KR19990037806A - infrared ray radiation apparatus - Google Patents

Abstract

According to the present invention, a plurality of ceramic blocks are stacked to form a far infrared ray radiator, and a separate heat insulating cover is provided to surround the radiant to form a heating part inside the radiator and to increase heating efficiency of the radiant. This makes it possible to easily heat the radiator to a high temperature and to provide a far-infrared radiation apparatus which can radiate far-infrared rays for a long time at a lower cost. In the construction of the far-infrared radiation apparatus A, the heating means 13 is provided. A plurality of ceramic blocks 12 are stacked on the main body 11 to form a far-infrared radiant body 1, and a heat insulating cover 2 which is guided and transferred by a conveying rail 21 on one side of the radiant body 1 is installed. Far infrared ray radiation apparatus characterized in that.

Description

Far Infrared Radiation Apparatus

The present invention relates to a far-infrared radiation apparatus, and more particularly, to stack a plurality of ceramic blocks to form a far-infrared radiation, and to form a heating part in the interior of the radiation, and at the same time to increase the heating efficiency for the radiation, By providing a separate removable insulation cover to be able to cool, it is possible to easily heat the radiator to a high temperature, and at the same time to provide a far-infrared radiation device that far infrared radiation is radiated for a long time.

In general, the most common method for obtaining a heat treatment effect that is beneficial to health is the method of heating the ceramics so that the human body can be irradiated with a large amount of far infrared rays radiated from the heated ceramics. After stacking and heating a large number of ceramic blocks, a number of far-infrared radiation apparatuses have been used that can be expected to have a therapeutic effect by far-infrared rays radiated from the ceramic blocks by surrounding or surrounding the heated ceramic blocks.

The far-infrared radiation apparatus, which is widely used as described above, moves a plurality of ceramic blocks into a separate heating chamber in a state in which a plurality of ceramic blocks are stacked on a mobile truck, and then heats the ceramic blocks stacked for a predetermined time in a heating chamber, and then heats the ceramic again. The block is moved outside the heating chamber to allow the human body to radiate a large amount of far infrared rays radiated from the heated ceramic block.

However, the conventional far-infrared radiation apparatus having the above-described configuration is capable of achieving a therapeutic effect by the far-infrared radiation radiated from the heated ceramics by heating and regulating the ceramic block to maintain high heat. Since it cools rapidly while moving from the inside to the outside of the heating chamber, in order to heat a large number of laminated ceramic blocks outside and maintain the heat storage state for a long time at high heat, a large amount of ceramic blocks must be provided as well. It requires a lot of fuel consumption to heat up, so there was an uneconomic problem.

In addition, in order to heat the ceramic blocks stacked in this way outside to maintain a certain temperature, the temperature inside the heating chamber must be relatively high, so in order to withstand such a high temperature atmosphere, the thickness of the heat insulating layer of the heating chamber must be kept thick. There is a problem that the manufacturing equipment cost for the heating chamber increases, and in the process of moving the ceramic block heated by high heat from the inside of the heating chamber to the outside of the heating chamber, the ceramic block is often thrown out by cracking due to rapid cooling. Heated ceramic blocks are not easy to move due to high heat, and as the ceramic blocks are repeatedly heated and cooled several times, the thermal shock can easily damage the ceramic blocks. Life of the far-infrared radiation system There was a problem such as being shortened.

1 is a perspective view of a device according to the invention

2 is a cross-sectional view of the device according to the invention.

<Description of Symbols for Main Parts of Drawings>

1: copy 2: heat cover 11: body

12: ceramic block 13: heating means 21: transfer rail

Accordingly, an object of the present invention is to solve the problems of the conventional far-infrared radiation apparatus used to move out of the heating chamber in a state in which a plurality of ceramic blocks are stacked and moved inside the heating chamber to be heated and regenerated as described above. In constructing the far-infrared radiation device A, a plurality of ceramic blocks on the main body 11 having the heating means 13 are provided.

(12) is laminated to form a far-infrared radiation (1), characterized in that by installing a heat insulating cover (2) guided by the transfer rail 21 on one side of the radiation (1).

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

1 is a perspective view showing the configuration of a far-infrared radiation apparatus according to the present invention, and FIG. 2 is a cross-sectional view showing the structure of the radiation apparatus according to the present invention, and its configuration is largely comprised of a copying body 1 and a heat insulating cover 2.

The radiator 1 is provided by stacking a plurality of ceramic blocks 12 so that a space is formed therein at a state where the main body 11 on which the heating means 13 is installed is fixedly installed at a predetermined position. Doing.

The heat insulating cover 2 is guided and moved by a rail 21 installed to extend a predetermined length on both bottoms of the copying body 1 in a state in which the door 22 is installed at one side of the copying body when the copying body 1 is heated. (1) is to surround five surfaces except the bottom or to be in an exposed state, and is installed at a distance from one side of the copy (1).

In order to use the far-infrared radiation apparatus (A) of the present invention, first, the radiator 1 must be heated, and a state in which the radiator 1 is completely enclosed by moving the insulation cover 2 on which the radiator 1 is installed. The heating means 13 in the main body 11 constituting the radiator 1 are operated to heat the ceramic blocks 12 stacked on the main body 11 at a high temperature for a predetermined time to reach a predetermined temperature. In order to prevent divergence, the insulation cover 2 enclosing the radiator 1 is moved to its original state to keep the radiated radiator 1 in an exposed state as it is, and the surrounding radiator 1 As a result, people are sitting or standing so that the heat radiated from the copy (1) is cut.

As such, the radiator 1 heated to a high temperature emits and radiates a large amount of far infrared rays from a plurality of ceramic blocks 12, so that far infrared rays act on the human body and thus a predetermined therapeutic effect can be expected.

In this state, after a certain time has elapsed, the radiator 1, which has been heated to a high temperature, gradually cools and falls below a set temperature. Then, the insulation cover 2, which has been moved to one side of the radiator 1, is moved to the radiator 1 side, thereby radiating the radiator 1 After heating the ceramic block 12 to a predetermined temperature by operating the heating means 13 installed in the main body 11 of the copying body 1 as described above, the heat insulating cover 2 is returned to its initial position. By moving, the heat and far-infrared rays emitted from the radiator 1 can be re-extracted for a predetermined time.

In the above configuration, it is not necessary to heat the radiator 1 in a state in which the radiator 1 is completely enclosed as a heat insulating cover 2 when heating the radiator 1, and the radiator 1 heated to a constant temperature gradually cools down. By operating the heating means 13 installed in the main body 1 without enclosing the heat insulating cover 2, the strength of the ceramic block 12 may be continuously maintained while controlling the strength thereof.

In addition, in the configuration of the heating means 13, the ceramic block 12 is not necessarily installed inside the main body 11 in which a plurality of stacks are provided, but is extended to an internal space formed by stacking the plurality of ceramic blocks 12. By doing so, the heating efficiency of the ceramic block 12 can be increased, and the heat source of the heating means 13 can also be used as the heat source.

As described above, although the present invention has been described with reference to the above embodiments, it is not necessarily limited thereto, and various modifications may be made without departing from the scope and spirit of the present invention.

As can be clearly seen from the above description, according to the far-infrared radiation apparatus of the present invention, by using a heating means inside the radiator to directly heat the ceramic block, it is possible to reduce the use of the ceramic block for the heat storage and to generate the combustion for heating the radiator. In addition to significantly reducing consumption, fuel costs can be greatly reduced, and the thickness of the insulation cover surrounding the radiator is reduced to prevent heat dissipation during heating, thereby lowering the manufacturing cost of the device. It is possible to achieve far-infrared radiation effect by radiation by moving only the insulation cover of simple structure instead of the simple structure, and it is possible to use the device more easily and to continuously heat the ceramic block, thereby reducing the consumption of fuel for heating and reducing the ceramic To reduce the thermal shock It provides a useful effect itge to extend the service life of the ceramic block by as much as.

Claims (2)

In constructing the far-infrared radiation apparatus A, a plurality of ceramic blocks 12 are laminated on the main body 11 having the heating means 13 to form a far-infrared radiation body 1, and the radiation body 1 is transferred to one side. Far-infrared radiation apparatus, characterized in that by installing a heat insulating cover (2) guided by the rail (21). The far-infrared radiation apparatus according to claim 1, wherein said heating means (13) is electrothermal heating means using electricity as a heat source.