KR200414024Y1 - Heating Wire for Radiating Far Infrared Ray - Google Patents

Abstract

The present invention is to allow the far-infrared rays to be radiated from the heating line itself used in the heater, such as electric blanket, electric yoke, electric steamer, more specifically, containing the far-infrared radiation material in the heating line itself that can offset the induced magnetic field Therefore, it is for a non-magnetic heating wire that allows the far-infrared radiation itself can be radiated even when the heating element is not arranged in the heater when a separate far-infrared radiating material. The constitution of the present invention comprises a first heating wire, a synthetic resin insulating layer or an NTC thermistor layer, an inner coating layer surrounding the first heating wire, a second heating wire wound on the first coating, and an outer coating layer wrapping the outer side of the second heating wire. And the current flowing in the first heating wire and the current flowing in the second heating wire are opposite to each other, and the inner coating layer or the outer coating layer contains a far infrared ray emitting material.

The present invention has the effect of allowing the heating device to radiate far infrared rays only by using a heating wire, even without introducing a separate far-infrared radiation configuration. In addition, the present invention has the effect of allowing far-infrared rays to be radiated in a magnetic field-free heating line without a leakage magnetic field.

Description

Far Infrared Ray Infrared Rays {Heating Wire for Radiating Far Infrared Ray}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing an exploded view of a conventional far-infrared radiation beam.

2 is a view showing the far-infrared radiation non-magnetic heating line of the present invention.

3 is a view showing another far-infrared radiation non-magnetic heating line of the present invention.

4 is a view showing another far-infrared radiation-free magnetic field heating line of the present invention.

5 is a view showing another far-infrared radiation non-magnetic heating line of the present invention.

6 is a view showing another far-infrared radiation non-magnetic heating line of the present invention.

7 is a view showing the far-infrared radiation material contained in the far-infrared radiation induction heating line of the present invention.

8 is a view schematically showing that far-infrared radiation is emitted from the far-infrared radiation-free heating line of the present invention.

<Description of Signs of Major Parts of Drawings>

1: ventricle 2: 1st heating wire

3: inner coating layer 4: second heating wire

5: outer coating layer 6: conductive layer

7: second outer coating layer 10: far infrared radiation material

The present invention is to allow the far-infrared rays to be radiated from the heating line itself used in the heater, such as electric blanket, electric yoke, electric steamer, more specifically, containing the far-infrared radiation material in the heating line itself that can offset the induced magnetic field Therefore, it is for a non-magnetic heating wire that allows the far-infrared radiation itself can be radiated even when the heating element is not arranged in the heater when a separate far-infrared radiating material.

Far infrared rays are infrared rays whose wavelength is 25 micrometers or more in steel, and mean the long wavelength among infrared rays. It is invisible, absorbs well into the material, and has strong resonance and resonance effects on organic compound molecules. It has good absorbing properties when it reaches an object. You get a warming effect. For example, you can hardly feel the warm energy in the water at 30 ℃, but sitting in the sun at the same temperature can feel warm because the infrared rays contained in the sun penetrates deep into the skin to create heat.

The thermal action of the far infrared helps to eliminate bacteria that cause various diseases, and expands the capillaries to help blood circulation and cell tissue production. In addition, by touching the water and protein molecules that make up the cells, the cells are shaken finely 2,000 times per minute to activate cell tissue, which is effective in preventing various adult diseases such as aging, promoting metabolism, and chronic fatigue. In addition, it promotes sweating, relieves pain, removes heavy metals, sleeps, deodorizes, disinfects, prevents mold growth, dehumidification, and purifies the air.It is effective in housing and building materials, kitchen utensils, textiles, clothing, bedding, medical equipment, and saunas. It is used in many fields.

Among them, in order to allow far infrared rays to be radiated from bedding, a method of disposing far infrared rays as a plane heating element is used. In general, in the case of various electric plates and electric wires, which are widely used as a convenient heating means, in order to radiate far infrared rays which are beneficial to the human body in addition to the heating effect by heating wires, a method of placing a material capable of emitting far infrared rays in the vicinity of the heating wires This will be described with reference to the drawings.

1 is a perspective view showing the configuration of the electric yaw according to the present invention, Figure 2 is a partially cutaway perspective view showing the configuration of the electric yaw according to the present invention, Figure 3 is a partially enlarged cross-sectional view showing the configuration of the electric yaw according to the present invention, The configuration consists of a cushion member 22, 25 capable of far-infrared radiation on both sides with a known heating line 23 interposed therebetween, and a floor member 21 and an exterior member 26 that surround the cushion member 22, 25, respectively. .

The cushion members 22 and 25 capable of far-infrared radiation are impregnated with a powder or a liquid by impregnating a material having excellent far-infrared radiation performance into a general cushioning material made of a cotton or the like having excellent cushioning property, or by other means. (25) It has a cushioning property and radiates a large amount of far infrared rays. In order to emit a large amount of far-infrared rays, the far-infrared radiation material impregnated in the materials forming the cushioning materials 22 and 25 and the flooring material 21 and the exterior material 26 may be various materials such as ceramic, jade, and ocher. In addition, these materials are impregnated in a powder or liquid form to impregnate the material of the desired cushioning material (22, 25) and the flooring material (21) and the exterior material (26).

According to the above configuration, when the electric yoke is laid on the floor and connected to a power source, the electric yoke is heated by the heating wire 23 and at the same time, a large amount from the cushion members 22, 25, the flooring material 21 and the exterior material 26 is used. Far-infrared rays are continuously radiated, so that the user can achieve a far-infrared-jjimjil effect along with the thermal effect, thereby obtaining the effect of health prevention by preventing disease and promoting blood circulation.

However, in such a structure, in order to radiate far infrared rays, it is cumbersome to separately provide cushioning materials 22 and 25 and flooring material 21 and exterior material 26 containing far-infrared radiation materials in the vicinity of the heating line 23. Therefore, there is a request for a configuration in which far infrared rays are radiated from the heating wire itself without such a configuration.

The object of the present invention is to provide a heating wire for a heating electric yoyo, an electric mat to allow the far-infrared radiation to be radiated from the heating wire while the heating wire is a magnetic field without generating an induction magnetic field.

The structure of the present invention for achieving the above object, the first heating wire, a synthetic resin insulating layer or NTC thermistor layer consisting of an inner coating layer surrounding the first heating wire, the second heating wire wound on the first coating, the second And an outer coating layer surrounding the outside of the heating wire, wherein the current flowing in the first heating wire and the current flowing in the second heating wire are in opposite directions, and the inner coating layer or the outer coating layer contains a far infrared ray emitting material. It features.

Or a first heating wire, a synthetic resin insulating layer, or an NTC thermistor layer, an inner coating layer surrounding the first heating wire, a second heating wire wound on the first coating, an outer coating layer surrounding the outside of the second heating wire, and an outer peripheral surface of the outer coating layer. And a metal shield wound around the second shielding layer, and a second outer coating layer surrounding the outer side of the metal shield, wherein the current flowing in the first heating wire and the current flowing in the second heating wire are opposite to each other, and the inner coating layer or the The outer coating layer or the second outer coating layer contains a far infrared ray emitting material.

The far-infrared radiation material is characterized in that it is provided contained in the form of a powder. The far-infrared radiation material is characterized in that it is provided contained in a liquid form. The far-infrared radiation material is characterized in that any one of ceramic, ocher, elvan, gansumite or jade.

Hereinafter, with reference to the embodiment of the present invention configuration shown in the accompanying drawings, it will be described in detail the configuration of the present invention.

2 to 6 is a view showing a variety of far-infrared radiation non-magnetic heating wire of the present invention. Referring to FIG. 2, a first heating wire 2, a first heating wire 2, spirally wound along a length direction in one direction on an outer circumferential surface of the ventricle 1 made of polyester or the like, and The inner coating layer 3 covering the outer circumferential surface of the ventricle 1, the second heating wire 4 spirally wound around the outer circumferential surface of the inner coating layer 3 at regular intervals, the inner coating layer 3, and the second heating wire 4. It is configured to include an outer coating layer (5) made of a synthetic resin material wrapped around.

The first heating wire 2 may be configured in various ways such that the opposite end of the power source is short-circuited with the second heating wire 4 or not to be short-circuited, and the current flows through the first heating wire 2 and the second heating wire 4. This is the opposite direction. The second heating wire 4 may be grounded or may be configured to have a plate shape and a surface shape as shown in FIG. 3.

The inner coating layer 3 may be made of an insulating synthetic resin or an NTC thermistor. In the case of an NTC thermistor, the thermistor reacts sensitively to temperature during operation of the temperature detection circuit. Because of this change, even if overheated at an arbitrary position affects the thermistor, and the heating wire itself automatically adjusts the amount of heat generated.

Therefore, the user sets the reference temperature, and when the temperature is higher than the reference temperature does not generate heat, and if the temperature is lower than the reference temperature, the temperature can be adjusted, and as a safety device to prevent overheating, as well as a function of controlling the temperature Will be able to perform

Various minerals that emit far infrared rays are contained in the inner coating layer 3 or the outer coating layer 5 in powder or liquid form. That is, when the raw material is in liquid form to form the inner coating layer 3 or the outer coating layer 5, minerals such as far-infrared radiation materials such as ceramics, loess, elvan, maculite or jade are added in powder form, or gels thereof. , Sol, liquid form to be mixed. When the heating operation progresses while the current flows in the first heating wire 2 or the second heating wire 4, the temperature of the inner coating layer 3 or the outer coating layer 5 increases, and the far-infrared radiation is contained in the far-infrared radiation material contained therein. It is radiated.

As another embodiment, referring to FIG. 4, instead of using the synthetic resin ventricle 1 and the heating wire wound around the first heating wire 2, the metal conductive wire 2a may be used. At this time, the operation principle of the heating wire is the same as before, but because of the relatively thick metal heat conducting wire (2a) there is a difference only in the bending or bending characteristics.

In some cases, as shown in FIG. 5, the energizing layer 6 may be wound between the second heating wire 4 and the outer coating layer 5. The conductive layer 6 includes an electrically conductive material, such as an electrically conductive synthetic resin, a metal thin film, a shield plate, a metal shield, and the like, and shields an electric field leaking from the inside together with the second heating wire 4, and charges to an external ground. It will function to discharge. Alternatively, as shown in FIG. 6, the conductive layer 6 may be provided on the outer side of the outer coating layer 5, and the outer side thereof may include the second outer coating layer 7. The far infrared emitting material may be optionally contained in the inner coating layer 3, the outer coating layer 5, or the second outer coating layer 7.

7 is a view showing the far-infrared radiation material contained in the far-infrared radiation-free heating element of the present invention, Figure 8 is a view schematically showing that far infrared radiation is emitted from the far-infrared radiation-free heating element of the present invention. 7 and 8, while the far-infrared radiation material 10 is contained in the outer coating layer 5, the outer coating layer is heated while the first heating wire 2 or the second heating wire 4 inside thereof is heated. The temperature of (5) is raised, and the far infrared ray emitting material 10 contained therein emits far infrared rays to the outside.

Therefore, even if the separate far-infrared radiator, the heating element is not provided inside the electric yoke, electric sheet, it is possible to emit far-infrared rays only by using the above-described heating line. In addition, since the heating wire has a function of canceling the induction magnetic field internally, the heating wire has an effect that the magnetic field does not leak outside the heating wire.

The present invention has the effect of allowing the heating device to radiate far infrared rays only by using a heating wire, even without introducing a separate far-infrared radiation configuration.

In addition, the present invention has the effect of allowing far-infrared rays to be radiated in a magnetic field-free heating line without a leakage magnetic field.

Claims (5)

First heating wire; An inner coating layer formed of a synthetic resin insulating layer or an NTC thermistor layer to surround the first heating wire; A second heating coil wound around the first coating; And Including an outer coating layer surrounding the outside of the second heating wire, The current flowing in the first heating wire and the current flowing in the second heating wire are made to be opposite to each other, And said inner coating layer or said outer coating layer contains far-infrared radiation material. First heating wire; An inner coating layer formed of a synthetic resin insulating layer or an NTC thermistor layer to surround the first heating wire; A second heating coil wound around the first coating; An outer coating layer surrounding an outer side of the second heating wire; A metal shield wound around an outer circumferential surface of the outer coating layer; And A second outer coating layer surrounding an outer side of the metal shield; The current flowing in the first heating wire and the current flowing in the second heating wire are made to be opposite to each other, And said inner coating layer or said outer coating layer or said second outer coating layer contains a far-infrared radiation material. The method according to claim 1 or 2, Far-infrared radiation-free heating element, characterized in that the far-infrared radiation material is contained in a powder form. The method according to claim 1 or 2, Far-infrared radiation-free heating element, characterized in that the far-infrared radiation material is contained in a liquid form. The method according to claim 1 or 2, The far-infrared radiation material is far-infrared radiation-free heating element, characterized in that any one of ceramic, ocher, ganban stone, macsumite or jade.

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