KR20130100388A - Plate heater and manufacturing method of plate heater - Google Patents

Abstract

PURPOSE: A plate heater and a manufacturing method thereof are provided to reduce power loss and power consumption by forming the plate heater of carbon to increase electrical conductivity and to remove electromagnetic waves by alternatively arranging the electricity inlets and outlets of electrode wires to offset the electromagnetic waves generated from the electrode wires. CONSTITUTION: A plate heater comprises a first conductor (10), a second conductor (20), a current carrier (30), multiple first electrode wires (11), multiple second electrode wires (21), and an insulator (50). The first conductor is arranged in a horizontal thread direction. The second conductor is arranged in parallel to the first conductor. The current carrier is arranged in parallel to the second conductor. The first conductor and the current carrier are connected in an inclined thread direction. The first electrode wires are arranged at regular intervals and connect the first conductor and the current carrier in an inclined thread direction. The first electrode wires generate heat when power is applied. The second electrode wires are arranged between first electrode wires and connect the second conductor and the current carrier. The second electrode wires generate heat when the power is applied. The insulator is arranged between the first and second electrode wires to prevent short circuit between the second conductor and the first electrode wires.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate heater,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a planar heating element and a planar heating element. More particularly, the present invention relates to a method of manufacturing a planar heating element and a planar heating element by alternately arranging heat generating electrode lines so that a power input direction and an output direction are opposite to each other, And a method of manufacturing a planar heating element and a planar heating element capable of solving the adverse effects caused by electromagnetic waves.

In general, the surface heat generating element is applied to various fields such as a heating mattress, a building wall surface, a partition, and the like, and is used for heating, or installed on a glass of a vehicle to be used for preventing sexuality. It has excellent heat generation rate, low electric power consumption rate, smoothness and durability, and is thus usefully used.

Such a conventional planar heating element has a structure in which the positive electrode conductor 1 and the negative electrode conductor 2 are positioned so as to be spaced apart from each other as shown in Fig. 1, and the positive electrode conductor 1 and the negative electrode conductor 2 and the carbon-carbon heating element 3 are positioned between the positive electrode 1 and the negative electrode 2 so that the positive electrode 1 and the negative electrode 2 are electrically connected to each other, The carbon-carbon heating element 3 is heated by the electric energy applied to the carbon-carbon heating element 3 so as to obtain heat energy.

In the process of supplying electricity to the carbon-carbon heating element 3, electromagnetic waves are generated in the carbon-carbon heating element 3, and the electromagnetic waves have a bad influence on the human body. When the surface heating element generating electromagnetic waves is used for a long time Headache, chronic fatigue, and muscle stiffness.

Meanwhile, as a method for shielding electromagnetic waves generated in the surface heat emission element, a shielding sheet using another shielding fiber, a silver foil, a gold foil or the like is separately laminated to shield electromagnetic waves generated in the surface heat emission element.

However, since the shielding sheet, which is an electromagnetic wave shielding means, generated by the surface heating element is expensive, the manufacturing cost is increased. Even if electromagnetic waves can be reduced, it is difficult to completely remove the shielding sheet. Another problem that is not good is being raised.

As a planar heating element for blocking electromagnetic waves, a planar heating element having an electromagnetic wave shielding function, which is disclosed in Japanese Patent No. 10-0703191, has been proposed. This is a mat or film having a thickness of 0.005 to 1.2 mm, An electromagnetic wave shielding layer deposited on one or both sides of a film selected from copper, silver, gold, and aluminum laminated on the upper surface of the conductive layer; and an upper surface of the electromagnetic wave shielding layer, Layer and a conductive layer, and an insulating layer laminated on the lower surface of the conductive layer and formed to be laterally longer than the electromagnetic wave shielding layer and the conductive layer, and both left and right ends of the insulating layers are sealed, , And the electromagnetic wave shielding layer is provided with a ground.

In such a conventional technique, electromagnetic waves generated by the electromagnetic wave shielding layer structure are shielded. However, the price of the surface heating element is expensive due to the electromagnetic wave shielding layer made of expensive materials such as copper, silver and gold, There is a problem in that a manufacturing process is added by further constituting an electromagnetic wave shielding layer, resulting in a problem that productivity and workability are greatly deteriorated.

In addition, the conventional planar heating elements require a large amount of electric power because the electrical conductivity of the electric energy applied from the conductor is greatly reduced, and thus there is a problem that the electric power is wasted and the electric power is burdened.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems of the conventional planar heating elements, and it is an object of the present invention to provide a planar heating element which comprises a heating element of a planar heating element as a carbon heating element, And an object of the present invention is to provide a planar heating element and a planar heating element which can eliminate electromagnetic waves by alternately arranging electrode lines so that the input direction and the output direction of the planar heating element are opposite to each other.

In the present invention for achieving the above object, in the planar heating element woven with warp and weft,

A first conductor disposed in the weft direction; and

A second conductor disposed parallel to the first conductor apart from the first conductor by a predetermined distance; and

A current collector disposed parallel to the second conductor by a predetermined distance from the second conductor; and

A plurality of first electrode wires connecting the first conductor and the current collector in the inclined direction and being woven at equal intervals to generate heat when the power is applied; and

A plurality of second electrode lines connecting the second conductor and the current collector in the inclined direction, the plurality of second electrode wires being woven between the plurality of first polar lines and being woven, and generating heat when power is applied; And

And an insulator disposed between the second conductor and the first electrode line to prevent the second conductor and the first electrode line from being short-circuited.

When power is input to the first conductor, electricity is sequentially output through the second conductor through the first electrode line, the current collector, and the second electrode line, and when power is input to the second conductor, electricity is sequentially. The electromagnetic field is canceled by the second electrode line, the current collector, and the first electrode line being output through the first conductor, and the direction of electricity flowing through the first electrode line and the direction of power flowing through the second electrode line alternate with each other. It is achieved by the planar heating element, characterized in that the electromagnetic wave is removed.

In addition, the first electrode line and the second electrode line is characterized in that the carbon heating element.

In addition, the insulator,

The warp yarn and the weft yarn may be woven between the second conductor and the first electrode line.

On the other hand, the present invention for achieving the above object, the process of arranging a plurality of first electrode lines and a plurality of second electrode lines at equal intervals between the inclined direction and the inclined direction in the process of arranging the inclined (제); 1 step;

A second step of installing a current collector in a weft direction so that the plurality of first electrode lines and the plurality of second electrode lines are connected to each other after the first step;

A third step of weaving the warp yarn, the plurality of first electrode lines and the plurality of second electrode lines and the weft yarn after the second process;

A fourth step of installing a second conductor in the weft direction so as to be connected to the second electrode lines at a position spaced apart from the current collector by a predetermined distance during the third step;

A fifth step of installing an insulator in the weft direction so as to insulate between the second conductor and the first electrode line after the fourth step; And

And a sixth step of installing the first conductor in the weft direction so as to be connected to the first electrode lines after the fifth step.

The method may further include a seventh process of cutting the inclined, the first electrode lines, and the second electrode lines after the sixth process.

The present invention has the effect of eliminating electromagnetic waves by disposing the electrode lines so that the directions of inputting currents and outputting directions are opposite to each other, by canceling each other between an electromagnetic field generated by inputting a current and an electromagnetic field generated by outputting a current.

Further, when the carbon heating element is used for overloading, there is an effect of preventing the carbon heating element from being broken and causing a fire. In addition, since the carbon heating element is used, power consumption can be minimized.

In addition, it can be continuously produced as a fabric, thereby improving the productivity.

1 is a configuration diagram showing the configuration of a conventional planar heating element.
2 is a flowchart showing a process of a method of manufacturing a planar heating element according to the present invention.
3 is a schematic view of a planar heating element according to the present invention.
4 is a view schematically showing an operating state in which electromagnetic waves are canceled by the planar heating element of the present invention.
5 is a cross-sectional view schematically illustrating a state in which an insulator is installed between the first electrode line and the second conductor in the planar heating element of the present invention.

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

As shown, the planar heating element of the present invention includes a first conductor 10, a first electrode line 11, a second conductor 20, a second electrode line 21, a current collector 30, and an insulator 50. It is done.

A plurality of first electrode lines 11 are electrically extended to the first conductor 10 to be electrically connected to the current collector 30. In this case, when the first electrode line 11 uses a carbon heating element and power is supplied to the first conductor 10, the first electrode line 11 generates heat.

In addition, the second conductor 20 is electrically connected to the second electrode lines 21, and is disposed between the first electrode lines 11 of the first conductor 10 to be electrically connected to the current collector 30. do. In this case, when the second electrode line 21 uses a carbon heating element and power is supplied to the second conductor 20, the second electrode line 21 generates heat. Here, the non-combustible and insulating fibers 40, that is, weft yarns, are formed between the first electrode line 11 and the second electrode line 21 so that the first electrode line 11 and the second electrode line 21 do not adhere to each other. ) And inclined. That is, the first electrode line 11 and the second electrode line 21 are prevented from being shorted to each other by maintaining a fixed distance between the first electrode line 11 and the second electrode line 21 by weft and inclination. Can be.

On the other hand, when the first electrode line 11 or the second electrode line 21 is overloaded, overheating may occur in the first electrode line 11 or the second electrode line 21 and a fire may occur. However, according to the present invention, the first electrode line 11 and the second electrode line 21 are formed of a carbon heating element so that the first electrode line 11 or the second electrode line 21 is cut off when overheated, thereby preventing a fire.

Here, when the first electrode line 11 and the second electrode line 21 are energized by the barrel 30 and power is applied to the first conductor 10, electricity is sequentially supplied to the first electrode line 11, The second conductor 20, and the second conductor 20 through the first and second electrode lines 30 and 21, respectively. Accordingly, the first electrode line 11 and the second electrode line 21 generate heat by electricity applied to the first conductor 10. When power is applied to the second conductor 20, electricity is sequentially supplied to the second electrode line 21, the barrel 30, the first electrode line 11, And then through the first conductor 10.

The planar heating element of the present invention configured as described above is configured such that the second electrode lines 21 are disposed between the first electrode lines 11 in the oblique direction, so that electricity flowing through the first electrode lines 11 and the second electrode lines 21 flows. Since the directions of cross each other, the electromagnetic fields cancel each other and can eliminate electromagnetic waves. Therefore, the planar heating element which does not generate electromagnetic waves can be manufactured.

However, in the conventional planar heating element, electromagnetic waves are generated by the electromagnetic field because electricity flows in one direction, but the planar heating element of the present invention cancels the electromagnetic fields by forming the input and output directions of electricity in opposite directions, respectively. Electromagnetic waves are removed. Therefore, the planar heating element of the present invention can prevent damage caused by electromagnetic waves even when used for a long time by removing the electromagnetic waves.

The insulator 50 is further provided between the second conductor 20 and the first electrode lines 11 to prevent the second conductor 20 and the first electrode line 11 from being short-circuited.

The insulator 50 satisfies all of the non-combustible materials while blocking the electrical contact, and the insulator 50 can prevent the first electrode line 11 and the second conductor 20 from being shorted to each other. In addition, the insulator 50 may be formed by weaving the weft of the fiber 40 and the warp.

The first electrode line and the second electrode line described above may be woven in a state where an insulator (not shown) is applied to the outer surface. In this case, the above-described insulator can be omitted.

Hereinafter, a method of manufacturing a planar heating element according to an embodiment of the present invention will be described.

As shown in FIG. 2, in the planar heating element manufacturing method according to an embodiment of the present invention, the first process S1 and the current collector 30 for arranging the first electrode line 11 and the second electrode line 21 are performed. The second process (S2) to be installed, the third process (S3) to weave the warp yarn formed by the fiber 40 and the warp yarn, the fourth process (S4) to which the second conductor 20 is installed, and the insulator (50) are installed. 6th process S6 in which 5th process S5 and the 1st conductor 10 are installed are included. Here, the method further includes a seventh step (S7) of cutting the warp yarn.

In the first step S1, a plurality of slopes formed of a plurality of first electrode lines 11 and a plurality of second electrode lines 21 formed of a carbon heating element and insulating and nonflammable fibers 40 are disposed, The first electrode line 11 and the second electrode line 21 are arranged side by side between the slopes of the first electrode line 11 and the second electrode line 21 at regular intervals.

The second step S2 includes a step of installing the barrel 30 in the weft direction so that the plurality of first electrode lines 11 and the plurality of second electrode lines 21 are connected to each other through the first step S1 to be. Accordingly, the first electrode line 11 and the second electrode line 21 are connected to each other by the barrel 30.

The third step S3 is a step in which a plurality of wefts formed by the inclination, the first electrode line 11 and the second electrode line 21 through the second step S2 and the insulating and nonflammable fibers 40 are weighed to be. The first electrode line 11 and the second electrode line 21 and the weft are woven so that the first electrode line 11 and the second electrode line 21 are bonded to the fiber 40 .

In the fourth step S4, the warp, the first electrode line 11 and the second electrode line 21 in the course of the third step (S3), and the second electrode line 21 when the weft is woven for a predetermined interval, The second conductor 20 is installed in the weft direction. The second electrode lines 21 are connected to each other by the second conductor 20 and when the power is applied through the second conductor 20, the current flows through the second electrode lines 21, .

The fifth step S5 is a step between the second conductor 20 and the first electrode line 11 so as to be insulated between the second conductor 20 and the first electrode line 11 after the fourth step S4. In which the insulator 50 and the non-combustible insulator 50 are provided. At this time, the insulator 50 may be formed by weaving warp and weft formed of insulating and nonflammable fibers 40, or may be provided with sheets of insulating and nonflammable material. Accordingly, the insulator 50 prevents the second conductor 20 and the first electrode line 11 from being short-circuited.

In the sixth step S6, the first conductor 10 is installed in the weft direction so that the first electrode lines 11 are connected to each other after the fifth step S5, In a stepwise manner. The first electrode lines 11 are connected by the first conductor 10 and the first electrode lines 11 are electrically connected to the first electrode lines 11 when current is supplied through the first conductor 10, .

Here, when power is applied to the first conductor 10, the current flows through the first electrode lines 11 to the barrel 30, and is output through the second conductor 20 via the second electrode lines 21. At this time, when power is applied to the second conductor 20, the current flows in the opposite direction. Therefore, when power is applied to either the first conductor 10 or the second conductor 20, the current flows to both the first electrode line 11 and the second electrode line 21.

In the seventh step S7, after the sixth step S6, the slanted first electrode lines 11 and the second electrode lines 21 are cut to form a planar heating element having a predetermined size. It is a process. Accordingly, the planar heating element that is continuously produced can be produced in a constant size.

Although the first steps (S1) to the sixth step (S6) in the present invention has been described as proceeding sequentially, the first step (S1) to the sixth step (S6) proceeds in the reverse order may produce a planar heating element have.

In the planar heating element manufactured by the method of manufacturing the planar heating element of the present invention having the above-described structure, since the first electrode lines 11 are arranged alternately with the second electrode lines 21 interposed therebetween, So that the canceling action of the electromagnetic wave generated by the electrical resistance is achieved.

That is, when power is input to the first electrode line 11, the second electrode line 21 is outputted with electricity, and when power is input to the second electrode line 21, the first electrode line 11 is outputted with electricity to generate the first electrode line. As the directions of the currents flowing through the 11 and the second electrode lines 21 flow in opposite directions, the electromagnetic fields generated by the first electrode lines 11 and the second electrode lines 21 cancel each other to remove the electromagnetic waves. Therefore, the planar heating element which does not generate electromagnetic waves can be manufactured.

In describing the present invention described above, even if the embodiment is different, the same reference numerals are used for the same configuration, and the description may be omitted as necessary.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Shall not be construed as being understood. Therefore, a person having ordinary knowledge in the technical field to which the present invention pertains may easily implement other forms of the present invention within the same scope as the above-described embodiments, or the present invention only by the description of the embodiments of the present invention. It will be possible to practice the invention in the same and equal range.

10: first conductor
11: first electrode line
20: second conductor
21: second electrode line
30: Trough whole
40: fiber
50: Insulator
S1: First step
S2: second process
S3: Third step
S4: Fourth step
S5: fifth step
S6: sixth step
S7: Seventh step

Claims (5)

In the planar heating element which is woven with warp and weft,
A first conductor disposed in the weft direction;
A second conductor disposed parallel to the first conductor apart from the first conductor by a predetermined distance;
A current collector arranged in parallel apart from the second conductor by a predetermined interval;
A plurality of first electrode lines connecting the first conductor and the current collector in the inclined direction, the plurality of first electrode wires being woven at equal intervals and generating heat when power is applied;
A plurality of second electrode lines connecting the second conductor and the current collector in the inclined direction, the plurality of second electrode wires being woven between the plurality of first polar lines and being woven, and generating heat when power is applied; And
And an insulator disposed between the second conductor and the first electrode line to prevent the second conductor and the first electrode line from being short-circuited.
When electricity is input to the first conductor, electricity is sequentially output through the second conductor through the first electrode line, the current collector, and the second electrode line, and when power is input to the second conductor, electricity is sequentially. The electromagnetic field is canceled by the second electrode line, the current collector, and the first electrode line being output through the first conductor, and the direction of electricity flowing through the first electrode line and the direction of power flowing through the second electrode line alternate with each other. Planar heating element, characterized in that the electromagnetic wave is removed.
The method according to claim 1,
And the first electrode line and the second electrode line are carbon heating elements.
The method according to claim 1,
The insulator
And the warp yarn and the weft yarn are woven between the second conductor and the first electrode line.
A first step of arranging a plurality of first electrode lines and a plurality of second electrode lines at equal intervals between an inclination and an inclination in an oblique direction in a process of disposing warp yarns;
A second process in which a plurality of first electrode lines and a plurality of second electrode lines are connected to each other after the first process is installed in a weft yarn direction;
A third step in which the warp yarns, a plurality of the first electrode yarns and a plurality of the second electrode yarns and the weft yarns are woven after the second process;
A fourth step of installing a second conductor in the weft direction so as to be connected to the second electrode lines at a position spaced apart from the barrel by a predetermined distance in the course of the third step;
A fifth step of installing an insulator in the weft direction so as to insulate between the second conductor and the first electrode line after the fourth step; And
And a sixth step of installing the first conductor in the weft direction so as to be connected to the first electrode lines after the fifth step.
The method of claim 4,
And a seventh process of cutting the inclined, the first electrode lines, and the second electrode lines after the sixth process.

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