KR102582337B1 - Poultice unit for far-infrared radiation - Google Patents

Abstract

A fomentation unit for far-infrared radiation is disclosed. This embodiment provides a far-infrared radiating fomentation unit that can emit a large amount of far-infrared rays immediately after use through preheating before use by the user.

Description

Poultice unit for far-infrared radiation}

The present invention relates to a fomentation unit that emits a large amount of far-infrared rays, and more specifically, to a fomentation unit for far-infrared rays that can promote blood circulation and health by emitting a large amount of far-infrared rays to the user.

In general, bricks or tiles, which are fired products of flat clay, can be used to finish the interior and exterior walls of a building, and these bricks or tiles are fixed to the interior and exterior walls of the building with mortar or adhesive.

Currently used indoor construction tiles are used as interior materials for kitchens, bathrooms, verandas, etc., but they have developed with a focus on design and practicality rather than hygiene aspects, and some antibacterial tiles are PVC-based and antibacterial tiles coated with ceramic on the glaze. It is being presented.

These tiles and bricks are mainly manufactured by mixing concrete or ceramics, and recently, red clay has been used as a finishing material with a far-infrared radiation effect.

In Patent Registration No. 0837850 (2008.06.05.) 'Soil tile and its manufacturing method', calcium hydroxide and red clay are mixed with one or more of elvan stone, illite, and tourmaline, and silica, fly ash, diatomaceous earth, We propose a tile manufactured by a composition containing one or more components of volcanic ash and one or more ore particles selected from the group of porcelain, pyrophyllite, and talc, and a dye and antibacterial agent on the surface.

Recently, efforts to manufacture finishing materials or building materials such as tiles using various natural materials are rapidly increasing, and in particular, materials containing minerals beneficial to the human body are being used in a variety of ways, for example, in red clay rooms or saunas. The above-mentioned finishing materials are used here.

(Document) Patent Registration No. 0837850 (2008.06.05.)

These embodiments are a far-infrared ray-radiating fomentation that can improve the user's satisfaction by detecting the user's use in advance and heating it to a predetermined temperature before the user actually uses it to maintain a ready state in which a large amount of far-infrared rays can be radiated. We would like to provide a unit.

The far-infrared radiation fomentation unit according to this embodiment includes a first bottom portion (100a) disposed in the first area (S1) corresponding to the area used by the user, and the remaining area excluding the first area (S1). a bottom portion 100 including a second bottom portion 100b disposed in a second area S2; A side portion extending from the outermost edge of the bottom 100 to a predetermined height in the vertical direction and provided with a plurality of far-infrared lamps 12 in a direction perpendicular to the bottom 100 and facing the user. (200); a heating unit 300 installed below the bottom 100 to heat the lower surface of the bottom 100 to a predetermined temperature; and a control unit 400 that controls the temperature of the heating unit 300.

The first and second bottom portions (100a, 100b) have an air pocket portion (32) formed on the inside, and the air pocket portion (32) is opened on the lower surface of the first and second bottom portions (100a, 100b). Entrance portion (32a); a chamber (32e) communicating with the inlet (32a) and forming a space in which heated air is stored; a guide groove portion (32f) formed on the inner peripheral surface to allow the heated air to move along the inner peripheral surface of the air chamber (32e); The upper sides of the first and second bottom portions 100a and 100b are positioned so that the heat energy of the heated air introduced through the inlet portion 32a is conducted to the upper surfaces of the first and second bottom portions 100a and 100b. It further includes first and second auxiliary air pocket parts (32b, 32c) extending in a radial direction, wherein the first auxiliary air pocket part (32b) is located on both left and right sides of the air pocket part (32), The second auxiliary air pocket portion 32c is characterized in that it extends relatively short between the left and right sides of the first auxiliary air pocket portion 32b.

First and second diameter reduction parts (32b1, 32c1) with reduced diameters are formed in the first and second auxiliary air pocket parts (32b, 32c), and the first and second diameter reduction parts (32b1, 32c1) After the air moves to the first and second auxiliary air pocket parts (32b, 32c), the amount discharged into the chamber (32e) stays in a minimized state, so that the entire first and second bottom parts (100a, 100b) It is characterized in that the temperature drop is prevented and the amount of far-infrared ray radiation to the outside is continuously maintained.

The side portion 200 includes a perforated plate 30 installed on the front of the far-infrared lamp 12 and formed with a plurality of through holes 31 opening at different sizes; It includes an air pocket portion 32 formed inside the perforated plate 30.

The control unit 400 is connected to a sensor unit (S) that detects the temperature of the bottom part 100 and the side part 200, and stores the storage information stored in the memory unit where the time zone and temperature information used by the user are stored. After controlling the operating time and temperature of the heating unit 300 so that the first area (S1) is heated before the second area (S2) during the t1 time before the user uses it, the t1 time elapses. After this, the heating of the second area (S2) is controlled to occur simultaneously for a period of time t2, and when the user inputs usage information in a preset time period, the operation of the far-infrared lamp 12 is turned on to heat the user. Controls far-infrared rays to be emitted at front, left, and right positions.

The present embodiments provide a far-infrared ray-radiating fomentation unit that detects the user's use in advance and maintains a state in which far-infrared rays can be radiated in advance, thereby providing the user with the best satisfaction, and can be conveniently used by users of various ages. It can promote changes in family life.

These embodiments improve heat transfer efficiency by changing the movement trajectory and flow of heated air for far-infrared radiation, enable high-efficiency far-infrared radiation even with low power, and induce convective flow of air through the air pocket portion to improve heat transfer. By reducing temperature drop, the amount of far-infrared rays emitted toward the user can be increased more.

1 is a plan view of a fomentation unit for far-infrared ray radiation according to this embodiment.
Figure 2 is a view showing an air pocket provided at the bottom according to this embodiment.
Figure 3 is a diagram showing a control unit and components associated with the control unit according to this embodiment.

A fomentation unit for far-infrared ray radiation according to this embodiment will be described with reference to the drawings.

Referring to the attached FIGS. 1 to 3, the far-infrared ray radiation fomentation unit according to this embodiment includes a first bottom portion 100a disposed in a first area S1 corresponding to the area used by the user, and the first At the bottom 100 including the second bottom 100b disposed in the second area S2 corresponding to the remaining area except for area 1 S1, and at the outermost edge of the bottom 100 A side portion 200 extending to a predetermined height in the vertical direction and provided with a plurality of far-infrared lamps 12 in a direction perpendicular to the bottom 100 and facing the user, and a side portion 200 of the bottom 100 A heating unit 300 installed on the lower side to heat the lower surface of the floor 100 to a predetermined temperature; and a control unit 400 that controls the temperature of the heating unit 300.

The far-infrared radiation heating unit may be installed in the balcony area or room of an apartment, or in an independent area in the case of a single-family home. For example, when installed in a balcony area, it may be possible to simultaneously provide a view of the outside and a heating function by having a sash facing the outside of the living room as the front, and the entrance and ceiling are installed separately.

In addition, in the case of single-family homes or country homes, tempered glass is installed in a location facing the outside to minimize the impact of outdoor air and secure a view, thereby improving user satisfaction.

The floor portion 100 according to this embodiment is formed in the form of a tile and uses clay or red clay, which are eco-friendly materials, so it emits far-infrared rays and negative ions and is harmless to the human body. It is manufactured in the form of a finishing material or tile, so it can be easily incorporated into a building and used. there is.

For example, the bottom part 100 may be molded from one or more of clay, red clay, kaolin, celadon clay, or white porcelain clay to emit far-infrared rays, but is not specifically specified.

As an example, the bottom part 100 is formed of a mineral such as clay or red clay, and the upper surface has a mineral layer 101 in which far-infrared minerals (tourmaline, elvan, germanium, and alabaster) and glaze are mixed to allow far-infrared rays to be more easily radiated. This formation causes the effect of increasing the far-infrared emissivity as the upper surface temperature increases.

The far-infrared ray has a wavelength of 8~16um, which is the most beneficial wavelength for the human body. When absorbed by the human body, it penetrates deep into the skin (4~5cm), 80 times deeper than general heat, and not only kills pathogens and cancer cells, but also constitutes cells within the human body. It is radiated to moisture and protein molecules and resonates with minute vibrations about 2,000 times per minute, thereby invigorating cellular activity and generating heat energy, thereby increasing body temperature.

When the user's body temperature rises, microvessels expand, blood circulation becomes active, metabolism is strengthened, and tissue regeneration increases, breaking down blood clots in blood vessels and promoting blood circulation. As the blood becomes clearer, it improves the pH and strengthens the ability to improve the constitution from acidic to slightly alkaline. It also has a relaxation effect that is helpful for mental health and is effective in relieving stress, which is the cause of adult diseases.

An air pocket portion 32 is formed on the inside of the bottom portion 100 so that a large amount of far-infrared rays having this effect are emitted, and the bottom portion 100 is divided into a first region S1 and a second region S2.

The first area S1 corresponds to an area mainly used by the user among the entire area of the floor 100 and corresponds to an area where the user mainly lies or sits. The second area (S2) corresponds to an area in which the frequency of contact with the user is relatively low compared to the first area (S1).

The first region (S1) is defined as the first bottom portion (100a), the second region (S2) is defined as the second bottom portion (100b), and the air pocket portion 32 is defined as the first and second bottom portions. It is formed in both (100a, 100b).

The air pocket part 32 is formed with an inlet part 32a through which heat energy generated from the heating part 300, which will be described later, flows in, so the heat energy of the heated air increases heat conduction of the bottom part 100. This causes the surface temperature to rise more quickly. For reference, an air pocket portion 32 is formed in both the bottom portion 100 and the perforated plate 30, but for convenience of explanation, the description is limited to the bottom portion 100.

Since the bottom part 100 is made of a ceramic material, the temperature does not drop rapidly after the temperature is raised to a predetermined temperature by the heating part 300 and the temperature is maintained for a certain period of time, so that the air pocket part 32 More far-infrared rays can be radiated toward the user through the heat energy of the stored high-temperature air.

In this embodiment, first and second auxiliary air pocket parts 32b and 32c are formed radially extending outward from the inner upper part 32d to conduct heat energy to the outside of the bottom part 100.

The bottom part 100 receives the heat generated from the heating part 300 and rises to a predetermined temperature, and the surface temperature does not decrease due to the heated air flowing into the air pocket part 32, but maintains the predetermined temperature. Since it is maintained, more far-infrared rays can be radiated outward.

In addition, the air pocket portion 32 can store heat energy, making it possible to store and use it for a long time without raising the temperature of the heating portion 300 to a high temperature, thereby enabling efficient use even with low power.

The air pocket portion 32 communicates with the inlet portion 32a and is formed with a chamber 32e in which heated air is stored, thereby delaying the temperature drop of the bottom portion 100 due to thermal energy storage, convection, and heat transfer phenomena. You can do it.

After heated air is introduced into the chamber 32e through the inlet 32a, heat is transferred to the first and second auxiliary air pockets 32b and 32c simultaneously with convection, and the inlet 32a Heat loss in the furnace can be minimized, making it more advantageous to increase the surface temperature of the bottom 100.

In particular, the guide groove portion 32f is formed on the inner circumferential surface to allow heated air to move along the inner circumferential surface of the air chamber 32e, and may have a cross-sectional shape of any one of a circular, oval, or polygonal shape, thereby allowing the heated air to move. can be achieved stably.

The guide groove portion 32f can induce the heated air convectively moving along the inner peripheral surface of the chamber 32e into a stable moving flow moving along the guide groove portion 32f rather than in a turbulent form, thereby reducing fluid movement loss and Stable heat exchange in the air pocket portion 32 can be achieved.

The first auxiliary air pocket portion (32b) corresponds to a type of passage communicating with the air pocket portion (32) and provides a space through which heat can flow.

In particular, since a plurality of first auxiliary air pocket parts (32b) are arranged in a radial form, air heated to a predetermined temperature stays in the air pocket part (32) while continuously convectively circulating as shown by the arrow, and heat transfer occurs. Through this, the temperature drop of the bottom 100 can be delayed as much as possible and a large amount of far-infrared rays can be stably emitted to the outside and toward the user.

The first auxiliary air pocket portion 32b is located as shown in the drawing, and the second auxiliary air pocket portion 32c has an extension length extending outward from the intermediate position between the first auxiliary air pocket portions 32b. extends relatively briefly. The reason why the second auxiliary air pocket portion 32c is extended like this is because it is extended short considering the thickness of the bottom portion 100.

In the first and second auxiliary air pocket portions (32b, 32c), some air stays in the first and second auxiliary air pocket portions (32b, 32c) without easily escaping after being introduced by a convection phenomenon, so that air heated to a specific temperature can be confined, so that the bottom portion (100) has a predetermined temperature. It is more advantageous to radiate a large amount of far-infrared rays outward by preventing a rapid decrease in temperature after the temperature rises.

In particular, in this embodiment, as the air heated by the first and second auxiliary air pockets 32b and 32c stays, the rate at which the surface temperature of the bottom 100 decreases can be reduced and a large amount of far-infrared rays are radiated more. You can do it.

In this embodiment, first and second diameter reduction parts (32b1, 32c1) with reduced diameters are formed at connection portions of the air pocket part (32) connected to the first and second auxiliary air pocket parts (32b, 32c).

The first and second diameter reducing parts (32b1, 32c1) are formed after air moving convectionly along the inner peripheral surface of the air pocket part 32 formed in a spherical shape flows into the first and second auxiliary air pocket parts (32b, 32c). It is formed to minimize the amount discharged again.

The first and second auxiliary air pocket parts (32b, 32c) are configured such that the air moves to the first and second auxiliary air pocket parts (32b, 32c) by the first and second diameter reduction parts (32b1, 32c1). Since the amount discharged to the chamber 32e stays in a minimized state, a decrease in temperature of the entire main body 20 is prevented, and the amount of far-infrared ray radiation to the outside can be continuously maintained.

Therefore, the spherical air pocket portion 32 continuously circulates convection of the heated air in the chamber 32e, and some air flows into the first and second auxiliary air pocket portions 32b and 32c. By staying there, it is possible to prevent the temperature of the entire bottom 100 from falling and to continuously emit far-infrared rays.

The air pocket portion 32 is formed in a shape in which the area of the inlet portion 32a opened on the side becomes narrow when viewed from the side by cutting the longitudinal cross-section, and becomes wider toward the inside based on the inlet portion 32a. .

The reason why the air pocket portion 32 is formed in this way is to keep the heated air in the air pocket portion 32 so that the surface temperature of the bottom portion 100 does not decrease, thereby allowing more energy even when heated to the same temperature. This is to improve user satisfaction by emitting far-infrared rays outward.

The bottom portion 100 according to this embodiment aims to emit far-infrared rays to the back of the head, back, buttocks, thighs, and calves when the user is lying down. And the side part 200 emits a large amount of far-infrared rays from all sides of the user.

The side portion 200 includes a perforated plate 30 installed on the front of the far-infrared lamp 12 and formed with a plurality of through holes 31 opening at different sizes, and an air pocket portion formed inside the perforated plate 30. Includes (32).

Unlike the first and second bottom parts 100a and 100b described above, the perforated plate 30 has a predetermined thickness and is installed on the side part 200 and heated by the far-infrared lamp 12.

Since the perforated plate 30 has an air pocket portion 32 formed therein and has the same structure as described above, detailed description will be omitted.

In this embodiment, a ceiling is provided at the vertical upper part of the floor 100, and far-infrared rays such as far-infrared lamps are installed on the ceiling, so that a large amount of far-infrared rays can be radiated vertically downward toward the user.

The side portion 200 may have all of the perforated plates 30 installed or may be installed one by one.

The control unit 400 according to this embodiment is connected to a sensor unit (S) that detects the temperature of the bottom part 100 and the side part 200. The sensor unit (S) uses a temperature sensor (S1), and whether or not the user is in use is detected through a pressure sensor (S2) installed on the bottom 100.

At least a plurality of the pressure sensors S2 are spaced apart at predetermined intervals, so that even when the user is located at any position on the floor 100, the presence or absence of the user can be detected and transmitted to the control unit 400.

The control unit 400 determines that the first area S1 is converted into the second area during the time t1 before use by the user through the storage information stored in the memory unit M where the time zone and temperature information used by the user are stored. (S2) Preheating control is performed on the heating unit 300 so that it is heated first. The preheating control adjusts the operating time and temperature for the first region S1.

The radiation therapy unit requires a certain amount of time for a large amount of far-infrared rays to be emitted after the user turns it on for use. The first and second bottom parts (100a, 100b) contain clay and red clay for far-infrared radiation. and a mixture formed of a large amount of minerals, and the surface temperature of the first and second bottom portions 100a and 100b must be raised to a certain temperature until a large amount of far-infrared rays are emitted.

To this end, the control unit 400 performs preheating control so that the first and second bottom portions 100a and 100b are heated in advance for a time t1 before use by the user according to the time zone information and temperature information actually used by the user. It is possible to prevent the user from feeling cold when lying or sitting on the floor 100.

In particular, in seasons such as winter when the outside air temperature drops below freezing, if the preheating control is performed as above, the user can use it comfortably without feeling cold or reluctant to use it.

Therefore, when users use a radiation therapy unit, they can lead a healthier life through satisfaction and increased blood circulation through a large amount of far-infrared radiation.

For this purpose, the control unit 400 controls the first floor 100a corresponding to the first area S1 for a time selected between 10 and 30 minutes corresponding to time t1 before actual use by the user. ) operates the heating unit 300 so that it is heated first.

For example, the heating unit 300 uses a carbon fiber heating element made in the form of cloth, but it may also be possible to use other heating elements. In addition, the side part 200 is also operated so that it is controlled to rise to a predetermined temperature within the shortest time.

The control unit 400 controls the heating of the second bottom portion 102b corresponding to the second area S2 to be simultaneously performed for a time t2 after time t1 has elapsed. The reason why the controller 400 does not heat the second area S2 together with the first area S2 is to improve economic efficiency through minimal consumption of electrical energy. In addition, since the area where the user mainly lies or sits corresponds to the first area (S1), the temperature is controlled to increase by heating preferentially over the second area (S2).

And, when the user inputs usage information at a preset time, the control unit 400 turns on the operation of the far-infrared lamp 12 so that far-infrared rays are emitted from the side part 200 as well, thereby emitting a large amount of far-infrared rays at the front, rear, left and right positions of the user. This radiation can be controlled.

The control unit 400 can prevent unnecessary power consumption by controlling the heating unit 300 to stop operating if the user's usage information is not input.

The control unit 400 can be controlled to provide information before use on the operation of the heating unit 300 using various terminals carried by the user, allowing convenient operation even when the user is in a remote location. Convenience can be greatly improved.

Above, an embodiment of the present invention has been described, but those skilled in the art can add, change, delete or add components without departing from the spirit of the present invention as set forth in the patent claims. The present invention may be modified and changed in various ways, and this will also be included within the scope of rights of the present invention.

12: Far infrared lamp
32: Air pocket part
32a: entrance part
32e: Chamber
32b, 32c: 1st and 2nd auxiliary air pocket parts
32b1, 32c1: first and second diameter reduction parts
100: bottom part
100a, 100b: 1st and 2nd bottom parts
200: side part
300: heating unit
400: control unit

Claims (5)

A first bottom portion 100a disposed in the first area S1 corresponding to the area used by the user, and a second area S2 corresponding to the remaining area excluding the first area S1. Bottom portion 100 including 2 bottom portions 100b;
A side portion extending from the outermost edge of the bottom 100 to a predetermined height in the vertical direction and provided with a plurality of far-infrared lamps 12 in a direction perpendicular to the bottom 100 and facing the user. (200);
a heating unit 300 installed below the bottom 100 to heat the lower surface of the bottom 100 to a predetermined temperature; and
It includes a control unit 400 that controls the temperature of the heating unit 300,
The control unit 400 is connected to a sensor unit (S) that detects the temperature of the bottom part 100 and the side part 200, and stores the storage information stored in the memory unit where the time zone and temperature information used by the user are stored. After controlling the operating time and temperature of the heating unit 300 so that the first area (S1) is heated before the second area (S2) during the t1 time before the user uses it, the t1 time elapses. After this, the heating of the second area S2 is controlled to occur simultaneously for a period of time t2,
A fomentation unit for far-infrared radiation that turns on the operation of the far-infrared lamp (12) when the user inputs usage information in a preset time period and controls the far-infrared rays to be emitted at the front, rear, left and right positions of the user.
According to claim 1,
The first and second bottom portions (100a, 100b) have an air pocket portion (32) formed on the inside, and the air pocket portion (32) is opened on the lower surface of the first and second bottom portions (100a, 100b). Entrance portion (32a);
a chamber (32e) communicating with the inlet (32a) and forming a space in which heated air is stored;
a guide groove portion (32f) formed on the inner peripheral surface to allow the heated air to move along the inner peripheral surface of the air chamber (32e);
The upper sides of the first and second bottom portions 100a and 100b are positioned so that the heat energy of the heated air introduced through the inlet portion 32a is conducted to the upper surfaces of the first and second bottom portions 100a and 100b. It further includes first and second auxiliary air pocket portions (32b, 32c) extending radially toward the
The first auxiliary air pocket portion 32b is located on both left and right sides of the air pocket portion 32, and the second auxiliary air pocket portion 32c is located relative to the left and right sides of the first auxiliary air pocket portion 32b. A fomentation unit for far-infrared radiation, characterized in that it is briefly extended. According to clause 2,
First and second diameter reduction parts (32b1, 32c1) with reduced diameters are formed in the first and second auxiliary air pocket parts (32b, 32c), and the first and second diameter reduction parts (32b1, 32c1) After the air moves to the first and second auxiliary air pocket parts (32b, 32c), the amount discharged into the chamber (32e) stays in a minimized state, so that the entire first and second bottom parts (100a, 100b) A fomentation unit for far-infrared ray radiation, characterized in that the temperature drop is prevented and the amount of far-infrared ray radiation is continuously maintained outward. According to claim 1,
The side portion 200 includes a perforated plate 30 installed on the front of the far-infrared lamp 12 and formed with a plurality of through holes 31 opening at different sizes;
A fomentation unit for far-infrared radiation, including an air pocket portion (32) formed inside the perforated plate (30). delete