KR200252935Y1 - Far-infrared heater of fan shape - Google Patents

Abstract

The present invention relates to a small-sized fan-type far-infrared heater used for home or office use, and by mounting a quartz tube having a ceramic coating layer formed on a conventional far-infrared heating element, a quartz tube in which visible light emitted from the heating element together with far-infrared ray is formed on the ceramic coating layer. It is converted into far-infrared rays through the heat, so the heating value is high, and the heating effect is excellent, and the quartz tube without heat deformation protects the coil's heat shrinkage and expansion, which increases the durability of the stove, and the coil is not exposed to the outside. The present invention relates to a fan-type far-infrared heater equipped with a quartz tube having a ceramic coating layer formed therein to prevent electric shock and fire accidents and to prevent oxidation due to dust.

Description

Fan-type far infrared heater {Far-infrared heater of fan shape}

The present invention relates to a fan-type far-infrared heater, and more particularly, a heat generation amount is better than that of a conventional product by attaching a quartz tube 56, which forms a ceramic coating layer, to a conical radiator 51 wound with a coil 52. The present invention relates to a fan-type far-infrared heater that is excellent in durability and can prevent an electric shock or fire in advance.

In general, the heat transfer method of the heater is a lot of the method by the convection of the air generated by heating the heating firing products, the heat transfer is low compared to the radiant heat transfer, the heat effect is low and the temperature distribution in the heater is not constant, Since coal or petroleum are used as raw materials, there are many problems such as fuel cost and odor during combustion. Therefore, in order to remedy these drawbacks, multi-function far-infrared heaters that emit far-infrared radiation with good heat generation while satisfying the user's desire for health as well as various heaters using electricity as a pollution-free energy source without odors and smoke have been spotlighted.

As shown in FIG. 1, the conventional fan-type far-infrared heater includes a controller 11 for selecting a rotation and temperature function, and includes a base 10 serving to supply power, and a power source of the base 10 to the far infrared ray. The strut 20, which is a passage connecting to the heating element 50, the rotating part 30 that is responsible for the rotational movement of the heater, and the reflecting plate 40 which serves to transfer heat forward, are provided. The far-infrared heating element 50 is provided in the center part of 40, and the protection grill 60 is detachably attached to the front surface.

Referring to the drawings shown in FIG. 2, when looking at the far-infrared heating element 50, which is a main component of the fan-type far infrared heater, in detail, the nichrome wire coil 52 pivots around the outer circumferential surface of the ceramic radiator 51. It is fixed to the iron support 55 installed in the central portion of the reflector plate 40, it is to apply the power to the coil 52 to emit far infrared rays.

In general, far infrared rays are wavelengths in the range of 5.6 to 1000 micrometers from visible light to longer wavelengths than red. When the far infrared is used by the intensive heating method by radiation, most of the objects to be heated show a strong absorption band in the far infrared wavelength range. High efficiency heat transfer effect can be obtained.

However, the fan-type far-infrared heater manufactured according to the prior art is sold in 8 to 12 pyeong of the heat transfer area, but it is difficult to obtain a good heating effect with one heater because the heat generation is small and heat transfer is difficult to a long distance. In addition, since the coil is exposed to the surface of the radiator, if the coil is disconnected due to various reasons, the coil may come into contact with the reflector or the front wire mesh, causing a fire accident. If touched, there was a possibility of an electric shock. In addition, there is a problem of shortening the overall life of the far-infrared heater due to the oxidization phenomenon caused by the accumulation of dust in the coil which is always exposed to the outside and the elastic limit of the coil due to repeated thermal expansion and contraction.

In order to solve the shortcomings of the fan-type far-infrared heater according to the prior art, in the Republic of Korea Utility Model Application No. 1999-14700, as shown in FIG. 3, a mesh-type aspire 70 outside the radiator 51 is a heating element. In the method of mounting and the application No. 2000-0019762, as shown in Figure 4, instead of detecting the coil 52 in the radiator 51, instead of the glass tube 58 to put the coil 20 therein radiator 51 ) And the upper and lower flanges (59) to introduce a method for fixing.

However, the above methods may have the effect of extending the lifespan by protecting the heating element against external shock or preventing the oxidation of the coil, but the problem of durability of the coil due to the low heat generation and thermal expansion of the heater itself, which is a disadvantage of the prior art, cannot be solved. have.

The present invention is configured to solve the above problems, by converting the visible light emitted from the heating element to far infrared rays to increase the amount of heat, and to protect the shrinkage and expansion of the nichrome wire coil against heat to increase the durability The main object is to provide a far infrared heater.

1 is a perspective view of the overall appearance of a fan-type far-infrared heater conventionally used

2 is a cross-sectional view of the far infrared heating element of FIG.

Figure 3 is an exploded perspective view of a far-infrared heating element with a mesh-shaped aspiration outside the radiator of the conventional heater

Figure 4 is a perspective view of a far-infrared heating element having another configuration with a conventional fan-type far infrared heater

5 is an exploded perspective view of the main components of the fan-type far-infrared heater according to the present invention

6 is a cross-sectional view of the main components of the fan-type far infrared heater according to the present invention

<Explanation of symbols for the main parts of the drawings>

10; Expected 20; Landlord 30; reel

40; Reflector plate 50; Far infrared heating element 60; Protective grille

11; Function selection controller

51; Emitter 52; Nichrome wire coil 53; volt

54; Nut 55; Iron support 56; Quartz tube

57; Ceramic pedestal

571; Bolt insertion holes 572; Nichrome wire through

The present invention for solving the above object, the base 10 having a predetermined shape and the support (20) erected on the base 10, the rotating portion 30 provided on the top of the support (20), and Far infrared ray heating element 50 and a reflecting plate 40, which is provided on the front surface of the rotating part 30, fixed to the central portion of the reflecting plate 40, the nichrome wire coil 52 is pivoted to the outer peripheral surface of the radiator 51, and the reflecting plate A fan-type far-infrared heater composed of a detachable protective grill (60) on the front surface of (40), characterized in that a quartz tube (56) having a ceramic coating layer for emitting far-infrared rays is mounted outside the far-infrared heating element (50). It can be achieved by providing a fan type far infrared heater.

1 to 4 has already been described with respect to the conventional fan-type far-infrared heater through the accompanying drawings of FIGS. 1 to 4, hereinafter with respect to the fan-type far-infrared heater according to the present invention in the embodiment shown in FIGS. Although described according to the present invention, the present invention is not limited only to the embodiment shown in the drawings.

The far-infrared heating element 50, which is a main component of the far-infrared heater according to the present invention, has a cylindrical ceramic material whose opening area is gradually wider in a portion where the coil 52 rotates and a constant diameter thereof. To fix the quartz tube 56 and the radiator 51 on the rear side of the radiator 51 and the quartz tube 56 having a ceramic coating layer surrounded by a predetermined interval on the outside of the radiator 51. A ceramic base 57, an iron base 55 for fixing the far infrared ray heating element 50 to the center of the reflector plate 40, and a bolt 53 for coupling the radiator 51 to the ceramic base 57. ) And a nut 54.

First, the shape of the ceramic pedestal 57 will be described in more detail in the above-described configuration. A cylindrical body having a different diameter may be superimposed, and the center of the ceramic pedestal may be a radiator 51 using a bolt 53 and a nut 54. 1 bolt insertion hole (13) which serves to combine with) and three small diameter holes (14) through which nichrome wire coils can be formed at three points around the bolt insertion hole (13). The rear end of the pedestal has a groove that can be combined with the iron base.

Also, in the radiator 51, the rear side of the radiator which is in contact with the ceramic pedestal 57 has the same contact with the center bolt insertion hole 571 formed in the ceramic pedestal 57 and the three through holes 572 of the coil. One bolt insertion hole (571 ') and three through holes (572') are formed so that the front, the front of the radiator 51 facing the front so that the far-infrared rays are evenly distributed forward through the reflector plate (40) It is comprised so that opening area may become large from the part to which the rotation of the coil 52 is complete | finished.

On the other hand, the rest of the configuration of the base 10 and the support 20, the upper portion of the support 20, the rotating portion 30, the reflecting plate 40, the front grill 60, etc., so a separate description is omitted. Let's do it.

The present invention as described above covers the quartz tube 56 formed with a ceramic coating on the radiator 51, and the three-stranded nichrome wire from the through hole 572 'of the radiator 51 passes through the ceramics through holes 572 and 572'. The ceramic pedestal 57 is mounted so as to pass through, and then the bolt 53 and the nut 54 are fastened to the center bolt holes 571 and 571 ′ of the radiator 51 and the ceramic pedestal 57 so that the far-infrared heating element 50 may be formed. Will be assembled. Subsequently, the assembly process for the main components of the fan-type far infrared heater is completed by inserting the far-infrared heat generator 50 into the iron support 55 fixed to the center of the reflector plate 40.

In the far-infrared heater of the present invention configured as described above, when power is supplied, electricity is transmitted to the coil 52 through a terminal, and heat generated from the coil 52 is conducted to a radiator or radiated directly toward a quartz tube. Will happen. Since both heat transfers pass through the quartz tube on which the ceramic coating layer is formed, the visible light is converted into far infrared rays, thereby radiating and transferring heat containing a large amount of far infrared rays.

The fan-type far-infrared heater according to the present invention as described above is not limited to the embodiment shown in the drawings, and thus, various changes may be made without departing from the basic concept of the claims and the dependent claims of the present invention.

As described above, the fan-type far-infrared heater of the present invention is equipped with a quartz tube coated with a ceramic coating on the outside of the heating element, thereby effectively blocking visible light emitted from the ceramic composition and increasing the amount of far-infrared radiation. It is excellent and the quartz tube which is not deformable to heat surrounds the coil, so it can increase the durability of the stove by protecting the heat shrinkage and expansion, and prevent the electric shock and fire accident because the coil is not exposed to the outside and is embedded in the quartz tube. This is to bring about the effect of preventing oxidation caused by dust.

Claims (3)

A base 10 having a predetermined shape, a support 20 standing on the base 10, a rotating part 30 provided on the upper part of the support 20, and a reflecting plate 40 provided on the front surface of the rotating part 30. ), A far-infrared heating element 50 fixed to a central portion of the reflecting plate 40 and having a structure in which the nichrome wire coil 52 pivots to the outer circumferential surface of the radiator 51, and a protective grill detachable to the front surface of the reflecting plate 40 ( 60. A fan type far infrared heater comprising: a fan type far infrared heater characterized in that a quartz tube 56 having a ceramic coating layer emitting far infrared rays is formed outside the far infrared heater 50. The quartz tube according to claim 1, wherein the far-infrared heat generating element 50 includes a radiator 51 made of a cylindrical ceramic material in which the coil 52 pivots, and a ceramic coating layer surrounded by a predetermined interval on the outside of the radiator 51. (56), a pedestal (57) of ceramic material for fixing the quartz tube (56) and the radiator (51), and a bolt (53) for coupling the radiator (51) to the ceramic pedestal (57); Fan-type far-infrared heater, characterized in that consisting of a nut (54). The part of claim 1 or 2, wherein the portion of the radiator 51 that the coil rotates is cylindrical in constant diameter, and the front portion facing toward the front becomes wider from the end of the turning of the coil 52. Fan type far infrared heater, characterized in that