KR200347754Y1 - The electrode of plane heater - Google Patents

Abstract

The present invention relates to an electrode structure of a planar heating element.

The present invention relates to a planar heating element configured to generate more heat in a part of the planar heating element by arranging the slant of the elongate electrode of the planar heating element or changing the shape of the planar heating element.

The effect according to the present invention is to generate more heat in the desired area without special control device in the thermal mat or thermal cushion using the plane heating element can be expected to increase the thermal effect of the mat and cushion comfortably and conveniently.

Description

The electrode of plane heater

The present invention is a field related to the arrangement of the energizing electrode of the planar heating element.

The prior art of the energizing electrode of the planar heating element that is being distributed or disclosed at home and abroad is as follows. The resin film may be coated in advance with a certain type of electrode and then coated with conductive carbon black, or sewn onto a rubber sheet containing conductive carbon black to form an electrode, or the silver thread may be sewn at the end of a planar fever where the heating wire and the fiber are woven. The conducting electrodes of the conventional planar heating element constituting the conducting electrode are arranged side by side for the purpose of uniform heating throughout the planar heating element.

The object of the present invention is to provide a planar heating element having an increased thermal effect by changing the current-carrying electrode structure of the conventional planar heating element.

The present invention is to provide a planar heating element having a heat effect is increased by changing the conventional side-by-side conducting electrode,

The technical problem of the present invention is to arrange the elongated electrode of the planar heating element used in the thermal mat or the thermal cushion by changing the inclination of the elongated electrode, or to change the shape of a portion of the side-by-side electrode to facilitate the control and maximize the thermal effect.

1 is a layout view of the electrode of the planar heating element having different inclination of the electrode according to the present invention

Figure 2 is an electrode arrangement of the planar heating element having a change in a portion of the electrode according to the present invention

3 is an example of electrode arrangement of a conventional planar heating element

Explanation of symbols on the main parts of the drawings

10: energized electrode

20: Planar heating electric resistor

30: power control line

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

1 is applied to a mat according to the present invention, the planar heating electric resistor in the configuration of various planar heating elements in which the heating means is provided with a film material containing conductive carbon black or a rubber plate or carbon fiber material containing conductive carbon black as a heating means ( 20 is a diagram showing a trapezoidal arrangement of the energizing electrodes 10 provided and arranged at predetermined intervals in order to supply electrical energy.

FIG. 3 shows the arrangement of side-by-side conducting electrodes 10 applied to a planar heating electrical resistor 20 of a planar heating element of a thermal mat or a thermal cushion sold in the related art.

To compare the effect according to the present invention in detail as follows.

In general, the planar heating element used for a thermal mat or a thermal cushion refers to a heating element that arranges an electric resistor in a plane, attaches a conducting electrode to both ends, and supplies electric energy to generate heat on the plane. In FIG. 3, since the electric resistors 21 facing the electrodes are connected in parallel through the conducting electrodes, when the voltage is applied to the conducting electrodes through the power control line 30, the electric resistors per length receive the same voltage. . The amount of heat generated by the electrical resistors 21 per length connected in parallel and receiving the same voltage is proportional to the square of the applied voltage and inversely proportional to the electrical resistance. In other words, it is as follows.

Calorific value = square of applied voltage / electrical resistance

And if the surface electrical properties are the same, the electric resistance 21 per length is proportional to the shortest distance from one electrode to the other electrode of the conducting electrode. Therefore, as shown in FIG. 3, when the conducting electrodes of the planar heating element are side by side, the same heat is generated on all surfaces because the distance between the two electrodes is the same.

However, as shown in FIG. 1, when the conducting electrodes of the planar heating element are arranged in a trapezoid, the length of the resistor per length is long in the A region, and the length of the resistor per length is short in the B region, and the electrical resistance of the resistor per length of the A region is large. Therefore, when a voltage is applied to the power control line 30, the A and B regions connected in parallel receive the same voltage, but the resistance of the A region is larger than the B region, so that the A region is a low temperature region because the amount of heat generated is low. A large amount of heat is generated to become a high temperature region.

When the conducting electrodes of the planar heating element are arranged in a trapezoidal shape as shown in FIG. 1, the temperature at the left end of the area A is lowest, and the temperature is gradually increased as it moves to the area B, so that the temperature at the right end of the area B is highest. Using this planar heating element in a thermal mat, if the mat is made, the area A is headed, and the area B is used as a leg, the foot is warmed and the head is cooled. .

Even with the same electrical energy and control conditions, more effective thermal effect can be expected by using a planar heating element like the present invention.

Figure 2 is applied to the hemorrhoidal treatment auxiliary cushion in accordance with the present invention, it shows a conducting electrode 10 is applied to the center portion of the parallel conducting electrode provided at both ends of the planar electrical resistor 20 of the various planar heating element . The hemorrhoidal treatment aid cushion that is commonly sold consists of a double heating element, a planar heating element for heating the whole to a low temperature and a heating element for providing a high temperature in the center. However, the planar heating element according to the present invention has a low electric resistance per length of the central portion (B) to generate a lot of heat to become a high temperature region, the electric resistance per length of the other region (A) is a large amount of heat generation is low, so the low temperature region do. By adjusting the width and the interval at which deformation is applied in the conducting electrode, the size and temperature of the high temperature region can be adjusted to a desired value. Therefore, it is possible to provide a high temperature and low temperature at the same time in one plane heating element by deforming the conducting electrode, it is possible to maximize the convenience of control and the efficiency of electrical energy.

According to the present invention, the heat generating amount of the planar heating element is effectively changed by changing the arrangement of the conducting electrodes of the planar heating element or changing the shape of the conducting electrode, thereby maximizing the thermal effect of the thermal product using the planar heating element, Efficiency improvement is expected.

Claims (1)

In the planar heating element provided by means of heat generation and thermal insulation drying, etc., in the configuration of a conducting electrode that is connected at predetermined intervals in order to supply electricity from the planar heating element provided by the heat generating means, The conduction electrode is configured to change the inclination of the conducting electrodes arranged at predetermined intervals, to change the spacing, or to change the shape of a portion of the conducting electrodes so as to generate more heat generation of the planar heating element at a desired portion. Plane heating element made of.