KR200441518Y1 - sheet type heating element have a heat insulator - Google Patents

Abstract

The present invention is an insulating base fabric having a predetermined thickness in the planar heating element provided with a heat insulating material so as to radiate far infrared rays by applying a voltage for AC or DC, and radiate heat in one direction to the lower part of the planar heating element that generates heat in a planar state. on; A carbon heat generating unit formed to have a heat generating function by resistance heat; A silver part stacked on both ends of the carbon heating part so that the current supplied to the carbon heating part is smoothly supplied without contact resistance; Copper foil electrode which is laminated in contact with the silver portion to supply the current amount to the carbon heating portion of the remote; With coated paper to seal; A planar heating element to be laminated; Bonding a heat insulating material having an aluminum deposition layer on the bottom surface, the adhesive layer on the inner carbon heating portion except for the copper foil electrode portion at both ends so as to easily connect the wire to the copper foil electrode of the planar heating element; Formed, characterized in that the planar heating element provided with a heat insulating material is configured.

Therefore, in the case of the conventional planar heating element in which the heat insulating material is laminated on the entire surface of the planar heating element or laminated on the heat insulating material and is encapsulated with an insulating fabric together with the planar heating element, the copper foil electrode part is connected to the copper foil electrode part of the planar heating element. Although it was difficult to connect the wire directly to the copper foil electrode part where the construction time was delayed or the insulation material was laminated because all the insulation materials were removed after the lamination of the laminated insulation material, only the carbon heating part, which is the inner part of the copper foil electrode formed at both ends of the planar heating element, is adhesive layer. It is possible to obtain the effect of easily connecting the wire to the copper foil electrode by forming a, by providing an aluminum deposition layer on the bottom of the heat insulating material can improve the heat insulating performance. In addition, the ferrite powder, which is a magnetic iron oxide compound having magnetic properties as ceramics acting on the planar heating element, is added and mixed with an organic foam or an organic nonwoven fabric or felt to form an insulating material, thereby removing electromagnetic waves.

Planar heating element, heat insulator, ferrite, electromagnetic wave absorption, crosslinked polyethylene, adhesive, organic material

Description

Sheet heating element with a heat insulator {sheet type heating element have a heat insulator}

1 is a cross-sectional view showing a conventional planar heating sheet.

2 is a perspective view showing a planar heating element provided with a heat insulating material according to the present invention.

3 is a cross-sectional view showing a planar heating element provided with a heat insulating material according to the present invention.

4 is a sectional view showing a heat insulating material configured with an electromagnetic wave absorption function.

<Explanation of symbols for main parts of drawing>

100: planar heating element with heat insulating material 102: insulating base fabric

114: coated paper 115: carbon heat generating portion

118: silver part 120: copper foil electrode

125: heat insulating material 140: planar heating element

145: thermoplastic resin layer 150: adhesive layer

155: aluminum deposition layer 160: ferrite

170: organic foam (organic nonwoven fabric or felt)

The present invention relates to a planar heating element provided with a heat insulating material, and more particularly, by applying a voltage for AC or DC, the heat insulating material is supplied in one direction to the planar heating element that emits far infrared rays and generates heat in a planar state of the planar heating element. When the adhesive layer is adhered to the lower portion, but the adhesive layer is formed on the entire surface of the carbon heat generating portion except for the copper foil electrode portion, the adhesive layer is not bonded between the copper foil electrode and the heat insulating material so that the wire can be easily connected, and ferrite having magnetic properties on the planar heating element. The present invention relates to a planar heating element provided with a heat insulator capable of absorbing electromagnetic waves generated by supplying electric current by mixing with a crosslinked or non-crosslinked polyethylene foam and shortening construction time and process.

In general, planar heating elements are used in places or products requiring heat generation, such as for heating floors at low temperatures in winter, for promoting the germination of living organisms, for melting roads, and for the need for far-infrared radiation, and using a crosslinked polyethylene foam on one side of the planar heating elements. The heat insulating material which laminated | stacked the comprised heat insulating material or laminated | stacked the heat generating body on the heat insulating material, and inserted into the insulating fabric is used.

Conventional planar heating elements in which such heat insulating materials are laminated are disclosed in Korean Patent Application No. 10-2003-0023448 filed on April 14, 2003, and Utility Model Application No. 20-2004, filed May 8, 2004. In the panel of the planar heating element comprising a planar heating element comprising a heat insulating material to block the cold air generated from the concrete and to keep heat generated heat, and a planar heating element located above the heat insulating material and radiates heat, A perforated part having a predetermined shape is formed in the heating element and has a structure in which the finishing material on the top of the planar heating element and the heat insulating material are bonded with an adhesive.

In addition, as a conventional planar heating sheet as shown in Fig. 1, Utility Model Application No. 20-2006-0003283 filed on February 6, 2006, the heat is released in the direction attached to one of the upper and lower surfaces of the planar heating element It includes a heat insulating / moisture-proof sheet for blocking the flow of moisture in the attached direction and the upper cover sheet attached to the upper surface of the planar heating element and a lower cover sheet attached to the lower surface of the heat insulating / moisture proof sheet, Both ends of the top cover sheet and both ends of the bottom cover sheet is configured to be attached on the side of the planar heating element and the heat insulation / moisture-proof sheet to close the side of the heat insulation / moisture-proof sheet.

As described above, the front surface of the heat insulating material is attached to one surface of the planar heating element or the heat insulating material laminated with the planar heating element is inserted into the upper cover sheet and the lower cover sheet, and the heat insulating material attached to the lower part of the planar heating element and the lower cover sheet and the planar heating element copper foil. It takes a long time to remove the top cover sheet laminated on the electrode surface, there was a problem that it is difficult to remove clean. In addition, when the upper cover sheet and the lower cover sheet is inserted and laminated on the structure with the planar heating element and the heat insulating material, the manufacturing process becomes complicated and the manufacturing cost increases. In addition, the planar heating element is a heating product that generates heat by energization of electricity, and thus, electromagnetic waves are generated at the moment when electric current is applied, and an electric field (or electric field) is generated from everything that uses electricity such as transmission and distribution lines and electrical appliances. It is generated in a straight line vertically from the source and easily removed or weakened by trees, buildings, and human skin.

However, the magnetic field (or magnetic field) has a characteristic of being formed in a circle around the source and is not easily removed or weakened by any object or material. In the case of the conventional planar heating element, the stress of the human body is caused by the magnetic field generated when electricity is supplied. Increasing the body temperature when the human body is exposed to electromagnetic waves for a long time there was a problem that changes in body temperature and biological rhythm is broken into development.

Therefore, the present invention is to solve the problems as described above, while bonding the heat insulating material formed with an aluminum deposition layer on the lower portion of the planar heating element that emits far-infrared rays and heats in the surface state, but only the carbon heating portion to adhere to the heat insulating material, It is possible to shorten the construction time and construction process by easily connecting the wire to the copper foil electrode portion that is not. In addition, to improve the insulation performance by forming a heat insulating material formed with an aluminum deposition layer, and to provide a planar heating element with a heat insulating material to effectively remove the adverse effects on the human body by adding a ferrite powder to the heat insulating material to absorb the electromagnetic waves generated when the current is energized. The purpose is.

The planar heating element 100 is provided with a heat insulating material according to the present invention for achieving the above object, the insulating base fabric 102 having a predetermined thickness; And a silver portion 118 stacked on both ends of the carbon heating portion 115 so that the current supplied to the carbon heating portion 115 is smoothly supplied without contact resistance; On the lower portion of the planar heating element 140 to be laminated with a coated paper 114; to seal the copper foil electrode 120 which is stacked in contact with the silver portion 118 to supply the current amount to the carbon heating unit 115 of the remote Aluminum deposition layer 155; A heat insulating material 125 formed thereon, but the adhesive layer 150 is bonded to only the carbon heating part 115 of the planar heating element with the heat insulating material; Characterized in that the planar heating element 100 is provided with a heat insulating material is configured.

The planar heating element 100 provided with the heat insulator is described in detail below through the specific embodiments shown in the accompanying drawings.

1 is a cross-sectional view showing a conventional planar heating sheet, Figure 2 is a perspective view showing a planar heating element provided with a heat insulating material according to the present invention, Figure 3 is a cross-sectional view showing a planar heating element provided with a heat insulating material according to the present invention, 4 is a cross-sectional view showing a heat insulating material configured with an electromagnetic wave absorption function.

First, as shown in FIGS. 2 and 3, a carbon paste having a heat generating function is applied to an insulating base fabric 102 having a predetermined thickness to form a carbon heat generating part 115, and the carbon heat generating part ( The silver portion 118 is formed by laminating the silver paste on both ends of the carbon heat generating portion 115 so that the current supplied to the 115 is smoothly supplied without contact resistance. The copper foil electrode 120 having a predetermined thickness to be supplied is laminated on the silver part 118 and then coated with the coated paper 114 for insulation to form a conventional planar heating element 140. The carbon heating unit 115 and the silver unit 118 as described above may be interchanged with 1 ° carbon printing and 2 ° silver printing, and the copper foil electrode 120 may be made of copper foil or aluminum foil or copper or aluminum. Use a non-metallic plate plated with tin.

The insulating base fabric 102 and the coated paper 114 may be a PET fabric, a polyethylene fabric, a polyurethane fabric, a polyimide fabric, a polypropylene fabric, a polyethylene naphthalate fabric, an acrylic fabric having a thickness of 20 to 200 μm, respectively. Preferably, 50 to 100 ㎛ PET fabric is used.

Then, after mixing the electromagnetic wave absorption powder of the ferrite 160 component having an electromagnetic wave absorbing function to the melted polyethylene resin under high pressure, by pressing and melting the freon foaming agent to form a fluidized cell and extruding it at atmospheric pressure to expand rapidly There is provided a heat insulating material 125 in which the polyethylene foam produced by the method is laminated on a PET fabric on which aluminum is deposited. The polyethylene foam insulation has a heat reflection effect by forming the aluminum deposition layer 155 on one surface, and is harder than the non-crosslinked polyethylene foam by adding a crosslinking agent to the polyethylene foam, and is configured to provide excellent heat insulation performance.

As described above, the ferrite 160 mixed in the crosslinked polyethylene foam is used as an electromagnetic wave absorber to absorb electromagnetic waves using high magnetic losses. The ferrite 160 is generally magnetic or ceramics that act on the magnetic material. Collectively known as iron oxide compounds. Since the heat insulator 125 mixed with the ferrite 160 is adhered to the lower portion of the planar heating element 140, it has a function of absorbing electromagnetic waves generated from the planar heating element 140.

In addition, the heat insulating material 125 is formed by mixing one or more types of polystyrene foam, polyethylene foam, polypropylene foam, polyurethane foam, and rubber foam, which are organic foams 170, and having a heat reflection function on one surface. The deposition layer is formed of a heat insulating material. In addition, ferrite 160 powder may be added to the heat insulating material 125 to absorb electromagnetic waves. The ferrite powder is added in an amount of 1 to 50% of the total weight of the heat insulating material, and preferably 15 to 30% to provide the electromagnetic wave absorption and heat insulating functions.

In general, magnetic fields (or magnetic fields) of electromagnetic waves have a characteristic of being formed in a circular shape around a source and are not easily removed or weakened by any object or material. In the case of a conventional planar heating element, a human body is generated by a magnetic field generated when electricity is supplied. Increasing the stress of the human body, if the body is exposed to electromagnetic waves for a long time there is a problem that the body temperature changes and the biological rhythm is broken into a disease developed, the lower surface of the heating element 140 to absorb the electromagnetic waves generated from the surface heating element to remove the stress of the human body To form a heat insulating material 125 having a heat insulating function and an electromagnetic wave absorption function at the same time.

On the other hand, the adhesive layer 150 formed to adhere the heat insulating material 125 to the lower portion of the planar heating element 140 is a die for extrusion of the thermoplastic resin 145 mixed with one or more kinds of PE or EVA (not shown) ) Extruded into a planar heating element 140 and the heat insulating material 125 or by using a dry laminating machine (not shown) between the planar heating element 140 and the heat insulating material 125, polyethylene resin, polyurethane, acrylic resin, PVC It is configured to apply the adhesive mixed with one or more kinds of resin to the insulating material 125 and the planar heating element 140 to be laminated.

And, as shown in Figure 3, the adhesive layer 150 is formed so that the heat insulating material 125 and the planar heating element 140 is bonded, the conductor is easily connected to the copper foil electrode 120 formed on both ends of the planar heating element 140 during construction It is formed by applying an adhesive to the entire surface of the carbon heat generating portion 115 except for the copper foil electrode 120 overlapping with the silver portion 118. Copper foil electrode 120, the site where the formation of the adhesive is excluded can be easily connected to the wire by using a punching terminal and solder not shown in the present invention can increase the construction capacity of the installer.

As described above, the non-bonded portion of the copper foil electrode 120 formed at both ends is non-bonded with respect to the copper foil electrode 120 of the planar heating element 140, and the inner portion has a non-bonded portion up to 3-15 cm, but preferably Is configured to form a 7 cm wide non-bonded portion.

Although preferred embodiments have been illustrated and described above, they are not limited to the above embodiments, and various modifications and changes can be made by those skilled in the art without departing from the spirit of the technical field to which the present invention pertains. You will be able to belong.

As described above, the present invention improves the construction ability and heat insulation performance when attaching the heat insulating material having the aluminum deposition layer to the bottom of the ordinary heat generating body, and generates a planar heating element by mixing ferrite powder having excellent electromagnetic wave absorption into the heat insulating material. There is an advantage of effectively eliminating electromagnetic waves. In addition, only the carbon heating portion is bonded with the heat insulator so that the wire can be easily attached to the planar heating element, so that the wire can be easily connected to the electrode of the planar heating element.

Claims (5)

Planar heating element 140; A heat insulator 125 attached to a bottom of the planar heating element to block heat emitted to the bottom; An aluminum deposition layer 155 on a bottom surface of the heat insulating material; Formed, but the adhesive layer 150 on the bottom surface of the planar heating element so that only the carbon heating unit 115 to the heat insulating material 125; Planar heating element provided with a heat insulating material, characterized in that formed The method according to claim 1; The portion where the planar heating element 140 is not adhered to the heat insulator 125 is non-bonded between the outer portion, the copper foil electrode, and the inner side of the carbon heating unit, 3 to 15 cm, based on the copper foil electrode 120 formed on the planar heating element. Planar heating element provided with a heat insulating material, characterized in that The method according to claim 1; The adhesive layer 150 forms a thermoplastic resin 145 between the planar heating element 140 and the heat insulating material 125 by mixing one or more kinds of PE or EVA, or polyethylene resin, polyurethane, acrylic resin, or PVC resin. Planar heating element provided with a heat insulating material, characterized in that formed by applying an adhesive mixed with one kind or more than one kind delete delete

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