was equipped with a case having a hollow hole, and consisted of a thermoelectric element installed inside the case, an operating time controller, a thermoelectric element driving circuit, a fan driving unit for discharging heat, a unit for generating an alarm sound at the end of operation, an oscillator that provides a reference clock to the controller, a DC adapter, a constant voltage circuit, and an operating status display unit. However, this cool massager has a problem in that, when used as a natural air-cooling type, the cooling and heating functions are initially distinguished, but as time passes, the heat of the cooling and heating part is neutralized and the cooling and heating functions are lost, so the cooling and heating functions cannot be continuously sustained. In addition, there is a conventional vibration and hot/cold facial massager comprising a case having a bottom plate in which the flat bottom edge is bent upward, the front part is inclined upward and extends in a shape that narrows toward the top, the rear part of the bottom is rounded and a rim of a certain height is formed on the edge, and a handle part formed on the top; a magnesium plate that matches the shape of the bottom plate and is installed on the inner side of the bottom plate; a thermoelectric element installed on the magnesium plate; a vibration motor installed on the inner front side of the handle part; a battery installed to drive the vibration motor; and a charger installed to charge the battery. However, since there is no continuous heat absorption and dissipation system due to natural air cooling, there is a problem that it is insufficient to continuously maintain the cold or hot compress function. FIG. 1 is a configuration diagram illustrating an example of a local hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid according to one embodiment of the present invention. Figure 2 is an exploded perspective view of the hot and cold facial massager of Figure 1. Figure 3 is a cross-sectional view of the hot and cold facial massager of Figure 1. FIGS. 4a and 4b are a perspective view and an internal thermoelectric flow diagram of the water jacket module of FIG. 3. FIGS. 5A and FIGS. 5B are a perspective view and an exploded perspective view of the heat absorption and dissipation exchanger of FIG. 1. FIG. 6 is a configuration diagram illustrating an example of a local hot and cold steam system using a thermoelectric element by heat dissipation of a thermoelectric liquid according to another embodiment of the present invention. Fig. 7 is an exploded perspective view of the hot and cold massage part of Fig. 6. Figures 8a and 8b are cross-sectional views of the hot and cold massage part of Figure 6. Hereinafter, a localized hot and cold steam system using a thermoelectric element based on thermoelectric liquid heat dissipation according to the present invention will be described in more detail through the detailed description of embodiments with reference to the