KR200430837Y1 - Plane type heating element - Google Patents

Abstract

The present invention relates to a planar heating element, and more particularly, to a planar heating element to maximize the far-infrared radiating effect by printing a carbon paste on the insulating film to form a carbon heating element and printing a far-infrared radiating material such as jade therebetween.

The object of the present invention is to provide a planar heating element having a high heat generating efficiency, the heating element is heated evenly as a whole, there is no change in temperature even if some disconnection. Another object of the present invention is to provide a planar heating element rich in far-infrared radiation of various wavelengths.

The present invention is an insulating film; A heat generating unit including a pair of first carbon heating elements formed by printing carbon pastes on both ends of the insulating film and a plurality of second carbon heating elements formed by printing carbon pastes to connect each of the first carbon heating elements; An electrical conductive part including a silver current collector formed by printing a silver paste on the first carbon heating element and a copper foil contacting the silver current collector to supply power; And a far infrared ray generator formed by printing at least one of the plurality of far infrared ray emitting materials between the second carbon heating elements.

Planar heating element, far infrared ray, carbon

Description

Planar heating element {PLANE TYPE HEATING ELEMENT}

1 is a perspective view of a conventional planar heating element,

2 is a perspective view of a planar heating element which is an embodiment of the present invention;

3 is a plan view of a planar heating element which is an embodiment of the present invention;

4 is a cross-sectional view of a planar heating element which is an embodiment of the present invention;

5 is a plan view of a planar heating element which is another embodiment of the present invention.

<Short description of the symbols in the drawings>

1: heating plate 3: epoxy resin

5: electrode 10: insulating film

20: heat generating portion 21: the first carbon heating element

22: second carbon heating element 30: electrical conductive portion

31: whole silver 32: copper foil

33: energized wire 40: far infrared ray generator

The present invention relates to a planar heating element, and more particularly, to a planar heating element to maximize the far-infrared radiating effect by printing a carbon paste on the insulating film to form a carbon heating element and printing a far-infrared radiating material such as jade therebetween.

The conventional planar heating element generates heat by connecting a heating wire made of a conductive resistor such as copper in series between the insulating pads, or a heating plate (1) made by applying plate carbon paper or carbon component as shown in FIG. Both surfaces were coated with resin (3), such as epoxy.

In the case of electrons using a hot wire, the electromagnetic wave emitted from the hot wire is harmful to the human body, and when the part of the hot wire is disconnected, the planar heating element does not function as a whole, and there is a problem in storage and transportation due to its bulky and heavy.

In the latter case of generating heat by applying power to a plate-shaped heating plate, electricity flows through a path of least resistance between the electrodes to which the electric power of the heating plate is supplied, so that the heating portion is uneven when the resistance is uneven. There was a problem.

Planar heating elements are also being developed in which heating elements in the form of strips, rather than heating plates, are connected in parallel, but even in the event of a disconnection in some strips, no heat is generated in the corresponding area, There is a risk.

In addition, the heating element using the carbon component has the advantage of providing a comfortable feeling of heating by emitting far infrared rays by itself, but for the planar heating element emitting a greater amount of far infrared rays, a pad made of a far infrared ray emitting material such as jade on top of the surface heating element Are attached.

By the way, the pad is inferior in flexibility, thick thickness, there is a problem in transport and construction, the heat of the heating element is also an obstacle to the transfer to the outside.

The present invention has been proposed in view of the above, and the object of the present invention is to provide a planar heating element that is heated evenly throughout the heating element and there is no local temperature change and there is little risk of fire even in case of partial disconnection.

Another object of the present invention is to provide a planar heating element with a compact printing of carbon to improve the heat generation efficiency.

Still another object of the present invention is to provide a planar heating element rich in far infrared radiation by printing a plurality of far-infrared radiating materials between heating elements.

In order to achieve the above object, the present invention is an insulating film; A heat generating unit including a pair of first carbon heating elements formed by printing carbon pastes on both ends of the insulating film and a plurality of second carbon heating elements formed by printing carbon pastes to connect each of the first carbon heating elements; An electrical conductive part including a silver current collector formed by printing a silver paste on the first carbon heating element and a copper foil contacting the silver current collector to supply power; And between the second carbon heating element, characterized in that it comprises a far infrared ray generator formed by printing at least one or more far-infrared radiation material selected from the group consisting of jade, loess, charcoal, ganban stone, gansumite, germanium, far infrared ceramics.

The printing is characterized in that the gravure printing to be printed in duplicate by using a copper plate 175 to 300 of the mesh.

In addition, the second carbon heating element may be connected to the first carbon heating element in a net form, or may be connected to the first carbon heating element in a straight line at a predetermined interval.

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

Figure 2 is a perspective view of a planar heating element according to an embodiment of the present invention, Figure 3 is a schematic plan view according to an embodiment of the present invention.

Referring to FIG. 3, the planar heating element according to an embodiment of the present invention includes an insulating film 10, a heat generating part 20, an electric conductive part 30, and a far infrared ray generator 40.

The insulating film 10 prevents electric shocks caused by external moisture infiltration or contact of a conductor and overheating of the heat generating part 20 when the power is supplied, and prevents physical damage of the heat generating part 20 and the far infrared ray generator 40. It acts as a protective film.

Insulating film 10 is generally made of polyethylene (PET) component, it is possible to use a film made of a variety of thermoplastic resins in addition to polyethylene, it is also possible to form an insulating film using an epoxy (epoxy) resin.

The heat generating unit 20 is also formed by printing carbon paste so as to connect each of the pair of first carbon heating elements 21 and the first carbon heating elements 21 formed by printing carbon pastes on both ends of the insulating film 10. It consists of a plurality of second carbon heating elements 22.

The carbon paste is a liquid substance formed by mixing synthetic resin with carbon black and a binder, which is a fine carbon powder, and is applied to the insulating film by a printing method.

Carbon black is characterized by strong heat resistance, good thermal conductivity, and low coefficient of thermal expansion. In particular, in the case of using copper wire as a heating element like a conventional heating wire, the resistance of the heating element increases as the temperature increases, but the efficiency of the heating element decreases.However, since carbon black is a semiconductor, the resistance is rather low when heat is applied. There is a self-regulation effect that slows the rise.

4 is a cross-sectional view of the planar heating element of the present invention. Referring to FIG. 4, it can be seen that the copper thin plate 32, the silver current collector 31, and the first carbon heating element 21 form a layer.

Power supply to the first carbon heating element 21 is made through a copper thin plate 32 connected to the conductive wire 33 and the conductive wire 33, between the copper thin plate 32 and the first carbon heating element 21 In order to smooth the current flow, a silver current collector 31 printed with silver paste is formed between the first carbon heating element 21 and the copper thin plate 32.

When directly connected to the carbon heating element 21 in the copper thin plate 32, the resistance value between the copper thin plate 32 and the carbon heating element 21 is changed rapidly, there is a possibility of overheating and sparking at the connection portion.

In particular, sparks generated when a poor contact occurs between the copper foil and the carbon heating element may cause a fire.

In order to reduce the sudden change in the resistance value and to eliminate the possibility of sparks, in the present invention, the silver paste was printed between the copper foil and the carbon heating element to smooth the flow of current.

In addition, as shown in Figure 3, between the second carbon heating element 22 various kinds of far-infrared radiating material is applied to form a far-infrared generator 40, the far-infrared generator 40 also by a printing method Is formed.

Far-infrared rays are light rays between about 4 μm and 1000 μm, with wavelengths of 8 to 16 μm being known to be most beneficial to the human body. This is because far infrared rays, unlike ultraviolet rays, have a long wavelength and can penetrate deep into the skin, and are irradiated with moisture and protein molecules constituting cells in the human body, causing resonance.

Through this resonance, the cell activity is vigorous, and heat energy generated in the process increases the body temperature, and at the same time, the expansion of the microvascular vessels and the enhancement of blood circulation has the effect of strengthening metabolism.

In addition, the heat is not simply transmitted from the skin surface, but because the heat is generated inside the body, the body warms up quickly and has the advantage of feeling the heat more smoothly at the same temperature.

The carbon heating element itself emits far infrared rays as a kind of far infrared ray emitting material. However, since the wavelengths of the far infrared rays emitted at a constant temperature for each material are different from each other, the degree of penetration of the far infrared rays into the irradiated material or the human body may vary.

Therefore, according to the physical condition of the person who is exposed to the far infrared rays, various far infrared rays are required depending on the kind of the material to be irradiated and dried.

In the present invention, by forming various kinds of far-infrared material in the planar heating element, there is an effect of emitting far-infrared rays of various wavelengths.

To this end, the present invention uses at least one far-infrared radiation material selected from the group consisting of jade, ocher, charcoal, ganban stone, macsumite, germanium, far infrared ceramics.

In addition, the energy radiated into the far infrared is related to the temperature of the far infrared radiating material, and the higher the temperature, the greater the amount of far infrared radiation.

In the present invention, by forming the far-infrared generator 40 between the second carbon heating element 22, the amount of energy radiated in far-infrared radiation is far greater than that of attaching the far-infrared radiation substance to the heating element in a simple pad form as in the prior art. Will be increased further.

While reducing the individual size of the far-infrared generator 40, a greater amount of far-infrared rays can be radiated if the spacing between the heating parts is tight.

Printing of carbon paste and silver paste is performed by a gravure printing method, and in particular, overlapping printing is performed using a copper plate having a bow of 175 to 300.

Gravure printing is a method of processing the grooves on the outer surface of the printing roller, and continuously printing while passing the to-be-printed (insulating film) between the printing roller and the press-in roller while the grooves contain the ink.

Conventionally, screen printing was used, but in the present invention, mass production was possible by using gravure printing, and as a result, it was possible to economically produce a planar heating element.

In particular, the general gravure printing is a single printing method for performing a single print, but the present invention was implemented a plurality of printing methods for printing in duplicate by using a copper plate of 175 to 300 mesh. In the conventional single printing method, since the denseness of the carbon component, which is a heat generating material, decreases in the planar heating element, the efficiency decreases and there is a problem in that disconnection occurs.

However, in the present invention, by repeatedly printing the carbon paste, the carbon heating element can be manufactured more densely, thus increasing the efficiency and reducing the risk of disconnection.

5 is a schematic plan view according to another embodiment of the present invention.

Referring to FIG. 5, in the planar heating element according to another embodiment of the present invention, the second carbon heating element 22 is connected to the first carbon heating element 21 in a mesh form.

As shown in FIG. 3, when the second carbon heating element 22 is connected to the first carbon heating element 21 in a straight shape, the second carbon heating element 22 is easy to manufacture, and the second carbon heating element 22 is made of a carbon heating element as compared to the case where the insulating film 10 is completely covered with the carbon heating element. 1 There is an advantage that the current is evenly supplied through both carbon heating elements.

However, when some of the second carbon heating elements are broken and disconnected, there may be a problem in that heat is not generated.

The mesh type carbon heating element collects only the advantages of the plate-type carbon heating element and the ladder-shaped carbon heating element, and the current flows evenly without biasing part of the current. Using current has the advantage of minimizing damage due to disconnection.

In addition, since it is easy to reduce the individual size of the far-infrared radiation substance, it is possible to increase the far-infrared radiation effect.

The planar heating element of the present invention is heated evenly as a whole, so that the local temperature difference is weak, and even in case of some disconnection, it is possible to provide an even temperature and reduce the risk of fire.

In addition, since far infrared rays of various wavelengths are radiated through various kinds of far infrared ray radiating materials, the effect of irradiating far infrared rays is greater than that of irradiating far infrared rays of a single wavelength.

In addition, by placing a far-infrared radiation material between the carbon heating element to increase the radiant energy, the heating and drying effect is great.

As mentioned above, although preferred embodiments of the present invention have been described, this is merely an embodiment of the present invention, and may have various embodiments within the scope of the technical idea of the present invention implemented in the claims. to be.

Claims (4)

Insulating film; A heat generating unit including a pair of first carbon heating elements formed by printing carbon pastes on both ends of the insulating film and a plurality of second carbon heating elements formed by printing carbon pastes to connect each of the first carbon heating elements; An electrical conductive part including a silver current collector formed by printing a silver paste on the first carbon heating element and a copper foil contacting the silver current collector to supply power; And A far infrared ray generator formed between the second carbon heating elements by printing at least one far infrared ray emitting material selected from the group consisting of jade, loess, charcoal, ganban stone, macsumite, germanium and far infrared ceramics; Planar heating element comprising a. The method of claim 1, The printing is a planar heating element, characterized in that the gravure printing to overlap printing using a copper plate 175 to 300 of the bow of the mesh. The method according to claim 1 or 2, The second carbon heating element is a planar heating element, characterized in that connected to the first carbon heating element in the form of a net. The method according to claim 1 or 2, The second carbon heating element is a planar heating element, characterized in that connected to the first carbon heating element in a straight line at a predetermined interval.

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