KR20120100237A - Heater system for electric heater - Google Patents

Abstract

PURPOSE: A heater device for an electric heater is provided to eliminate heat loss between a heating object and a filling hole, thereby farther emitting heat to a remote place. CONSTITUTION: A heating object is made of nano particles so that the gap between the heating object and the inner circumference of a storage hole is fully filled by the heating object. The heating object emits heat in response to power to both ends of the heating object. An insulation member(150) insulates both ends of the heating object from a heat emitting plate(110). One end of a connection unit(170) is embedded in the heating object. The other end of the connection unit protrudes to connect with a power line.

Description

Heater system for electric heater {heater system for electric heater}

The present invention relates to a heater device for an electric heater, and more particularly, a filling hole is formed to accommodate a heating element provided on a rear surface thereof, and a heat sink formed gradually thinner toward an upper end thereof, and a filling hole formed in the heat sink. By constructing the heater device so that the heating element is provided on the inner circumferential surface without any gap, heat loss between the heating element and the filling hole can be eliminated, thereby increasing the thermal efficiency compared to the power consumption, and heat radiation to a long distance due to the shape and structure of the heat sink. The present invention relates to a heating apparatus having a heat sink made possible.

 In general, a heating apparatus used for indoor heating can be roughly classified into an oil heater using petroleum, a gas heater using gas, and an electric heater using electricity.

The petroleum heater is complicated to manufacture due to its complicated configuration, and because the exhaust air contains a lot of harmful substances in human body due to incomplete combustion, it contaminates the surrounding air, and there is a high risk of fire in the handling process, and it is necessary to supplement fuel periodically. Therefore, there is a problem that maintenance is cumbersome.

In comparison, electric heaters are simple to use because they are simple to use. They can be manufactured easily, and their handling is extremely simple, and the risk of fire is relatively lower than that of petroleum heaters. Increasingly, the use of indoor heating means is increasing.

The conventional general electric heater is a heater rod formed of a transparent heat-resistant quartz tube or an opaque heat-resistant ceramic tube containing a nichrome coil-like electric heating element is inserted into a storage hole formed on the back of the heat sink formed in a plate shape, the heater The heating rod is heated by applying power to the rod side, and the generated heat is released into the room through the heat sink.

However, the conventional general electric heater has a structure in which a heater rod formed of a transparent heat-resistant quartz tube or an opaque heat-resistant ceramic tube containing a nichrome coil-type electric heating element is inserted into a storage hole formed on the rear surface of the heat sink as described above. Therefore, the gap between the inner circumferential surface of the storage hole and the outer circumferential surface of the heater rod is generated by inserting the heater rod into the storage hole of the heat dissipation plate, and there is a problem in that thermal efficiency is inevitably lowered due to the gap.

In addition, since the heat sink of the conventional electric heater is formed in a simple rectangular plate shape to widen the heat dissipation area, there is a problem that heat radiated through the heat sink is not radiated to a long distance.

Accordingly, the present invention has been made in order to solve the above-described problems, the filling hole is formed to accommodate the heating element provided on the back, the heat sink formed gradually thinner toward the top, and the filling hole formed in the heat sink It is an object of the present invention to provide a heater device for an electric heater, which can eliminate heat loss between the heating element and the filling hole by increasing the heat efficiency between the heating element and the filling hole so that the heating element is provided without a gap. .

In addition, another object of the present invention devised to solve the above-described problems, the filling hole is formed to accommodate the heating element provided on the back, the heat sink is formed gradually thinner toward the top, and the heat sink The heater device is configured to be provided on the inner circumferential surface of the formed filling hole without a gap, thereby providing an electric heater heater device capable of heat radiation to a long distance by the shape and structure of the heat sink.

The present invention for achieving the above object is a heater device for electric heaters, the storage hole is formed through both ends of the bottom and the middle portion of the rear surface, the thickness is configured to be thinner from the lower end to the upper end to dissipate heat to a long distance The surface of the heat dissipation layer is coated with a heat generating layer to increase the radiant heat, and the plate-shaped heat dissipation plate is provided with a wavy cross-section, and the nano-particles to be filled without gap in the storage hole inner circumferential surface of the heat dissipation to apply power to both ends A heating element provided to be capable of dissipating heat, an insulating member provided to block both ends of the heating element filled in the storage hole, and insulated from the heat sink, and one end of which is embedded in the heating element through a central portion of the insulating member, respectively. And the other end includes a connection portion protruding for connection with a power line. .

In addition, the heat generating layer is 50 to 70% by weight of villus (or illite) having particles of 1,000 or more and 10,000 or less, 20 to 40% by weight of kaolin, 3 to 8% by weight of pearlite, and 5 to 25% by weight of adhesive. It characterized by consisting of a mixture of the mixture.

In addition, the heat dissipation plate has a thinner upper end than the lower end so as to be radiated to a far distance transmitted from the heating element, and is formed in a wavy cross section, and a pair of storage holes have a ceramic insulator for insulating the heating element. On the upper part of the storage hole formed at the center of the back surface, a pair of heat storage protrusions spaced apart from each other are formed to protrude in the longitudinal direction to prevent the heat sink from being bent due to high heat. And a pair of heat storage grooves are formed in a lengthwise direction to prevent heat from being collected at the upper and lower ends of the heat sink and to generate heat in a complex manner so that heat can be radiated to a long distance. When the inner circumference receives high heat from the heating element heated by high heat, It characterized in that the janghol damage having a pair of grooves to prevent (tears) is formed in the longitudinal direction.

According to the heater apparatus for an electric heater according to the present invention as described above, the filling hole is formed to accommodate the heating element provided on the back, the heat sink formed gradually thinner toward the top, and the filling hole formed in the heat sink By configuring the heater device so that the heating element is provided on the inner circumferential surface without any gap, heat loss between the heating element and the filling hole can be eliminated, thereby increasing the thermal efficiency compared to the power consumption.

In addition, according to the heater apparatus for an electric heater according to the present invention, the filling hole is formed to accommodate the heating element provided on the rear surface, the heat sink formed gradually thinner toward the top, and the inner peripheral surface of the filling hole formed in the heat sink By configuring the heater device so that the heating element is provided without a gap, heat can be radiated to a long distance by the shape and structure of the heat sink, so that heating can be performed within a short time.

1 is a perspective view showing a heater apparatus for an electric heater according to an embodiment of the present invention.
2 is a sectional view taken along line A-A 'in Fig.
3 is a view showing a heat radiation state of the heater apparatus for an electric heater according to an embodiment of the present invention.
4 is a perspective view showing a heat sink and a heat radiation state of the heater apparatus for an electric heater according to another embodiment of the present invention.

Hereinafter, an embodiment of the heater apparatus for an electric heater according to the present invention will be described in detail.

First, it should be noted that, in the drawings, the same components or parts have the same reference numerals as much as possible. In describing the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as not to obscure the gist of the invention.

As shown, the heater apparatus 100 for an electric heater according to the present invention is installed in a safety net on the front side and the inner surface is installed in a case (not shown) equipped with a heat insulating member to dissipate heat corresponding to the power applied. By providing the heating element to the storage hole formed on the rear surface of the heat sink in a filling manner and changing the shape and structure of the heat sink, it is possible to eliminate the gap between the heat generating element and the heat sink to improve the thermal efficiency compared to the power consumption, Due to its structure, it is provided to radiate heat to a long distance.

That is, the heater device 100 for an electric heater according to an embodiment of the present invention described above is formed with a storage hole (not shown) through which both ends penetrate the upper and middle portions of the rear surface, and the upper end to dissipate heat to a long distance. The thinner the thickness from the bottom to the bottom, the surface of the heat dissipation layer 110 is coated with a heat generating layer 111 to increase the radiant heat is provided with a wavy cross-section, and the inner peripheral surface of the storage hole of the heat dissipation plate 110 and It is composed of nanoparticles to be filled without gaps in the heat generating element 130 is provided to be capable of dissipating heat corresponding to applying power to both ends, and the heat sink by blocking both ends of the heat generating element 130 filled in the storage hole ( An insulating member 150 provided to insulate the 110 and the central portion of the insulating member 150 penetrate the central portion of the insulating member 150, and one end is embedded in the heating element 110, and the other end protrudes for connection to the power line. It comprises a connecting portion 170.

Here, the heat generating layer 111 is 50 to 70% by weight of chorus (or illite) having nanoparticles of 1,000 mesh to 10,000 mesh, 20 to 40% by weight of kaolin, 3 to 8% by weight of pearlite and adhesive It consists of a mixture of 5 to 25% by weight.

Hereinafter, with reference to the accompanying drawings, a heater device for an electric heater according to an embodiment of the present invention described in more detail as follows.

First, the heat sink 110 of the heater device for an electric heater according to an embodiment of the present invention, the other end than one end, that is, the top of the heat sink is installed so that it can be radiated to a far distance transmitted from the heating element 130, Its thickness is gradually thinner and is formed in a wavy cross section, and a pair of storage holes penetrated to fill the heating element 130 are respectively formed in the upper central portion of the rear surface, wherein the inner circumferential surface of the pair of storage holes is a heating element. The ceramic insulator 112 is coated to be insulated from the 130.

In addition, a pair of heat storage protrusions 113 spaced apart from each other are formed to protrude in the longitudinal direction at a lower portion of the storage hole formed at the center of the rear surface of the heat sink 110 so as to prevent the heat sink from being bent due to high heat.

In addition, by storing a part of the heat transferred from the heating element 130 in the upper and lower front of the heat sink 110 to prevent the heat collecting to the upper and lower ends of the heat sink 110, the radiation wavelength of the heat is generated in combination A pair of heat storage grooves 114 are formed in the longitudinal direction so that heat can be radiated to a long distance.

In addition, a pair of grooves (not shown) are provided on the inner circumferential surface of each of the heat sinks 110 so as to prevent breakage (torn) of each storage hole due to high heat when high heat is transmitted from a heating element heated to a high temperature. It is further formed in the longitudinal direction.

When the heat generating layer 111 coated on the surface of the heat sink 110 is composed of nanoparticles of 1,000 mesh or less, the heat generating area is reduced, and when the heat generating layer 111 is composed of 10,000 mesh or more, the cost of manufacturing increases. As described above, it is preferable to configure the nanoparticles of 1,000 mesh ~ 10,000 mesh.

The heating element 130 is formed of nanoparticles to fill the storage hole formed on the rear surface of the heat dissipation plate 110 without gaps so as to generate heat corresponding to applying power to both ends.

That is, the heating element 130 is filled in the storage hole of the heat sink 110 is formed in the center and the upper end of the storage hole coated with the ceramic insulator 112, which is an insulating material on the inner peripheral surface of the storage hole Conductive polymer heating element 131 and the conductive polymer heating element 131 which is composed of nanoparticles of 600 mesh to 15,000 mesh so as to be able to generate heat in correspondence to the application of power so as to increase the thermal efficiency because the inner peripheral surface and the gap do not occur. And an insulator 132, which is composed of nanoparticles of 600 mesh to 15,000 mesh to store heat generated from the conductive polymer heating element 131 so as to correspond to power supply. The mixture of the 131 and the insulator 132 is mixed in a ratio of 8: 2 to 9: 1 so that the resistance value (temperature) can be adjusted with respect to the size (heating area) and thickness of the heat sink 110. It is is configured.

Here, the conductive polymer heating element 131 is composed of carbon or graphite or a mixture of carbon and graphite, the mixture of carbon and graphite is composed of 1: 9 to 9: 1 in a ratio.

In addition, the insulator 132 is composed of mica or magnesium or mica and magnesium, the mixture of mica and magnesium is mixed in a ratio of 5: 5 to 7: 3.

On the other hand, if the particles of the conductive polymer heating element 131 is composed of 600 mesh or less, the heat generating area is reduced, if composed of more than 15,000 mesh, the cost of manufacturing increases, so as described above Particles of the heating element 110 is preferably composed of 600 mesh 15,000 mesh nanoparticles.

The insulator 132 is mixed with the conductive polymer heating element 131 and has mica having nanoparticles of 600 mesh or more and 15,000 mesh or less in the same manner as the particles of the conductive polymer heating element 131 to improve heat storage when heat is generated. Or magnesium or mica and a mixture of magnesium.

The insulating member 150 prevents the heating element 130 filled in the storage hole of the heat dissipation plate 110 from being discharged, and insulates both ends of the storage hole to insulate the heating element 130 and the heat dissipation plate 110. It is comprised so that the connection part 170 can be installed by blocking.

That is, the insulating member 150 is formed as a cylindrical body with an insertion protrusion (not shown) projecting in a cross-sectional shape corresponding to the groove and the storage hole spaced apart from each other on the outer circumferential surface so as to be prevented by being inserted into the storage hole. In the center part, a through hole (not shown) is formed to pass through one end of the connection part 170.

 Meanwhile, as illustrated in FIGS. 1 to 3, the heat dissipation plate 110 of the heater 100 for an electric heater is formed in a cross section in a wave shape to radiate heat to a long distance, but is not limited thereto. As shown in Fig. 4, it may be formed in a square plate having a curved cross section.

That is, the heat dissipation plate 1100 of the heater apparatus for an electric heater according to another embodiment of the present invention has a filling hole 1111 to fill the heating element 130 (see FIG. 2) on both sides of the rear center portion. It is formed in a cross-section of the curved shape, the thickness is formed thinner toward both ends from the filling hole 1111 so that the heat can be radiated to a long distance, the front of the heat sink 1110 by storing a portion of the heat transmitted from the heating element 130 The first heat storage groove 1112 and the first heat storage are symmetrical with respect to the central part so as to prevent the heat from being collected at the upper and lower ends of the heat sink, and the heat radiation is generated in a complex manner so that heat can be radiated to a long distance. A second heat storage groove 1113 and a third heat storage groove 1114 are formed at one side of the groove 1112 in the longitudinal direction, respectively.

In addition, the bottom of the outer periphery of the filling hole 1111 formed on the bottom of the heat dissipation plate 1110, the damage preventing recess 1115 in the longitudinal direction to prevent the filling hole is damaged (torn) due to the high heat transmitted from the heating element 130 Each formed as is provided.

When using a heater device for an electric heater according to an embodiment of the present invention made in this way, as shown in Figure 1 to 3, one end passes through the through hole formed in the central portion of the insulating member 150, the heat sink The power line is connected to each one end of the connection portion 170 provided with one end embedded in the storage hole of 110, and then power is applied.

The conductive polymer heating element 131 and mica manufactured by mixing carbon and graphite in a ratio of 2: 8 after making carbon and graphite into nanoparticles of 10,000 mesh in a storage hole by applying power to the connection part 170 side. And magnesium are made of 10,000 mesh nanoparticles, and these micas and magnesium are mixed at a ratio of 6: 4, and the insulator 132 is mixed at a ratio of 8: 2, and the heating elements are respectively filled without gaps in the inner circumferential surface of the storage hole. 130 will generate heat.

That is, when the power is turned to the connection part 170 side, the conductive polymer heating elements 131 of the heating element 130 are tunneled with each other to express electrical conductivity, so that heat is generated in the entire heating element 130 and the generated heat disappears. It is transmitted to the heat sink 110 side without.

The heat transferred to the heat sink 110 side is a heat sink 110 is formed in a cross-section of the wave shape as shown in (a) of Figure 3 and a pair of heat storage groove 114 formed on the front top, and the front By the pair of heat storage grooves 114 formed at the bottom and the thickness change, that is, the thickness is formed thinner from the lower end to the upper end, the radiation wavelength of the heat is generated in a complex manner, and the heat is radiated to a long distance.

That is, when the heat sink 130 is formed as shown in Figure 3 (b), the heat radiated from the heat sink is radiated without changing the wavelength can not be radiated to a long distance, and also change in thickness as shown in Figure 3 (c) If there is no change in thickness so as to form a thinner or thinner from the lower end to the upper end as shown in (d) of Figure 3, even if a heat sink without a pair of heat storage groove 114 in the upper and lower front is radiated from the heat sink The heat does not have a change in wavelength can not be radiated to a long distance like the heat sink of the present invention.

In addition, the heat sink 110 is a heat generating layer 111 composed of a mixture of 50% by weight of chorus mica having 5,000 mesh nanoparticles on the surface, 30% by weight of kaolin, 5% by weight of pearlite, and 15% by weight of the adhesive. Since the coating is configured to increase the radiant heat it is possible to heat the room in a short time.

The heater device configured as described above is provided without a gap between the heating element and the storage hole of the heat sink to increase the thermal efficiency compared to the power consumption, and is formed in a wavy cross-section and formed in a pair of heat formed at the top and bottom of the front surface. Radiating heat can be radiated to a long distance by the heat sink formed with the storage groove 114.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be clear to those who have knowledge of.

100; Heater device for electric heater
110; Heat sink
130; Heating element
150; Insulation
170; Connection

Claims (7)

In the heater apparatus for an electric heater,
A storage hole is formed at both the upper and middle sides of the rear surface, and has a thinner thickness from the lower end to the upper end so as to dissipate heat to a long distance, and the surface is coated with a heating layer to increase radiant heat. Plate-shaped heat sink provided with;
A heating element composed of nanoparticles so as to fill the inner circumferential surface of the heat dissipation plate without gaps and configured to dissipate heat corresponding to applying power to both ends;
An insulating member provided to block both ends of the heating element filled in the storage hole to insulate the heat sink;
A connection part penetrating through a central portion of the insulating member, one end of which is embedded in a heating element, and the other end protruding for connection to a power line;
Heater device for an electric heater, characterized in that made.
The method of claim 1,
The heating layer is 50 to 70% by weight of chorus (or illite) having nanoparticles of 1,000 mesh to 10,000 mesh, 20 to 40% by weight of kaolin, 3 to 8% by weight of pearlite, and 5 to 25% by weight of adhesive. Heater device for an electric heater, characterized in that composed of a mixture.
The method of claim 1,
The heat sink has a thinner upper end than the lower end of the heat sink so as to be able to radiate to a distance transmitted from the heating element, and is formed in a wavy cross section, and a pair of storage holes inner circumferential surface is coated with a ceramic insulator for insulation with the heating element, In the lower portion of the storage hole formed in the rear center portion, a pair of heat storage protrusions spaced apart from each other are formed to protrude in the longitudinal direction so as to prevent the heat sink from being bent due to high heat. A pair of heat storage grooves are formed in the longitudinal direction to prevent heat from being collected at the top and bottom ends of the heat sink, and the heat can be radiated to a long distance by generating a plurality of heat radiation wavelengths. When receiving high heat from the heating element heated by heat, each storage hole is Hand (tears) the electrical heater heating apparatus characterized in that a pair of grooves are provided is formed in a longitudinal direction to prevent.
The method according to claim 1 or 3,
The heating element is a storage hole coated with a ceramic insulator, which is an insulating material on the inner circumferential surface is filled in the storage hole of the heat sink is formed at the center and the top of the back, respectively, so that the gap does not occur with the inner circumferential surface of the storage hole can increase the thermal efficiency Conductive polymer heating element is composed of nanoparticles of 600 mesh ~ 15,000 mesh so as to generate heat in response to applying the power, and mixed with the conductive polymer heating element to store the heat generated from the conductive polymer heating element in response to the application of power It consists of an insulator composed of 600 mesh ~ 15,000 mesh nanoparticles to be provided, the mixture of the conductive polymer heating element and the insulator can adjust the resistance value (temperature) with respect to the size (heating area) and thickness of the heat sink. Electric heater, characterized in that the mixture is composed of a ratio of 8: 2 ~ 9: 1 Heaters.
The method of claim 4, wherein
The conductive polymer heating element is composed of carbon or graphite or a mixture of carbon and graphite, the mixture of carbon and graphite is composed of 1: 9 to 9: 1 mixed ratio, the insulator is mica or magnesium or mica and magnesium This mixture is configured, wherein the mica and magnesium mixing is a heater device for an electric heater, characterized in that the mixture is configured in a ratio of 5: 5 to 7: 3.
The method of claim 1,
The heat sink is formed with a curved cross-section having filling holes formed on both sides of the rear center portion to fill the heating elements, and the thickness is thinner from the filling hole toward both ends so that heat can be radiated to a long distance. Part of the heat transfer from the heating element is stored in the upper and lower ends of the heat sink to prevent it from being collected, and the radiation wavelength of the heat is generated in a complex manner so that the heat can be radiated to a long distance from the center of the first symmetrical heat storage. And a second heat storage groove and a third heat storage groove formed on one side of the first heat storage groove in a longitudinal direction, respectively.
The method of claim 6,
Heater device for electric heater, characterized in that the damage prevention grooves are formed in the longitudinal direction on the bottom of the outer circumferential surface of the filling hole formed on the bottom surface of the heat sink to prevent the filling hole from being broken (torn) due to the high heat transmitted from the heating element. .

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