KR19990064743A - long distance infrared radiation system - Google Patents

Abstract

The present invention relates to a far-infrared generator for smoothly inducing metabolism of the human circulation system through the heat action, the object of the present invention is to arrange the far-infrared radiator around the heating plate of the heating device to promote the emission of far infrared rays To provide a far-infrared radiation device.

The present invention for achieving the above object is a burner 10 for generating a flame, a heating plate 12 for performing a heat exchange action by receiving the flame of the burner 10, and a base for supporting the heating plate 12 ( 17) and a far-infrared radiator 14 which is stacked along the circumference of the heat generating plate 12 and has an interlayer spacer 15.

Description

Long Infrared Radiation System

The present invention relates to a far-infrared generator for smoothly inducing the metabolism of the human circulation system through the heat action, and in particular, does not require a separate blast furnace device and heating the ceramic brick or ganban stone for far-infrared radiation in a narrow place It relates to a far infrared radiation device that can be made.

Elvan and ceramic natural stones are known to emit a large amount of far infrared rays that act effectively on their own. By using the far-infrared radiation of natural stone, heat treatment, one of health treatments, can be performed.

Thermal therapy penetrates far-infrared rays deep into the skin to promote metabolism of the human circulatory system, and is used by stacking ceramic bricks or elvan stones to obtain a large amount of far-infrared radiation.

In particular, the stacked far-infrared radiator bricks are heated to several hundred degrees in the blast furnace so that far-infrared rays radiated from the stacked far-infrared radiators such as ceramics can effectively penetrate the human skin.

However, since natural elvan or ceramic does not have a uniform shape, in order to stack them to a desired height and width, the far-infrared radiant in the form of germanium, elvan, ceramic or jade is molded and dried in a constant shape in advance. After firing at about (1,200 ℃) to produce a radiator brick.

Until now, in order to obtain the thermal treatment effect using far-infrared rays, the stacked far-infrared radiators are introduced into the blast furnace, heated for a predetermined time, and then taken out to the outside of the blast furnace, and then the far-infrared rays emitted from the heated far-infrared radiator are exposed for a predetermined time. When the heated far infrared laminated brick naturally cools and reaches a certain temperature, it must be put back into the blast furnace and reheated, so that continuous thermal treatment cannot be performed.

In addition, such traditional heating and natural cooling and reheating programs are less energy efficient. In particular, the existing far-infrared radiator for heat treatment needs a large area because it requires a blast furnace for heating the far-infrared radiator and a space for taking out the heated far-infrared radiator from the blast furnace, respectively.

An object of the present invention is to provide a far-infrared radiation device that can be installed in a narrow space to obtain a heat treatment effect using far-infrared in the room.

Another object of the present invention is to provide a far-infrared radiation device that is easy to install and that can maximize the energy efficiency for heating the far-infrared radiator.

1 is a perspective view of a far infrared radiation device according to the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view taken along the line B-B in FIG.

4 is a structural diagram of a heating plate applied to the present invention.

5 is a perspective view for explaining another example of the present invention.

※ Explanation of symbols about main part of drawing ※

10: burner 11: crater

12: heating element 13: year

14: far infrared emitter 15: spacer

16: firebrick 17: base

18 Bracket 19 Baffle Plate

20: far infrared radiation plate 21: fastening bolt

The present invention for achieving the above object comprises a burner for heating, a heating plate for radiating heat by receiving the heat of the burner, a base for supporting the heating plate, and a far-infrared radiator stacked along the circumference of the heating plate It is characterized by.

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

1 is a perspective view of the apparatus of the present invention, FIG. 2 is a cross-sectional view taken along the line A-A of FIG. 1, and FIG. 3 is a cross-sectional view taken along the line B-B of FIG.

As referred to herein, the flame generated from the burner 10 is installed to be introduced into the flame inlet of the heating element 12 through the fireball (11).

The heating element 12 is manufactured in a baffle structure having a plurality of horizontal baffle plates 19 therein. Although the baffle plate 19 shows a horizontal type in the drawing, the concept of the present invention is not limited thereto, and may be manufactured as a vertical baffle plate as another embodiment.

The heating element 12 is fixedly installed with a fixed bracket 18 on the base 17 made of a heat insulating material.

A general brick or a firebrick 16 is disposed around the periphery of the base 17, and the far infrared radiator 14 is laminated in multiple stages so as to cover the heating element sufficiently in the periphery of the heat generator 12. The far-infrared radiator 14 may be manufactured in the form of a brick using a material that emits a large amount of far-infrared rays such as ceramic powder, ganban stone powder, jade stone powder, and germanium powder as a main raw material.

On the other hand, when the far-infrared radiator 14 manufactured in the form of a brick is disposed on the heating element 12, the spacer 15 is inserted between the layer and the layer of the radiator brick to form an interlayer space portion.

The heat generating element 12 may be in contact with the outside air through the space portion formed by the spacer 15, thereby increasing the heat generating efficiency and increasing the heat transfer efficiency of the far-infrared radiator bricks, and visually showing the heating state of the heat generating element 12. You can check it.

The remaining heat exchanged while passing through the baffle plate 19 of the heating element 12 is provided with a communication to be exhausted to the outside through the flue 13 that can be provided on one side of the upper end of the heating element 12.

Referring to the operation of the present invention configured as described above is as follows.

First, when the flame according to the operation of the burner 10 is introduced into the lower flame inlet of the heating element 12 having a baffle structure along the fireball 11, the flame moves horizontally along the baffle plate 19 inside the heating element. It is upwardly discharged to the outside through the year 13. At this time, the heating element 12 having the structure as shown in FIG. 4 performs heat exchange to heat the surface of the heating element, and the far-infrared radiator 14 disposed adjacent to the heating element 12 begins to be heated by this surface heating.

At this time, through the space portion formed by the interlayer spacers 15 of the far-infrared radiator 14, it is possible to visually check the heating element 12 that has been heated. Also, through the space portion, the convection of air for heat transfer is facilitated and the far-infrared radiator. Increase the heating rate of (14).

Accordingly, when the far-infrared radiator 14 is heated to a predetermined temperature, it is possible to obtain a heat treatment effect by the far-infrared rays from that time, and to manually or automatically turn on / off the burner 10 based on the temperature value measured by the temperature sensor. By adjusting, the temperature of the far-infrared radiator can be maintained at a constant range at all times.

5 shows another embodiment of the present invention. Here, a state in which the far-infrared radiation plate 20 is attached to both surfaces of the heating element 12 to be heated by the burner 10 is shown.

As described above, the far-infrared radiating plate 20 is manufactured through a molding and firing process using a material that emits a large amount of far-infrared rays such as ceramic powder, ganban stone powder, jade stone, germanium powder as a main raw material.

Looking specifically at the structure of the radiation plate attached far-infrared radiation device, although not shown in the drawings, a bolt for fastening the radiating plate 20 to any specific location on both sides of the heating plate 12 is fixedly attached and the fixing bolt After forming a fastening hole in a specific portion of the far-infrared radiation plate 20 to correspond to the position of the combination there is a structure for fixing using a fastening nut (21).

In another embodiment of the present invention, the fastening nut is welded to the heating plate 12 and the fastening bolt is coupled to the fastening nut through the fastening hole provided in the far infrared radiation plate 20 to fix the far infrared radiation plate to the heating plate. It may be.

The far-infrared radiation device of another embodiment of the present invention will have a combined function of the heating function of the room and the heat treatment function using the far-infrared emission.

As described above, the present invention can miniaturize the far-infrared radiator capable of obtaining a thermal effect without degrading its function, thereby exhibiting a unique effect of not being restricted by its installation area or installation place.

In addition, the present invention can maintain the temperature of the far-infrared radiator of the far-infrared radiator always at a constant temperature range to obtain an energy saving effect and save the down time during the heating time which is a disadvantage of the existing equipment.

In addition, the present invention enables the manufacture of an indoor heating device having a far-infrared radiation function that can obtain a thermal effect.

Particularly, in the present invention, the burner is specified as a heating means, and then the far-infrared radiator (or radiating plate) is heated by heat generated on the transfer passage (heating element) by using the flame discharged from the burner. It does not limit the technical idea. It will be apparent that the technical idea of the present invention can be applied to any heating means such as an electric heater, a steam heater, or the like.

Claims (3)

Burner 10 for generating a flame, a heating plate 12 for receiving heat from the burner 10 to perform heat exchange, a base 17 for supporting the heating plate 12, and the heating plate 12 A far-infrared radiation device comprising a far-infrared radiator (14) stacked along a circumference and having an interlayer spacer (15). 2. The far-infrared radiation device according to claim 1, wherein the heat generating plate (12) has a baffle structure formed by a baffle plate (19) partitioning its interior. A burner 10 generating a flame, a heating plate 12 which receives the flame of the burner 10 to perform a heat exchange action, and fastening bolt means installed at specific places on both sides of the heating plate 12; Far-infrared radiation apparatus comprising a far-infrared radiation plate (20) provided with a fastening hole for coupling to the fastening bolt means, and a fastening nut (21).