KR200312294Y1 - Far-infrared radiation structure - Google Patents

Abstract

The present invention is to powder the far-infrared radiating material to be sealed in a gel (gel) in the hose or flexible pack in a gel state and arranged in close contact with the heating line to increase the user's comfort and enjoy various health promotion effects It relates to one far infrared emitter.

The far-infrared radiator according to the present invention is a far-infrared radiator that is heated by a heating unit heated by electricity supply and hot water circulation, etc. to emit far infrared rays. The far-infrared radiation portion, which is enclosed in a hose or flexible pack with a gel material, and a fixing groove for fixing the heat-generating portion and the far-infrared radiation portion at the lower portion of the heat generating portion and the far infrared radiation portion arranged on the same line is provided on the upper surface thereof. The fixed face layer is formed, and the compressed face layer made of a heat resistant and durable material laminated on the heat generating part and the far infrared ray radiating part to provide cushioning and comfort is provided.

Description

Far-infrared radiation structure

The present invention relates to a far-infrared radiator, and more particularly, to far-infrared radiation effect by increasing the far-infrared radiant material by powdering and sealing it in a gel state in a hose or flexible pack so as to be in close contact with a heating part. It relates to a far infrared emitter.

Far infrared rays are 3 ~ 1000㎛ of the wavelength range of light, which has stronger heat action than visible light, and radiant energy is direct and instantaneous heat transfer and heats up quickly and saves energy. Dry heating, heating, heat treatment, health products, food processing, It is widely used for building interior materials, household goods, and biological actions of animals and plants.

In addition, it is found that far-infrared rays are emitted in large quantities from natural ore such as jade, elvan, germanium stone, or processed stone such as ceramic material made by baking clay, porcelain, or ceramic material which is formed by heating and heating powdered far-infrared radiation minerals. In addition, it can be seen that the health supplement products using minerals that emit far-infrared rays such as natural or processed ores have been recently developed and commercialized.

Representative products using the conventional far-infrared radiator can be seen that the coin-sized far-infrared radiator is attached to bedding or furniture such as electric thermal insulation or non-electric mattress, cushion, sofa, or clothing such as shoes or clothing.

1 is a view for explaining a thermal insulation mat that is one of the typical products using a conventional far-infrared radiator, as shown in Figure 1 is a general thermal insulation mat 1 is a top surface of the mat (1) having a heating portion (2) Far infrared ray radiator 3 is provided. In particular, the far-infrared radiation unit 3 is a plurality of far-infrared-emitting minerals, for example, jade, macsumite, amethyst, ceramic, germanium stone, ocher, charcoal, etc. pieces are disposed on the mat surface, the heat generating unit (2) According to the heating of the far-infrared divergent mineral material is made of a structure that emits far-infrared rays.

However, in the conventional far-infrared radiator as described above, first, the hard mineral pieces such as jade are placed on the surface of the mat, medical device, or clothing in various cube shapes such as circular, hexagonal, and quadrangular bodies to be in contact with the user's body. If there is a problem that causes inconvenience in use due to the hard foreign matter.

Second, in the case of a mat, a medical device or a garment which is heated by a hot water circulation, the hose for hot water circulation is pressed by a hard mineral material when it is used for a long time, which causes disadvantages in circulation of the hose.

Third, when the power is cut off by being disposed on the surface of the mat, medical equipment or clothing, the far-infrared radiator has a problem of being rapidly cooled by mineral fragments having a poor heat storage function.

Accordingly, an object of the present invention is to seal the far-infrared radiating material into a hose or flexible pack in a gel state by pulverizing the far-infrared radiant material and arrange it in close contact with the same line of the heating part to increase the user's comfort and increase various health effects. To provide a far-infrared radiator to enjoy.

In order to achieve the above object, the far-infrared radiator according to the present invention, in the far-infrared radiator radiated far infrared rays by heating by a heating unit heated by electricity supply and hot water circulation, etc., arranged closely on the same line as the heating unit. And the far-infrared radiant material is powdered and gelled, and the far-infrared radiator is inserted into a hose or flexible pack with a gel material, and the heating part and the far-infrared radiator are fixed under the same heat generating part and far-infrared radiating part. A fixed groove layer is formed on the upper surface of the fixed groove, and the compressed shoulder layer is made of a heat-resistant and durable material laminated on top of the heat generating portion and the far-infrared radiation portion to provide cushioning and comfort.

1 is a view for explaining a thermal insulation mat that is one of the typical products using a conventional far-infrared radiator.

Figure 2 is a structural diagram of the far infrared radiator according to the present invention.

3 is a view for explaining a hot water circulation type thermal mat using the far-infrared radiator of FIG.

4 is a view for explaining a first embodiment of the far-infrared radiator used in the thermal mat of FIG.

5 is a view for explaining a second embodiment of the far-infrared radiator used in the thermal mat of FIG.

Explanation of symbols on the main parts of the drawings

10: mat 11: heat generating portion

12: far infrared radiation portion 13: compressed cotton layer

14: fixing groove 15: fixing surface layer

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a structural diagram of a far infrared radiator according to the present invention.

Referring to Figure 2, the far-infrared radiator according to the present invention, the heating portion 11 is heated by the electricity supply and hot water circulation, and the like, the heating portion 11 is heated by the radiating far infrared rays and the heat generating portion 11 Fixing the heat generating portion 11 and the far infrared radiating portion 12 in the lower portion of the far infrared radiating portion 12 arranged in parallel with the same line and the heat generating portion 11 and the far infrared radiating portion 12 arranged in the same line. Compression made of a heat-resistant and durable material is laminated to the fixing surface layer 15 formed on the upper surface and the heat generating portion 11 and the far-infrared radiation portion 12 to provide cushioning and comfort The backing layer 13 is provided.

In particular, the far-infrared radiating part 12 is a far-infrared radiating mineral material is powder-treated in a gel (gel) state and packed into a hose or a flexible pack, close to one side or both sides in the same line with the heat generating portion (11). Are arranged.

In addition, the far infrared radiation unit 12 is arranged on one side or both sides of the heating unit 11 in an independent structure to match the width of the thermal mat, health clothing, winter clothes, physical therapy device, etc. to which the far infrared radiator of the present invention is applied. In this case, the far-infrared radiation unit 12 of the independent structure is connected to each other in a state in which the middle of the hose or the fusible pack is blocked at a predetermined unit length.

In order to help the understanding of the far-infrared radiator having the above-described structure, a case where the hot water is circulated below and applied to a hot water circulation type thermal mat to obtain the heating effect will be described as an example.

FIG. 3 is a view for explaining a hot water circulation type thermal mat using the far infrared radiator of FIG. 2, and FIG. 4 is a view for explaining a first embodiment of the far infrared radiator used for the thermal mat of FIG. 3. 5 is a view for explaining a second embodiment of the far infrared radiator used in the thermal mat of FIG.

Referring to these drawings, the hot water circulation type thermal mat using the far-infrared radiator according to the present invention is provided with a small electric hot water boiler 20 as shown in FIG.

In addition, the heating unit is installed according to the circulation path of the circulating water heated by the hot water boiler 20 separately from the hot water boiler 20 and the heat generating part 11 of the circulation hose type for transmitting the heated hot water heat is arranged therein. The mat 10 is comprised.

The thermal mat 10 according to the present invention is arranged in a predetermined shape to match the mat size so that the heat generating portion 11 of the circulation hose form evenly to the entire mat surface as shown in FIG.

In addition, as shown in FIGS. 4 and 5, the far-infrared radiating part 12 in the form of a hose or a flexible pack is arranged closely to the heat generating part 11 in the same line as the heat generating part 11.

At this time, the far-infrared radiation unit 12 is a far-infrared radiation mineral, for example, jade, macsumite, amethyst, ceramic, germanium stone, ocher, charcoal, etc. are powdered and then treated with a gel (Gel) material hose or flexible Squeezed into the castle pack and vacuumed.

The far-infrared radiating part 12 is arranged closely to one side or both sides of the heat generating part 11, in particular, as shown in FIG. Far-infrared radiation portion 12 in which the radiation minerals are enclosed is arranged, or as shown in FIG. 5, the far-infrared radiation portion 12 in which the far-infrared radiation minerals are enclosed is arranged only on one side of the heat generating unit 11.

In particular, the far-infrared radiation portion 12 in the form of a hose or soluble pack filled with the far-infrared radiation mineral in the gel state is arranged on one side or both sides of the heat generating portion 11 in an independent structure to match the width of the mat.

In this case, the far-infrared radiation unit 12 of the independent structure is connected to each other in a state in which the middle of the hose or the fusible pack is blocked at a predetermined unit length. Therefore, it is possible to minimize the leakage portion of the far-infrared radiation mineral in the gel state when the far-infrared radiation portion 12 made of a hose or soluble pack.

Fixing grooves for fixing the movement of the heat generating portion 11 and the far infrared radiation portion 12 as shown in Figure 4 and 5 in the lower portion of the heat generating portion 11 and the far infrared radiation portion 12 arranged on the same line. The fixed surface layer 15 with which 14 was formed in the upper surface is provided.

In addition, the upper surface of the heat generating portion 11 and the far infrared ray radiating portion 12 is laminated with a compressed cotton layer 13 made of a heat-resistant and durable material that provides cushioning and comfortable conditions to the human body.

On the other hand, the far-infrared radiator according to the present invention can also be applied to electric heating type thermal mats, health clothes, winter clothes, physical therapy devices, etc. In this case, to facilitate the activity of the user wearing them, for example, the trunk, arms, legs Manufactured in batches separated by parts.

Referring to the accompanying drawings, an embodiment of a thermal mat using a far-infrared radiator having the above configuration is as follows.

The hot water produced by heating in the small hot water boiler 20 is discharged to the heat generating part 11 in the form of a circulation hose on the mat 10 side, and as shown in FIGS. 4 and 5 on the entire surface of the mat 10. The heat is transferred to the far-infrared radiation unit 12 and the compression face layer 13 while passing through the heat generating unit 11 formed in a curved shape, and then flows back into the hot water boiler 20.

At this time, when the heated circulating water passes through the heat generating portion 11 inside the mat 10 through the circulation hose, the far infrared ray emitting mineral material of the far infrared ray radiating portion 12 that receives heat from the heat generating portion 11 receives far infrared rays. Radiates.

The compressive face layer 13 which receives heat from the heat generating part 11 transfers heat to the mat surface to heat the mat, and the far infrared ray radiating part 12 transmits far infrared rays to the mat surface through the compressed face layer 13. Radiates.

Therefore, the far-infrared radiating part 12 of the gel state is in close contact with the hot water circulation hose which is a heat generating source to maximize the divergence of the far infrared rays which is beneficial to the human body due to the efficient heating, and the sealed body at a predetermined pressure prevents the hot water circulation hose from being pressed. To smooth the flow of circulating water.

What has been described above is just one embodiment of the far-infrared radiator according to the present invention, but the hot water circulation type thermal mat which is intended to obtain the heating effect by circulating hot water as an example, but not limited to this by electric supply It would be said that the technical spirit of the present invention is to the extent that it can be applied to an electric heating type thermal mat or other health clothing, winter clothes, medical equipment, etc. to obtain a heating effect through the heating heating wire.

As described above, the far infrared emitter according to the present invention has the following effects.

First, the far-infrared rays obtained from the hard far-infrared radiation minerals attached to the surface are obtained from the hose or the fusible pack with the soft gel inside, so that the inconvenience of use due to the hard foreign matter is eliminated when contacted with the user's body. It can be used without discomfort, and it is effective to provide the best conditions to the general public, as well as the use of the elderly, pregnant women, recovering patients, patients and the like.

Second, the far-infrared radiation portion of a certain pressure is arranged on one side or both sides of the heating portion to secure the space to prevent the pressing phenomenon of the heating portion to maximize the far-infrared radiation effect.

Third, since the far-infrared radiator is arranged inside, the heat storage function is improved, and thus, there is an advantage of contributing to the effect of power saving by maintaining latent heat for a long time when the power is cut off.

Claims (3)

In the far-infrared radiator which is heated by a heating unit heated by electricity supply and hot water circulation, etc. to radiate far infrared rays, A far-infrared radiation unit arranged closely on the same line as the heat generating unit, the far-infrared radiant material powder-treated, and injected into a hose or flexible pack with a gel state material; A fixing surface layer having a fixing groove formed at an upper surface thereof to fix the heating portion and the far infrared radiation portion at the lower portion of the heat generating portion and the far infrared radiation portion arranged on the same line; Far-infrared radiator characterized in that the compression face layer made of a heat-resistant and durable material laminated on top of the heat generating portion and the far infrared radiation radiator to provide cushioning and comfort. The method according to claim 1, wherein the far infrared radiation unit, Far-infrared radiator, characterized in that arranged closely to one side or both sides of the heating portion. The method according to claim 1, wherein the far infrared radiation unit, The hose or flexible pack in which the gel is filled with far-infrared radiation minerals is installed in an independent structure according to the width of the mat, and the independent structure of the hose or the flexible pack is connected to each other in a state in which the intermediate is blocked at every unit length. Far infrared ray emitter.