KR900010138Y1 - Heating plate - Google Patents

Abstract

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Description

Heating board

1 is a perspective view showing a first embodiment of a heat generating substrate according to the present invention.

2 to 3 are each a perspective view of a heating substrate according to another embodiment of the present invention.

4-5 are some rear views, each showing another embodiment.

6 is a partial side cross-sectional view showing another embodiment.

7 is a side view showing main parts of an embodiment in which the present invention is applied to a sheet-like article.

8 is a front view of main parts showing another embodiment.

* Explanation of symbols for main parts of the drawings

2: Heating tile (heating board) 4: Tile (insulating board)

6, 12, 24: electrode wire 10, 14, 26: resistance heating element

22: insulating board

The present invention relates to a heating substrate which is used for indoor heating, warming, melting snow and ice in the outdoors, and for providing fruit trees, heating of vegetables, germination promotion, and the like, in particular, improvement of resistance heating elements.

Electric carpets and blankets are used for indoor heating and thermal insulation. These electric carpets and the like generally surround the entire surface with a metal resistance heating element such as nichrome wire, and control the amount of heat generated by a temperature controller or the like to adjust the temperature.

However, the metal-resistance heating element has a problem in safety, such as a high power consumption, a need for a temperature control device, a high cost, and a risk of electric shock due to wear and leakage of the insulation coating.

On top of that, the metal resistance heating element is broken easily, and once broken, it is impossible to repair and loses its value as a product.

Moreover, in the sheet-like thing, there existed a problem, such as giving a foreign material in the part of a heat generating body.

On the other hand, there is provided a product using a planar heating element instead of a metal resistance heating element, a planar heating element is applied to the front surface of the substrate such as cloth or resin sheet and dried and planar conductive paint mixed with carbon and / or metal powder with insulating resin It is made of resistance heating element.

The planar heating element solves various problems caused by the metal resistance heating element, such as a low risk of electric shock, no disconnection, and no foreign object to the user. However, in the planar heating element, there is a problem that the surface temperature is not constant because it is difficult to apply the conductive paint to the entire surface on the substrate with a uniform thickness. In addition, when abnormal heat is generated in the planar heating element, even if two heating elements are melted and cut, the surroundings are in an energized state. Moreover, there also existed a problem that a planar heating element peels easily from a board | substrate.

The present invention has been made to solve the above problems, and the gist of the heating substrate according to the present invention is a conductive paint formed by mixing at least a pair of electrode wires on an insulating substrate and mixing a conductive nonmetal powder and an insulating thermoplastic resin. The pair of electrode wires are connected to each other by a resistance heating element formed in a plurality of lines on the substrate.

In this invention, it consists of a parallel circuit which connected between a pair of electrode wires with the resistance heating body formed in the ancestor.

Therefore, the electric current supplied to the electrode wire flows by being dispersed in each of the resistance heating elements, and each resistance heating element is heated by Joule heat, and as the insulating thermoplastic resin as its constituent material expands, the density of the conductive nonmetallic granule becomes small and the resistance heating element is formed. While the resistance increases, the current value decreases. As a result, the resistance heating value is stabilized at the balance point of the resistance, the current value and the Joule calorific value to generate a constant Joule heat, so that the temperature is kept constant, and this action is formed for each resistance heating element of each West. The temperature can be set arbitrarily from the correlation between the density of the conductive nonmetal powder and the expansion coefficient of the insulating thermoplastic resin.

Therefore, when the resistance heating element of any ancestor is melted and cut off due to abnormal heat generation, the electricity supply to the resistance heating element is stopped and the function as the heating element is stopped. However, even in this case, the resistive heating element of another ancestor can function as the heating element.

EXAMPLE

Next, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a perspective view showing the heat generating tile 2. In FIG. 4, ceramic tiles are used for floors and walls such as bathrooms, toilets, and subsoils. A pair of electrode wires 6 are formed on the rear surface of the tile 4, and a power cord 8 is connected to an electrode portion 6a provided at one end of the electrode wires 6 so as to conduct electricity to the electrode wires 6. . The electrode wire 6 is a thin sheet composed of equivalent electric conductors and is attached to the tile 4 by an adhesive or the like. The pair of electrode wires 6 includes resistance heating elements 10, 10 formed by a plurality of lines. The electrical currents connected to the electrode wires 6 are connected in parallel to each other so that the resistance heating elements 10 flow in a dispersed manner. The electrode wire 6 is covered with a resin or the like and insulated from the outside after the resistance heating element 10 is formed.

The resistance heating element 10 mixes carbonaceous powder, which is a conductive nonmetallic powder, and insulating thermoplastic resin such as polypropylene and polyethylene in a constant ratio and uniformly kneads the conductive paint on the back surface of the tile 4 by screen printing or spraying. It is applied to and dried on a high resistivity conductor. Therefore, when the resistance heating element 10 is energized, Joule heat is generated to increase the temperature together with the tile 4. When the temperature of the resistance heating element 10 rises, the insulating thermoplastic resin as its constituent material thermally expands, and the density of the carbon becomes loose. As a result, the resistance of the resistance heating element 10 increases, while the current value decreases. Therefore, the resistance, current value, and Joule calorific value of the resistance heating element 10 are balanced at a certain point, and the resistance heating element 10 is stable at the balance point to generate a constant joule calorie, so that the temperature is kept constant.

Therefore, when the temperature of the resistance heating element 10 decreases due to a decrease in the external temperature, the insulating thermoplastic resin contracts to decrease the resistance and increase the current value so that the heat of Joule heat increases and returns to the original constant temperature. . In this operation, each of the resistance heating elements 10 operates independently, and each of the resistance heating elements 10 operates as if a temperature control device is provided.

Here, the constant temperature can be arbitrarily set by selecting an insulating thermoplastic resin having a carbon density and an appropriate expansion coefficient in the resistance heating element 10.

As described above, according to the present embodiment, since each of the resistance heating elements 10 acts as a heating element, if any resistance heating element 10 is abnormally generated and melted and cut, the electricity supply to the resistance heating element 10 stops and leads to a fire. There is no work. Moreover, even if the resistance heating element 10 is disconnected for any reason, since the resistance heating element 10 stops functioning and other normal resistance heating element 10 acts as a heating element, the value as the heating tile 2 is lost. It doesn't work.

In addition, according to the present embodiment, since the carbon powder is used as the conductive nonmetal powder, it is safer against leakage compared to using metal powder, and the secondary effect of generating far-infrared rays thereon has a heating and warming effect. Can provide excellent products.

Next, another embodiment of the present invention will be described.

2 shows the heat generating tile 2 as in the above embodiment, wherein the heat generating tile 2 forms a pair of electrode wires 6 on its back side and simultaneously connects the pair of electrode wires 6 to a plurality of ancestors. After the resistance heating element 10 is connected, the surface is insulated with a resin or the like (not shown) to form a pair of electrode wires 12 thereon, and the pair of electrode wires 12 are connected to a plurality of linear resistance heating elements ( 14). The electrode wire 6 and the electrode wire 12 are connected to different power cords 8 and 16, respectively, so that the energized state is switched by a switching switch (not shown).

According to this embodiment, it is possible to select the heat generation amount of the heat generating tile 2 by the switching switch.

As shown in FIG. 3, it is not necessary to attach the power cord 8 to each of the heat generating tiles 2, and the electrode wires 6 of the heat generating tiles 2 may be connected in series with the connection cords 18. In FIG. This is because the resistance heating element 10 according to the present invention, which does not contain a metal powder and is formed in a linear manner thereon, has a very low power consumption.

Therefore, if the heat generating tile 2 is formed in an appropriate size, the heat generating tile 2 can be provided in correspondence with the installation area of the heat generating tile 2 immediately, and the wiring can be further miniaturized.

In addition, it is not necessary to arrange the electrode wires 6 against each other in substantially parallel directions, and as shown in FIG. 4, the electrode wires 6 may be arranged substantially perpendicular to each other, and the electrode wires 6 may be arranged in the heat generating tile 2. It may be arranged in a curved shape to suit the external shape of the.

In addition, as shown in FIG. 5, the heat generating resistor 10 may be bent, and the ancestor is a concept including not only a straight line but also a curve.

And as shown in FIG. 6, the groove | channel 20 may be provided in the back surface of the tile 4 in which the electrode wire 6 is formed, and the electrode wire 6 may be arrange | positioned in the groove | channel 20, and a resistance heating element 10 can also be arrange | positioned in a groove.

In the embodiment of the present invention, explanation is omitted one by one, but it is preferable to insulate the exposed portion of the electrode wire 6 with a resin or the like.

Moreover, it is also possible to form an electrode wire and a resistive heating element in the back surface of a tile by baking.

The embodiment of the present invention has been described in detail by taking ceramic tiles as an example. However, the insulating substrate according to the present invention is not limited to ceramics (including ceramics), but may be formed of a plate-like material formed of resin, mortar or gypsum. Can be. For example, if the heating board according to the present invention is used as a heating board according to the present invention, the tile or slate can be used to melt the snow. Can be used for dragons.

It is also possible to use the heating substrate according to the present invention as a board for cooking or the like. The insulated substrate according to the present invention is not limited to a plate-like object, and even if a sheet-like material such as a resin film, cloth, paper, or leather, the present invention can be easily applied. For example, when a heat resistant resin film such as a polyimide film is used as a heat generating substrate, the film can be attached to a drip tank or the like already installed to prevent freezing. In addition, if the present invention is applied to an electric carpet or an electric blanket, the resistance heating element is flat, which does not give foreign users a sense of foreign substances, and the heat and heating effect is increased by the generation of far-infrared rays, which are excellent in breathability and hygienic and incidental effects. It can make a difference. In addition, since the resistance heating element according to the present invention consumes less power, the present invention may be applied to an automotive sheet to take power from a battery.

As described above, when the insulating substrate according to the present invention is a sheet-like article, the electrode wire 6 and the resistance heating element 10 can be formed on both surfaces of the sheet-shaped insulating substrate 22 as shown in FIG.

In this case, as shown in FIG. 8, the electrode wire 24 and the resistance heating element 26 are formed on the other surface so as to be orthogonal to the electrode line 6 and the low phase heating element 10 formed on one surface of the insulating substrate 22. May be formed.

The present invention may be applied by mixing a carbon powder and a conductive polymer powder as a conductive nonmetallic separator.

Although the embodiments of the present invention have been described in detail above, the present invention can be applied to various other uses, and the present invention can be carried out in a form in which various changes, modifications, and improvements have been made without departing from the spirit thereof. It is.

As is evident from the above description, the present invention is to form a resistive heating element that does not contain a metal powder on an insulating substrate in a plurality of lines, so that the resistive heating element of each line has a temperature control function.

According to the heat generating substrate of the present invention can be maintained at a set temperature without using a temperature control device, moreover, because the power consumption is small, it is possible to provide a low cost and low cost maintenance substrate.

In addition, since the resistance heating element itself melts and cuts against abnormal heat generation, the abnormal heat generation can be stopped. Furthermore, since the resistance heating element does not contain metal powder, the current flowing through the resistance heating element is weak, and there is no electric shock due to leakage or the like. This is excellent. In addition, even if a part of the resistance heating element is disconnected, the function as the heating substrate is not lost.

On the other hand, the heat generating substrate according to the present invention does not produce unevenness in the surface temperature, and even if the sheet-like material does not produce irregularities on the surface, it does not give the user a feeling of discomfort or foreign matter.

In addition, the heat generating substrate according to the present invention is excellent in breathability and excellent effect.

Claims (3)

Forming at least a pair of electrode wires on an insulating substrate and connecting the pair of electrode wires by a resistive heating element formed of a plurality of lines on the substrate with a conductive paint formed by mixing a conductive nonmetallic powder and an insulating thermoplastic resin. Heating substrate characterized in that. The heat generating substrate according to claim 1, wherein the insulating substrate is a plate-like material made of ceramics, resin, mortar, gypsum or the like or a sheet-like material made of resin, cloth, paper or leather. The heat generating substrate according to claim 1 or 2, wherein the conductive nonmetal powder is composed of a carbon or a conductive polymer, or a carbon and a conductive polymer.