KR200472593Y1 - Weaving Electric Resistance Element - Google Patents

Abstract

The present invention relates to an electric resistance body in which warp (weft) and weft (weft) are both constituted by electric resistance lines, the warp and weft intersect each other to form a flat body, Shaped electric resistor.

Description

{Weaving Electric Resistance Element}

The present invention is characterized in that the warp (weft) and the weft (weft) are both made of electric resistance lines, the warp and weft are crossed each other at the bottom, and the woven flat body is covered with an electrically insulating material.

Background Art [0002] Conventionally, heating devices such as electric carpet, electric blankets and electric sheets, heating means for seats such as automobiles and motorcycles, heating mat for agricultural use, rod heating or roof heating for snow- An in-plane heating element is used. Most of these have a structure in which the arrangement of the electric resistance lines is arranged in a serial manner with a constant spacing. Therefore, in order to heat the flat body with the linear heating element, the heating power is raised to a higher temperature, so that the power consumption is large, the load current is concentrated on one heating wire in a serial manner, and when the heating wire is stressed, There is a problem that the risk is high.

There is a problem in that the load current is concentrated on one resistance line and the resistance line is liable to become high temperature when stressed, so that the risk of fire and burn is high. Therefore, the object of the present invention is to make the structure of the electric resistance line flat.

The present invention aims to solve this problem by using an electric resistance body made by weaving the structure of electric resistance wire into a flat sieve in the form of a fabric.

The present invention has the effect of being able to pursue a mild thermal sensation due to the uniform temperature distribution of the planar heating element, safety due to the low temperature of the heating portion, and power consumption reduction.

1 is a state diagram of a weft-type electric resistor according to the present invention;
2 is a state diagram of a weft-type electric resistance structure according to the present invention.
3 is a layout view of an electric resistance line of a conventional planar heating element.
Fig. 4 is a state diagram of a weft-type electric resistance structure to which a weft-type electric resistance body according to the present invention is connected.

The present invention relates to an electric resistance body in which warp (weft) and weft (weft) are both constituted by electric resistance lines, the warp and weft intersect each other to form a flat body, .

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

Fig. 3 shows a structure of a conventional planar heating element 30, which is basically used as a synthetic resin and has a flexible sheet shape and has an electric resistance line 31 inside and used for heating. Conventional surface heating elements have a problem in that the load current is concentrated on one heating wire in a serial manner, and when the heating wire is stressed, the heating current tends to become high, resulting in a high risk of fire or burn.

이다. 여기서, ρ은 전기저항율이고, L은 선의 길이이고, A는 선의 단면적이다. Basically, the electric resistance line has an electric resistivity of 50 to 150 占 占 · m and a diameter of 0.2 to 0.5 mm. The electrical resistance R of the conductor is

to be. Where p is the electric resistivity, L is the length of the line, and A is the cross-sectional area of the line.

In one embodiment, when the electrical resistivity is 100 mu OMEGA .cm and the diameter is 0.3mm, a resistance wire having an electrical resistance value of about 14? / M can be formed. In order to generate a plane heat of 200 W / m 2 power density at a voltage of 220 V by the resistance wire, an electric resistance value of 242? Is required, so a resistance wire of about 17 m is required. The power density per unit length of the resistance wire is 11.7 W / m. Therefore, the arrangement of the resistance wires is a serial type structure in which resistance wires are arranged at intervals of 6 cm on a flat sieve of 1 m 2.

However, in the present invention, if the wire diameter of the resistance wire is reduced to about 0.02 mm, a resistance wire having an electric resistance value of about 3,184? / M can be formed. When a voltage of 220 V is applied to the resistance wire with a distance of 3 m between the electrodes, a power consumption of 5 W is required and a resistance wire of about 120 m is required to provide a flat heating of 200 W / m 2 power density with the resistance wire of 3 m. The power density per length is 1.6 W / m. The arrangement of the resistance wires is a parallel type structure in which resistance wires of 3 m length are arranged at intervals of 0.83 cm on a flat sieve of 1 m 2.

In order to generate plane heat at the same power density on the above-mentioned 1-m 2 flat body, the design is 1.6 W / m per unit and the line distance is 0.83 cm, but the conventional method is 11.7 W / m per unit and the line distance is 6 cm.

Therefore, the present invention is a heating structure in which a uniform temperature distribution can be obtained at a low temperature.

Referring to FIG. 1, there is shown a state diagram of a weft-type electric resistance body according to the present invention, in which both the warp yarns 11 and the weft yarns 12 are made of electrical resistance wires, And the grounded electrical resistive body 10 is formed by covering the woven flat body with an electrically insulating material.

The present invention is characterized in that a weaving-type electric resistance body having a flat body structure woven with a wire having a thin thickness of an electric resistance wire is obtained.

Referring to FIG. 2, there is shown a state diagram of a weft-type electric resistance structure 20 according to the present invention, wherein a warp type electric resistance body 10 in which warp (weft) and weft And a connection point 22 is formed on the pair of electrode lines 21 by electrically connecting one or a plurality of the above-mentioned both ends of the above-described electric resistor of the woven type in parallel.

The connection point is a connection portion for applying power to the resistor through the electrode.

In the electrical resistance structural body, the warp type electric resistance body 10 in which the warp (weft) and weft (weft) are intertwined with each other with the electric resistance line interposed therebetween is constituted. And a plurality of electrically connected structures arranged in parallel with both ends of the above-described weft-type electrical resistor are formed, and the structure is covered with an electrically insulating material.

The electrical insulation described above is an object of electrical safety and prevention of electric shock by covering the electrical resistance structure with an electrical insulating material.

In the electric resistance structural body, the warp (weft) and the weft (weft) are both constituted by electric resistance lines, the warp and weft intersect each other to form a flat body, and the interwoven flat body is covered with an electrically insulating material And a connection point 22 electrically connected to the one end or both ends of the one or more of the above-described woven electrical resistors in parallel is formed on the pair of electrode lines 21, And the electrode wire is covered with an electrically insulating material.

In the electric resistance structural body, the warp (weft) and the weft (weft) are both constituted by electric resistance lines, the warp and weft intersect each other to form a flat body, and the interwoven flat body is covered with an electrically insulating material And a connection point 22 electrically connected with one or a plurality of the above-mentioned both ends of the above-mentioned rectangular electric resistor is arranged in parallel on the pair of electrode lines 21, Wherein an electrode wire is coated with an electrically insulating material and the above-mentioned electric resistance body is fixed on a network.

An example of the method of fixing to the mesh network is characterized in that the electrical resistance structure is inserted between the mesh of the upper and lower layers and is integrated by sewing, laminating, bonding or the like.

Referring to FIG. 4, there is shown a state diagram of a weft-type electric resistance structural body 20 to which a weft-type electric resistance body according to the present invention is connected, in which warp yarns and weft yarns are both cross- A shaped electric resistor 10 is constituted and on a pair of electrode lines 21, a rectangular electric resistor connected in a staggered manner by a connecting portion 13 composed of a plurality of the above-mentioned electric resistors of a weaving type is connected to one or a plurality of the above- And connection points (22) electrically connected to each other are arranged in parallel with both ends of the weft-type electrical resistor.

In order to shorten the distance between the electrodes,

The connecting portion may be connected to a crimping terminal or the like.

The weft (weft) is characterized by being made of fiber yarn which is an electrically non-conductive material.

If the warp yarns are non-conductive yarns, if one warp yarn is cut in the warp-type electric resistance yarn, the warp yarns are detoured to the warp yarns of the yarn yarns and current is generated in the rear yarns. So that the current does not pass through the rear of the uneven slope.

Therefore, the weft-type electric resistance body according to the present invention can generate heat in a low-temperature flat body, so that the temperature distribution can be uniform, electric power consumption can be reduced, and electric safety can be sought.

10: Weaving type electric resistor
11: warp (warp)
12: Weft (weft)
13: Connection
20: Orthogonal type electric resistance structure
21: Electrode line
22: Connection point
30: Conventional surface heating element
31: Electrical resistance wire

Claims (8)

delete delete delete delete delete In the electrical resistance structural body, a warp type electric resistance body 10 in which warp (weft) and weft (weft) are intertwined with each other with an electric resistance line is formed, and on the pair of electrode lines 21, A connecting point 22 is formed in which a weaving type electrical resistor connected in a staggered manner by a connecting portion 13 composed of a plurality of electrical resistors is arranged in parallel with one or a plurality of the connected ends of the above- Wherein the electrical resistive structure is formed of a thermoplastic resin. delete delete

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