KR101502437B1 - carbon heater with porous ceramic board - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to porous ceramic board carbon heaters, and more particularly, to porous ceramic board carbon heaters having a porous structure formed by compressing aggregates of 2 to 3 mm particles composed of perlite, kaolin, zeolite, Porous ceramic board; A carbon heating plate composed of a carbon fiber isher which generates heat by electric power, a linear copper plate which transmits electric power, and a glass fiber plate which contains carbon islands and a linear copper plate inside; A reflector configured to reflect the radiant heat forward; A porous ceramic board, a carbon heating plate, and a reflector, which are open to the front side, and a body for supplying power to the carbon heating plate; The carbon fiber papers are arranged side by side in at least two planes on the same plane; The linear copper plate is connected to each end of the carbon islands retaining, one of the linear copper plates being connected to two carbon fiber sheets; The carbon heating plate, the porous ceramic board, and the reflector plate in this order, and the carbon heating plate is composed of a flat plate or a plate concave toward the open direction, The present invention relates to a heater that radiates far infrared rays, anion, and quantum energy, and has a deodorizing and humidity control effect.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a carbon heater,

TECHNICAL FIELD The present invention relates to a porous ceramic board carbon heater, and more particularly, to a porous ceramic board which is formed into a plate structure by high-temperature compression of aggregates of 2 to 3 mm particles composed of perlite, kaolin, zeolite, ilite, elvanite and sodium silicate. A carbon heating plate that is heated by power supply; A reflector configured to reflect the radiant heat forward; A porous ceramic board, a carbon heating plate, and a reflector, which are open to the front side, and a body for supplying power to the carbon heating plate; The carbon heating plate, the porous ceramic board, and the reflector plate in this order, and the carbon heating plate is composed of a flat plate or a plate concave toward the open direction, The present invention relates to a heater that emits far-infrared rays and anions, and has a deodorizing and humidity control effect.

In general, heaters are mainly heated by oil, gas and electric coils, and are used for winter heating, sauna, and fomentation.

Techniques with added stability and functionality in such heaters have been developed and used variously. For example, Korean Patent Laid-Open Publication No. Hei 10-2012-0021004 discloses an antibacterial nano-device using a natural stone panel, A heat generating coil disposed inside the body and corresponding to the opening; And a frame surrounding the outer edge of the body portion, wherein the body portion generates far-infrared rays by heat generation of the heat-generating coil and emits the far-infrared rays through the opening, the heating device using the antibacterial nano- Sauna device having this "is published.

However, in the "heating device using the natural stone panel of the antibacterial nano-device and the sauna device having the antibacterial nano-device" and the electric coil heater in general, heat is concentrated only to the portion where the electric coil passes, and the resistance value of the electric coil is increased There is a risk of fire when a high temperature is generated, and there is a problem in that the operation can not be performed when the electric coil is disconnected.

In the conventional electric coils and heaters using oil and gas, heating by convection takes a long time for the user to heat up to a necessary temperature. The heater using oil and gas has a risk of fire and explosion.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a porous ceramic board which is formed into a plate structure by high- A carbon heating plate that is heated by power supply; A reflector configured to reflect the radiant heat forward; A porous ceramic board, a porous ceramic board, a carbon heating plate, and a reflector, which are open to the front side and include a body for supplying electric power to the carbon heating plate, so that far infrared rays are emitted by a heated porous ceramic board, Allows the effect of deodorization and humidity control by the board.

And the aggregate of the porous ceramic board is 2 to 3 mm particles; Wherein the aggregate comprises 60 to 80 parts by weight of perlite and 20 to 40 parts by weight of the functional aggregate, wherein the functional aggregate comprises at least one of kaolin, zeolite, ilite, elvan, and sodium silicate; The porous ceramic board is compressed and formed at a temperature of 500 to 850 DEG C so that the porous ceramic board has a plurality of minute pores and the heated porous ceramic board allows the far infrared rays and negative ions to radiate.

The carbon heating plate is composed of a carbon fiber sheet which generates heat by electric power, a linear copper plate which transmits electric power, a glass fiber board which contains carbon islands and a linear copper plate inside; The carbon fiber papers are arranged side by side in at least two planes on the same plane; The linear copper plate is connected to each end of the carbon islands retaining, one of the linear copper plates being connected to two carbon fiber sheets; The connection between the carbon islands and the linear copper plate is bonded by an adhesive or tape, and the bonded area is punched to form a plurality of through holes, whereby the bonding and connection of the carbon islands and the linear copper plate are strengthened by punching and through- , So that the temperature and location of the heat generated by the carbon heating plate are uniform.

In addition, they are composed of porous ceramic board, carbon heating plate and reflector in the order from the front, or in the order of carbon heating plate, porous ceramic board and reflector; The carbon heating plate is composed of a flat plate or a concave plate oriented in the open direction so that the main part of the radiant heat radiated forward can be used as a porous ceramic board or a carbon heating plate and the radiant heat radiated can be focused on a certain area .

As described above, the porous ceramic board carbon heater constitutes a porous porous ceramic board which is formed into a plate structure by compressing 2 to 3 mm particles of perlite, kaolin, zeolite, ilite, elvanite and sodium silicate at 500 to 850 ° C, This porous ceramic board is heated by a carbon heating element to emit far infrared rays, anion and quantum energy, and has numerous deodorizing and humidity control effects through porous ceramic boards.

The carbon fiber sheet of the carbon heating plate is arranged in parallel on at least two planes on the same plane, and the linear copper plate is connected to each end of the carbon islands. In one of the linear copper plates, two carbon fibers are connected, The carbon fiber sheet is heated and bonded at a temperature and a site where the carbon fiber sheet is heated and bonded. The carbon islands and the linear copper plate are bonded by an adhesive or a tape, and the bonded area is punched to form a plurality of through holes, There is an effect that the adhesion between the island holding and the linear copper plate and the connection are firm.

In addition, the main part of the radiant heat emitted from the front is composed of a porous ceramic board, a carbon heating plate and a reflector in this order, or a carbon heating plate, a porous ceramic board and a reflector in this order, Is constituted by a flat plate or a plate concave toward the open direction, so that the radiant heat radiated can be concentrated on a certain region.

1 is a perspective view of a porous ceramic board carbon heater according to a basic example of the present invention.
2 is a perspective view of a porous ceramic board, a carbon heating plate, and a reflector according to a basic example of the present invention.
3 is a rear view of a carbon heating plate according to an example of the present invention.
4 is a sectional view of a porous ceramic board carbon heater according to a basic example of the present invention.
5 is a sectional view of a porous ceramic board carbon heater according to the first and second modification examples of the present invention.
6 is a sectional view of a porous ceramic board carbon heater according to a modification 2-1 of the present invention.
7 is a sectional view of a porous ceramic board carbon heater according to a modification 2-2 of the present invention.

TECHNICAL FIELD The present invention relates to a porous ceramic board carbon heater, and more particularly, to a porous ceramic board which is formed into a plate structure by high-temperature compression of aggregates of 2 to 3 mm particles composed of perlite, kaolin, zeolite, ilite, elvanite and sodium silicate. A carbon heating plate that is heated by power supply; A reflector configured to reflect the radiant heat forward; A porous ceramic board, a carbon heating plate, and a reflector, which are open to the front side, and a body for supplying power to the carbon heating plate; The carbon heating plate, the porous ceramic board, and the reflector plate in this order, and the carbon heating plate is composed of a flat plate or a plate concave toward the open direction, The present invention relates to a heater that radiates far infrared rays, anion, and quantum energy, and has a deodorizing and humidity control effect.

The present invention comprises a porous ceramic board, a carbon heating plate, a reflector, and a body.

2, the porous ceramic board 120 is a porous board molded into a plate structure by high-temperature compressing aggregates of a predetermined size. The size of the porous ceramic board 120 aggregate is 2 to 3 mm Preferably, the aggregate is composed of 60 to 80 parts by weight of perlite and 20 to 40 parts by weight of the functional aggregate. The functional aggregate may be kaolin, zeolite, ilite, elvanite, And at least one of sodium silicate and sodium silicate.

Here, Perlite is a natural inorganic material with no chemical reaction and toxicity, which is made by calcining and expanding the perlite (citron) collected from the volcanic region to 1,000 ~ 1,300 ℃. Due to the numerous pores made through the plastic expansion process Light weight of a specific gravity of 0.1 to 0.25, heat insulating property of 0.040 to 0.060 kcal / m.hr. ° C, water retention of an effective water content of 40 vol% or more, and the like.

In addition, kaolin and sodium silicate are used to improve the adhesion of each aggregate of the porous ceramic board 120. Zeolite and ilite have high adsorption properties and are used for deodorization. In the heating of ilite and elvan, And is used for far-infrared rays and anion dissipation.

The forming of the porous ceramic board 120 is completed in the form of a rectangular plate by applying a pressure of about 70 kg with a press machine at a temperature of 500 to 850 ° C. A more varied aggregate can be added according to the requirements of the user and the manufacturer, Not only high temperatures and larger pressures can be applied, but also various shapes can be produced.

The next carbon heating plate 130 includes a carbon island holding 131 that generates heat by electric power as shown in FIGS. 2 and 3, a linear copper plate 132 that transmits electric power, a carbon islands 131 and a linear copper plate And a fiber glass plate 133 including the inside of the fiberglass plate 132 as the inside.

The carbon islands 131 are coated with rough surfaces on which current flows with the exposed carbon fibers to form a smooth back surface. The carbon islands 131 are arranged side by side in at least two, preferably three, Each of the linear copper plates 132 is connected to two carbon islands 131. In this case,

'모양, 등으로 연결된다.That is, when the carbon islands 131 are elongated, as shown in FIG. 3, the shape of the carbon island 131 and the linear copper plate 132 connected to each other is'('ㄷ') shape, four long if the '

'Shape, and so on.

At this time, in the connection of the carbon islands 131 and the linear copper plate 132, the adhesive is applied to the rough surface of the carbon islands 131, or the double-sided tape 134 is attached and the linear copper plate 132 is bonded and connected.

Further, in order to improve the connection of the bonded portion, a plurality of small through holes 132a are formed by punching in the direction of the carbon island 131 from the linear copper plate 132. [

A terminal portion 133a connected to the linear copper plate 132 to which only one carbon island 131 is connected is formed on the back surface of the glass fiber plate 133. [

In addition, the structure that surrounds the carbon islands 131 and the linear copper plate 132 can be used as a material having a high heat resistance, high fire resistance, and easy bending, besides the glass fiber plate 133.

Next, the reflection plate 140 is a plate that reflects radiant heat. The body 110 is open to the front and includes a porous ceramic board 120, a carbon heating plate 130, and a reflection plate 140 , And supplies power to the carbon heating plate (130).

The body 110 includes a temperature control means for the carbon heating plate 130, a protection net opened in front, a fire prevention means, and the like.

The porous ceramic board 120 and the carbon heating plate 130 and the reflector 140 may have different positions and shapes from each other. As shown in FIG. 4, each configuration is a flat plate, and the porous ceramic board 120, the carbon heating plate 130, and the reflection plate 140 are arranged in this order from the front.

As shown in FIG. 5, the first to second modifications are formed in the order of the carbon heating plate 130, the porous ceramic board 120, and the reflection plate 140 from the open front, As shown in FIG. 6, the 2-1 deformation is formed by a plate concave toward the direction in which the carbon heating plate 130 is opened, and is configured in the order of the porous ceramic board 120, the carbon heating plate 130, 7, a carbon heating plate 130, a porous ceramic board 120, a reflection plate 140, and a reflection plate 140 are formed on the surface of the carbon heating plate 130, Respectively.

As described above, the porous ceramic board carbon heater 100 is a porous ceramic board (porous ceramic board) formed by compressing perlite, kaolin, zeolite, ilite, elvanite and silicate of 2 to 3 mm particles at a temperature of 500 to 850 ° C. The porous ceramic board 120 is heated by the carbon heating body 130 to radiate far infrared rays, anion and quantum energy, and is also capable of absorbing and deodorizing the porous ceramic board 120 by means of a large number of fine voids of the porous ceramic board 120 There is an effect of humidity control.

The carbon islands 131 of the carbon heating plate 130 are arranged in a line on the same plane and the linear copper plates 132 are connected to the respective ends of the carbon islands 131, ) Has a uniform effect on the temperature and location at which the carbon heating plate (131) of the carbon heating plate (130) is heated to generate heat than the carbon heating plate having the size of the carbon heating plate (130) have.

The connection between the carbon islands 131 and the linear copper plate 132 is bonded by an adhesive or a tape 134 and the bonded portion is punched in the direction of the carbon islands 131 from the linear copper plate 132, The linear copper plate 132 in the through hole 132a is protruded or exposed to the carbon island holding 131 by punching to form a gap between the carbon island holding 131 and the linear copper plate 132 And the connection is robust.

The porous ceramic board 120 is formed in the order of the carbon ceramic plate 120, the carbon heating plate 130 and the reflector plate 140 in this order from the front side. The carbon heating plate 130, the porous ceramic board 120, The carbon heat generating plate 130 may be formed of a flat plate or a concave plate oriented in the open direction so that the radiant heat radiated from the plate may be formed in a certain region It is possible to concentrate on.

100: Porous ceramic board Carbon heater 110: Body 120: Porous ceramic board
130: carbon heating plate 131: carbon island holding 132: linear copper plate
132a: through hole 133: glass fiber board 133a: terminal portion
134: tape 140: reflector

Claims (4)

delete 60 to 80 parts by weight of a perlite having a particle size of 2 to 3 mm, and 20 to 40 parts by weight of a functional aggregate having a particle size of 2 to 3 mm, wherein the functional aggregate is at least one of kaolin, zeolite, A porous porous ceramic board having a plate structure formed by compressing the functional aggregates at a high temperature of 500 to 850 캜;
A carbon heating plate that is heated by power supply;
A reflector configured to reflect the radiant heat forward;
And a porous ceramic board, a carbon heating plate, and a reflector, which are open to the front side, and which supply electric power to the carbon heating plate.
3. The method of claim 2,
The carbon heating plate is composed of a carbon fiber sheet which is heated by electric power, a linear copper plate which transmits electric power, a glass fiber board which contains carbon islands and a linear copper plate inside;
The carbon fiber papers are arranged side by side in at least two planes on the same plane;
The linear copper plate is connected to each end of the carbon islands retaining, one of the linear copper plates being connected to two carbon fiber sheets;
Wherein the carbon islands and the linear copper plates are bonded by an adhesive or a tape, and the bonded regions are punched to form a plurality of through holes. delete

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