KR200325527Y1 - Panel for emitting infrared ray and its structure - Google Patents

Abstract

The present invention is to manufacture a panel using a material that emits far-infrared rays, and to manufacture a structure to attach the product, by dividing the material that emits far-infrared rays, such as char, germanium, ocher, elvan, jade, including A panel may be prepared, or all of the above materials are mixed and a panel is prepared using the mixture, or a panel is prepared using a mixture obtained by mixing one of the above materials with salt, and the manufactured panel is constructed. Manufacture by attaching to the frame.

The present invention emits a variety of far-infrared rays from the panel or structure, can easily create an environment that can simultaneously experience the efficacy of a number of materials in each home or office, and can save a lot of time and space according to the construction have.

Description

Far infrared rays emitting panel and its structure {PANEL FOR EMITTING INFRARED RAY AND ITS STRUCTURE}

The present invention relates to a panel that emits far-infrared rays and its structure, and more specifically, to prepare a panel by partitioning the material that emits far-infrared rays, such as char, germanium, ocher, elvan, jade, including salt, or the above materials. Are mixed, and a panel is prepared using the mixture, or a panel is prepared by using a mixture of one of the above materials selected by mixing with salt, and the prepared panel is attached to the structure frame, thereby benefiting the human body. The present invention relates to a panel and a structure in which far-infrared rays are emitted that block far-infrared rays, negative ions, constant temperature and humidity, deodorization, and electromagnetic waves to enable people to live healthy lives.

In general, salt promotes blood circulation by releasing far-infrared rays, has excellent detoxification and bactericidal effects, and when sweating on the steam, rub it on the skin to remove toxins from the body and inhibit the growth of bacteria. It has a therapeutic effect. In addition, general salt, rock salt, and bamboo salt, which are not processed, are easily dissolved in water and have no adhesive or adhesive strength, but salts that have been heated and cooled at high temperatures for a long time are completely different from ordinary salts, that is, they do not dissolve in water. It has the property of not penetrating moisture, and when it is powdered and added with water, adhesive force is generated, so that it can be used as an adhesive or a solid having a certain shape.

Charcoal is widely used to have the effect of purification (deodorization), oxidation prevention, far infrared emission, anion emission, humidity control, electromagnetic shielding.

Germanium is known to release far-infrared rays that are beneficial to humans, promote immune interferon production and oxygen supply, automatically regulate blood pressure, and improve blood circulation by purifying blood.

Ocher is very excellent in humidity control, and because a large amount of far-infrared rays are emitted by heat or natural light, as well as smooth the blood circulation of the body, and excellent thermal and thermal insulation effect.

Elvan is a deodorizing effect and water purification effect that absorbs, decomposes and removes harmful substances to the human body, and contains a lot of minerals to facilitate the body's blood circulation, which is effective in adult diseases such as high blood pressure and diabetes.

Conventionally, it has been common to make an environment having a characteristic such as salt room, charcoal room, ocher room as one of the above materials in a jjimjilbang, sauna, home, and the like. However, this method is difficult to work because each material is constructed in a separate space, and it is expensive to maintain and repair, and requires a lot of time and space to create a unique environment. have.

In addition, modern people living modern busy daily life have to move sequentially through the environment with separate characteristics in order to experience the efficacy of multiple materials, and consume a lot of energy to heat each of them. There was a problem that had to be done, and a problem that had to be equipped separately for various experiences.

The present invention is to overcome the above-mentioned conventional problems, an object of the present invention is to fill a mixture or filled with a mixture of various materials that emit far infrared rays, such as salt, charcoal, germanium, ocher, elvan, jade, which is beneficial to the human body. By manufacturing a panel, and attaching the product to the structure frame to provide a panel and the structure that emits far-infrared rays having various effects beneficial to the human body.

The panel and the structure of the far-infrared ray emitted according to the present invention for achieving the object of the present invention has a bottom surface, partitioned into a charcoal layer, germanium layer, ocher layer, elvan, jade layer, salt layer in a mold having a receiving space The panel is manufactured by filling the panel, and the panel is attached to a structural frame manufactured in a desired shape using materials such as steel or wood.

In addition, the panel and the structure of the far-infrared emission according to the present invention has a bottom surface, to manufacture a panel by filling a mixed far-infrared emission mixed with a plurality of materials emitting far-infrared infrared rays in a mold having a receiving space, and the panel It is made by attaching to a structure frame manufactured to a desired shape using materials such as steel or wood.

Alternatively, the panel and the structure of the far infrared ray emitting device according to the present invention have a bottom surface, and the panel is manufactured by filling a mixture having selected and mixed one of a plurality of materials emitting salt and far infrared rays into a mold having a receiving space. The panel is attached to a structure frame made of a desired shape using materials such as steel or wood.

1 is a plan view of a panel emitting far infrared rays according to a first embodiment of the present invention,

2 is a cross-sectional view taken along line AA ′ of FIG. 1;

3 is a perspective view of a structure attached to a panel that emits far infrared rays according to a first embodiment of the present invention,

4 is a plan view of a panel emitting far infrared rays according to a second embodiment of the present invention,

5 is a cross-sectional view taken along line BB ′ of FIG. 4;

6 is a perspective view of a structure with a panel that emits far infrared rays according to a second embodiment of the present invention,

7 is a plan view of a panel emitting far infrared rays according to a third embodiment of the present invention,

8 is a cross-sectional view taken along line C-C 'of FIG.

9 is a perspective view of a structure with a panel that emits far infrared rays according to a third embodiment of the present invention.

※ Explanation of Signs of Major Parts of Drawings

10, 20, 30: mold 11: salt layer

12: charcoal layer 13: germanium layer

14: ocher layer 15: elvan rock layer

16: Jade layer 21: Mixed far infrared ray emission

31: mixed salt plate 100, 200, 300: structure frame

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a plan view of a panel emitting far infrared rays according to a first embodiment of the present invention, FIG. 2 is a sectional view taken along line AA ′ of FIG. 1, and FIG. 3 shows a panel emitting far infrared rays according to a first embodiment of the present invention. 4 is a plan view of a panel emitting far infrared rays according to a second embodiment of the present invention, FIG. 5 is a cross-sectional view taken along line BB ′ of FIG. 4, and FIG. 6 is a second embodiment of the present invention. FIG. 7 is a perspective view of a panel having a panel emitting far infrared rays according to the present invention, FIG. 7 is a plan view of a panel emitting far infrared rays according to a third embodiment of the present invention, FIG. 8 is a cross-sectional view taken along line CC ′ of FIG. A perspective view of a structure with a panel that emits far infrared rays according to a third embodiment of the present invention.

The panel and the structure in which far infrared rays are emitted according to the first embodiment of the present invention are manufactured as follows.

First, the panel which emits far-infrared rays indicated by the entire reference 1 is manufactured as follows.

A mold 10 having a bottom surface and having a receiving space formed therein is formed, and a salt layer 11 is formed on one side of the receiving space of the mold 10.

The salt layer 11 is selected from any one of ordinary salt, rock salt or bamboo salt into a heating furnace and heated to 850 to 1300 ℃ to melt in a liquid state and the melt produced in the melting process of a predetermined predetermined shape It is prepared by a molding process poured into the mold and a cooling process of cooling and solidifying the melt poured on the mold.

The salt layer 11 may be prepared by mixing 70 to 90 wt% of powder and 10 to 30 wt% of a binder of one selected from general salt, rock salt or bamboo salt.

A charcoal layer 12 is formed by mixing 70 to 80wt% charcoal powder and 20 to 30wt% caking agent on one side of the salt layer 11, and a germanium powder 70 to 80wt with a surface parallel to one side of the charcoal layer 12. % And 20 to 30 wt% of a binder are mixed to form a germanium layer 13, and on one side of the germanium layer 13, an ocher powder 14 is mixed by mixing 80 to 90 wt% of an ocher powder and 10 to 20 wt% of a binder. It forms, the ganban rock powder 70 ~ 90wt% on one side of the ocher layer 14 and 10 ~ 30wt% caking agent to form a gangan rock layer 15, 70 ~ 90wt of jade powder on one side of the bedrock stone layer 15 The jade layer 16 is formed by mixing% and 10 to 30 wt% of a binder, and the jade layer 16 is formed on one side of the jade layer 16 to the other side of the receiving space of the mold 10.

Then, a material emitting a plurality of far-infrared rays is respectively partitioned in the receiving space to dry the filled mold 10.

The filling order of the material emitting the far-infrared ray filled in the receiving space of the mold 10 may be changed in the illustrated order, but the material layer 11 emitting the far-infrared infrared rays when each of the receiving space of the mold 10 is filled. , 12, 13, 14, 15, 16) It is preferable to make the composition ratio the same.

In addition, the powder of the material that emits the far infrared rays is preferably about the size of the sand, the binder is preferably clay or gypsum that can maintain the coking force even at high heat.

The weight ratio of each material to the caking agent increases the effect of far infrared ray emission as the content of the material emitting far infrared rays increases, but when the content of the caking agent decreases, the caking force is reduced so that the material emitting far infrared rays from the structure is separated. Since this occurs, it is preferable to prepare in the weight ratio of the above-described material and the binder.

In addition, the salt layer (11), the germanium layer (13), the ganban rock layer (15), the jade layer (16) is a layer of rock salt or bamboo salt lumps or germanium, ganban stone, jade gemstones directly cut processing the shape thereof After the manufacture of the shape of may be attached to the receiving space of the mold (10).

Next, by attaching the panel (1) manufactured in this way to the structure frame 100 produced in a predetermined shape using a plate such as steel or wood it can be produced a structure in which far infrared rays are emitted.

The panel and the structure in which the far infrared rays are emitted according to the second embodiment of the present invention are manufactured by mixing all the composition ratios according to the first embodiment.

First, the panel emitting far infrared rays indicated by the entire reference number 2 is manufactured as follows.

A mold 20 having a bottom surface and having an accommodating space therein is manufactured and filled with the far infrared rays 21 mixed in the accommodating space of the mold 20.

Mixed far-infrared emission (21) is salt powder 50 ~ 60wt%, charcoal powder 5 ~ 10wt%, germanium powder 5 ~ 10wt%, ocher powder 5 ~ 15%, elvan powder 5 ~ 15%, jade powder 5 ~ 15% Is mixed with distilled water at an appropriate ratio, and the mixture produced in the mixing process is put in a heating furnace and heated to 850 to 1300 ° C. to melt in a liquid state, and a melt formed during the melting process is previously set in a predetermined shape. The pouring into the molding process and the cooling process for cooling and solidifying the melt poured into the mold is prepared.

Then, the mold 20 to which the far-infrared emission 21 mixed in the accommodation space is attached is dried.

In addition, the melt produced in the melting process may be prepared by pouring directly into the mold 20 to cool.

Next, by attaching the panel 2 manufactured in this way to a structure frame 200 manufactured in a predetermined shape using a plate such as steel or wood, a structure in which far infrared rays are emitted can be manufactured.

The panel and the structure in which the far infrared ray is emitted according to the third embodiment of the present invention are manufactured as follows.

First, the panel emitting far infrared rays indicated by the entire symbol 3 is manufactured as follows.

A mold 30 having a bottom surface and a receiving space formed therein is manufactured, and the mixed salt plate 31 is filled in the receiving space of the mold 30.

Mixed salt plate 31 is a melting process of melting 70 ~ 90wt% salt powder and 10 ~ 30wt% of one material selected from the material that emits far infrared rays and then melt it in a liquid state by heating it to 850 ~ 1300 ℃ in a heating furnace It is prepared by the molding process of pouring the melt produced in the melting process into a predetermined shape of the mold and a cooling process of cooling and solidifying the melt poured on the mold.

It is preferable to use charcoal, germanium, loess, elvan, or jade as the material emitting far infrared rays.

Then, the mold 30 filled with the mixed salt plate 31 in the receiving space is dried.

In addition, the melt produced in the melting process may be directly poured into the mold 30 and cooled to manufacture.

Next, by attaching the panel 3 manufactured in this way to the structure frame 300 manufactured in a predetermined shape by using a plate such as steel or wood, it is possible to manufacture a structure in which far infrared rays are emitted.

The structure frames 100, 200, and 300 of the first, second, and third embodiments may be used by selecting any one of a circular, polygonal, dome, and tunnel shape, and the structure frames 100, 200. , 300) may be formed into a roof shape, and a wall may be formed, and the installation position may also be variously modified and installed using a support member such as a bottom surface of the room, an intermediate location of the room, and a ceiling of the room.

In addition, after the above-described materials for emitting far infrared rays are manufactured in a tile shape, the structures may be directly attached to the structure frames 100, 200, and 300 to manufacture a structure for emitting far infrared rays. At this time, the size of the tile is 5 ~ 40cm in width and length.

Alternatively, the far-infrared ray emitting panels 1, 2, and 3 manufactured through the first, second, and third embodiments may be attached to walls and ceilings of general homes, offices, schools, or church buildings.

As described above, the panel and the structure in which the far infrared rays are emitted according to the first, second, and third embodiments of the present invention are attached to a mold, and a panel-type building material is used for construction. Since construction can be dried, construction can be simplified, anyone can easily install, shorten construction period, and save time and money in maintenance and repair.

In addition, by having a panel and a structure filled with a plurality of materials that emit far infrared rays, or a mixture of a plurality of materials, respectively, by creating an environment that can simultaneously experience a variety of effects on a plurality of materials, each feature of the conventional You can save a lot of time and space to create an environment with this, and the time and cost required for ordinary people living in busy daily life to search for environments with separate characteristics to experience the efficacy of various materials. There is an effect to save.

In addition, by attaching a panel that emits far infrared rays on the wall or ceiling of a general home or office, there is an effect that can experience the various effects of the material that emits far infrared rays while daily life.

In addition, even if the panel or structure is not painted separately, each material has its own color or light, which retains its color or light even after the panel or structure is finished, and is also suitable for mixed far-infrared emissions. Because of the color of the mix, the appearance of the plate is naturally beautiful effect.

Claims (9)

In the panel where far infrared is emitted, A mold having a bottom surface and having a receiving space therein; A salt layer selected from any one of ordinary salts, rock salts or bamboo salts formed on one side of the receiving space of the mold, put into a heating furnace, heated to 850 to 1300 ° C., melted, poured into a mold and cooled; Charcoal layer prepared by mixing the charcoal powder 70 ~ 80wt% and the binder 20 ~ 30wt% formed on one side of the salt layer; A germanium layer prepared by mixing 70 to 80 wt% of germanium powder and 20 to 30 wt% of a binder formed on one side of the charcoal layer; An ocher layer prepared by mixing 80 to 90 wt% of ocher powder and 10 to 20 wt% of a binder formed on one side of the germanium layer; An elvan rock layer prepared by mixing 70 to 90 wt% of elvan powder and 10 to 30 wt% of caking agent formed on one side of an ocher layer; Far-infrared ray is emitted panel characterized in that consisting of an jade layer made by mixing the jade powder 70 ~ 90wt% and the binder 10 ~ 30wt% formed on one side of the elvan rock layer to the other side. The method of claim 1, The salt layer is a panel that emits far-infrared rays, characterized in that manufactured by mixing 70 ~ 90wt% of powder and 10 ~ 30wt% of binder selected from any one of the salt, rock salt or bamboo salt. The method of claim 1, The salt layer, germanium layer, ganban stone layer, jade layer is a panel that emits far-infrared rays, characterized in that the lumps of rock salt or bamboo salt and germanium, ganban stone, jade ore directly cut and attached to the receiving space of the mold. In the panel where far infrared is emitted, A mold having a bottom surface and having a receiving space therein; 50 ~ 60wt% salt powder, 5 ~ 10wt% char, 5 ~ 10wt% germanium powder, 5 ~ 15% ocher powder, 5 ~ 15% elvan powder, 5 ~ 15% jade powder 5 ~ 15% And then it is heated to 850 ~ 1300 ℃ in a furnace to melt and poured into the mold to form a panel after the far-infrared radiation, characterized in that consisting of a mixed far-infrared emission cooled. In the panel where far infrared is emitted, A mold having a bottom surface and having a receiving space therein; 70 ~ 90wt% of salt powder filled in the receiving space of the mold and 10 ~ 30wt% of powder of the selected one which emits far infrared rays are mixed, and then it is heated in a furnace to 850 ~ 1300 ℃ and poured into the mold. Far-infrared ray is emitted panel characterized in that it consists of a mixed salt plate cooled after molding. The method of claim 5, Far infrared ray is emitted material is charcoal, germanium, ocher, elvan, jade is far-infrared panel. The structure of claim 1 or 4 or 5, wherein the far-infrared rays are emitted, characterized in that the frame made by the panel is attached to the frame attached. The method of claim 7, wherein The frame is a structure that emits far-infrared rays, characterized in that any one selected from the shape of a circle or polygon, dome or tunnel (Tunnel). The method of claim 7, wherein The structure that emits far infrared rays is a structure that emits far-infrared rays, characterized in that the roof and the wall are constituted by selecting any one of a circular or polygonal, a dome or a tunnel type.