KR200293782Y1 - Far infrared rays producter using reflective plate coated far infrared rays radiation matter - Google Patents

Abstract

The present invention relates to a far-infrared generator using a reflector plate coated with a far-infrared radiation material that prevents waste of energy by coating a synthetic ceramic coating that emits far-infrared rays on a reflecting plate so that the emitted far-infrared ray has a directivity.

A far infrared ray generating apparatus using a reflector plate coated with a far-infrared radiation material includes a housing detachably assembled on one side thereof to open and close the inside by the cover, and an opening in which the far-infrared radiation is opened in front;

Far-infrared radiation means installed in the housing and coated with a radiation member for emitting far infrared rays in front of the housing to emit far infrared rays through the housing outlet;

A control unit installed at the housing such that a knob and a remote control signal receiving sensor are exposed to control each function of the far-infrared radiation means by a user's operation;

And a blower installed inside the housing to smoothly discharge the far infrared rays and heat radiated from the far infrared radiation means through the outlet.

Description

Far infrared rays generator using reflector plate coated with far infrared radiation material {Far infrared rays producter using reflective plate coated far infrared rays radiation matter}

The present invention coats the synthetic ceramic paint that emits far infrared rays on the reflecting plate so that far infrared rays are emitted only in the direction where the ceramics are exposed so that the far infrared rays can be cut off to unnecessary places to reduce the waste of energy. The present invention relates to a far infrared ray generating apparatus using a reflecting plate coated with a radiation material.

Infrared is a kind of electromagnetic waves with a longer wavelength and a greater thermal effect than the red region of visible light. Infrared rays having long wavelengths within this infrared wavelength range are called Far Infrared Rays.

This far infrared ray is a kind of electromagnetic waves with a longer wavelength and heat action than infrared rays. When it reaches an object, it absorbs and penetrates strongly, and when it is exposed to the human body, it penetrates deep into the skin and creates heat. It is known to act to remove the causative bacteria and to expand the capillaries to help blood circulation and the generation of tissue.

Therefore, due to various effects of the far infrared rays on the human body, many kinds of products for using the far infrared rays in daily life have been released to the market.

However, in the conventional far-infrared generator, a radiation material emitting far infrared rays has a certain shape, and since the radiation material is disposed in a state spaced in front of the reflector, the omnidirectional shape, that is, the radiation material radiates far infrared rays in a 360 ° direction. As a result, heat and far-infrared rays are radiated where they are not necessary depending on the place, resulting in waste of energy, which causes a problem of using a far-infrared generator having more functions than necessary.

Therefore, the present invention is to solve the above problems, and its purpose is to spray the synthetic ceramic paint that emits far infrared rays onto the reflecting plate so that the far infrared rays are emitted only in the direction in which the ceramics are exposed so that the directionality is unnecessary. It is to provide a far-infrared generator using a reflector plate coated with a far-infrared radiation material that can prevent the radiation of far-infrared radiation in the place to prevent waste of energy.

The far-infrared generating apparatus using the reflector plate coated with the far-infrared radiation material includes a housing detachably assembled on one side thereof to open and close the inside by the cover, and an outlet through which the far-infrared radiation is opened in front; Far-infrared radiation means installed in the housing and coated with a radiation member for emitting far infrared rays in front of the housing to emit far infrared rays through the housing outlet; A control unit installed at the housing such that a knob and a remote control signal receiving sensor are exposed to control each function of the far-infrared radiation means by a user's operation; And a blower installed inside the housing to smoothly discharge the far infrared rays and heat radiated from the far infrared radiation means through the outlet.

Here, the spinning means is 16.9 to 20.9% by weight of iron oxide (Fe ₂ O ₃ ), manganese dioxide (MnO ₂ ) 2 to 4% by weight, copper oxide (CuO) which is a radiation member radiating far infrared rays to 60 to 80% by weight epoxy resin ) 25 to 30% by weight of a synthetic ceramic powder containing 2 to 4% by weight and 4.1 to 6.1% by weight of cobalt oxide (CoO) is mixed and coated on the front surface of the body, and the coating surface is disposed toward the housing outlet. ; A heating member disposed behind the reflective member to heat the reflective member; And a heat insulating member disposed behind the heating member to block heat generated from the heating member from being transferred backward.

1 is a front view of a far infrared ray generating apparatus according to the present invention

Figure 2 is a side cross-sectional view of the far infrared ray generating apparatus according to the present invention

Figure 3 is a perspective view showing a first embodiment of the reflecting means of the far infrared ray generating apparatus according to the present invention

Figure 4 is a perspective view showing a second embodiment of the reflecting means of the far infrared ray generating apparatus according to the present invention

Figure 5 is a side cross-sectional view showing that the reflective member of the present invention is configured in a streamlined shape

6 is a front view showing a heater wire as a heating member of a far infrared ray generator according to the present invention.

7 is a side cross-sectional view of the reflecting means of FIG.

Figure 8 relates to a reflecting means according to the present invention, the side cross-sectional view showing a state in which the reflector is further installed behind the heat insulating material

Figure 9 is a side cross-sectional view showing a state in which each element of the reflecting means arranged in a spaced apart state

Explanation of symbols on the main parts of the drawings

1: Reflector 2: Reflector

3: radiation member 10: far infrared ray generator

11 housing 12 far infrared radiation means

13 control unit 14 blower

21: heating member 22: heat insulating member

23: sub reflection member

Hereinafter, on the basis of the accompanying drawings will be described in detail the configuration of the far-infrared generator using the reflector plate coated with the far-infrared radiation material according to the present invention.

In the far-infrared generator using the reflector plate coated with the far-infrared radiation material according to the present invention, the far-infrared generator 10 using the reflector plate coated with the far-infrared radiation material has a housing 11 and the inside of the housing 11 as shown in the drawings. The far-infrared radiation means 12 that is received and radiates the far infrared rays, the control unit 13 for controlling the far-infrared waterproof end, and the blower 14 to smoothly discharge the far infrared rays and heat radiated from the far-infrared radiation means 12 It is configured to include.

The housing 11 has a lid 15 detachably assembled to the rear of the body in which the inlet is formed to open and close the storage space 16 therein.

An outlet 17 is formed in the body of the housing 11 so that the far infrared rays radiated from the far infrared radiating means 12 can be discharged to the outside, and the outlet 17 has a grill to adjust the discharge direction of the radiated far infrared rays. 18 is installed. In addition, upper and lower ends of the outlet 17 are formed with guide panels 19a and 19b for guiding discharged far-infrared rays to the outlet. The guide panels 19a and 19b are formed by the blower 14. Arranged at an appropriate length and angle so that the conveyed air can be guided to the outlet 17.

In FIG. 2, since the blower 14 is installed at an upper portion thereof, the upper guide panel 19a protrudes downward so that the air transported by the blower 14 may be rubbed against the far-infrared radiation means 12. The guide panel 19b installed at the lower portion of the 17 protrudes upward in proximity to the end portion of the far infrared radiation means 12 so as to prevent the air reflected by the far infrared radiation means 12 from being transported downward. The shape of the guide panels 19a and 19b may optionally vary depending on the structure and arrangement of the far-infrared radiation means 12 and the structure of the air transport path accordingly.

The cover 15 of the housing 11 has a passage 20 formed at a portion adjacent to the blower 14 so that air can flow into the housing 11, and the cover 15 has the far-infrared radiation. It is preferable to be made of a metal material having excellent reflection performance so as to reflect far-infrared rays emitted from the means 12 to the outlet 17, and preferably of zinc or aluminum.

The far infrared radiation means 12 is a reflection member 2 coated with a radiation member 3 having a far infrared radiation function, and a heating member 21 disposed behind the reflection member 2 to heat the reflection member 2. And a heat insulation member 22 disposed at the rear of the heating member 21 to block heat generated from the heating member 21 from being transmitted backward.

The reflective member 2 is coated with a radiation member 3 for emitting far infrared rays on one side thereof and is integrally formed with the reflective member 2.

Since the radiating member 3 emitting far infrared rays is coated on the reflecting member 2 as described above, the far infrared rays radiated from the radiating member 3 are radiated to the exposed part as reflected by the reflecting member 3, thereby providing directivity. Will have

In other words, the far-infrared rays generated from the coating surface are reflected by the reflecting member 2 so that they do not pass through the reflecting plate and are radiated toward the front of the coating surface to have directivity, thereby allowing the far-infrared rays to be radiated in a desired specific direction.

The reflective member 2 may be configured in a plate shape, but may be configured in various forms according to a user's purpose of use. For example, as shown in FIGS. 2 to 3, the reflective member 2 may be configured in an arc shape so that the far infrared rays emitted from the radiation member 3 coated on one side thereof may be concentrated at a certain point.

In this case, the size of the diameter of the arc can be selectively set. If the diameter of the arc is increased, the far-infrared rays radiated from the radiating member 3 will be concentrated in a farther place than when the diameter of the arc is reduced.

In addition, the reflective member 2 of the present invention may be configured in a streamline shape in which the acid 4 and the valley 5 are continuous on the side on which the radiating member 3 is coated as shown in FIG. 5.

When the side of the reflective member 2 is formed in a streamline shape as described above, the radiation member 3 coated thereon also has a streamline shape. Far infrared rays emitted from the protruding mountains 4 are diffused and The reflected far infrared rays are concentrated.

Therefore, the radiation member 3 having many valleys and acids 4 emits far infrared rays more widely than the radiation member 3 having a planar shape while irradiating far infrared rays irregularly.

As the reflective member 2 configured as described above, a metal material having excellent far-infrared ray shielding effect is preferable, and among the metal materials, a zinc plate or an aluminum plate having excellent reflection effect is preferably used.

The radiation member 3 coated on the reflective member 2 may be made of a material having excellent coating power and excellent heat resistance while emitting a lot of far infrared rays.

This far-infrared radiation member 3 is mixed with 60 to 80 wt% of epoxy resin material and 25 to 35 wt% of synthetic ceramic powder, and coated on the reflective member 2 by spraying in a liquid state.

The epoxy resin is required to have heat resistance that can withstand 150 to 200 DEG C as an unsaturated resin series heat-resistant shield.

Component of the synthetic ceramic powder is iron oxide (Fe ₂ O ₃ ) 16.9-20.9% by weight, manganese dioxide (MnO ₂ ) 2-4% by weight, copper oxide (CuO) 2-4% by weight, cobalt oxide (CoO) 4.1- Including 6.1% by weight adds up to 25-35% by weight.

The reflective member 2 coated with the far-infrared radiation material configured as described above is exposed to the coated surface because the far-infrared radiation emitted from the synthetic ceramics is reflected by the reflective member 2 because the radiation material is coated on one side thereof. However, most of the far infrared rays are radiated to have directivity.

The heating member 21 is to be installed in the rear of the reflecting member 2 to heat the far-infrared radiation to enable the far-infrared generator 10 to serve as a heat treatment or sauna function.

The heating member 21 may use a plate-like heating element as shown in the figure, and may also use the heater wire 23 as shown in FIG. These planar heating elements and heater wires 23 are well known in the art.

The heat insulating member 22 is installed at the rear of the heating member 21 to prevent the heat generated from the heating member 21 from being transferred to the rear so that most of the heated air and far-infrared rays are discharged to the outlet of the housing 11. To guide you through, is the technology of air.

On the other hand, the far-infrared radiation means 12 of the present invention may further install a sub-reflective member 24 behind the heat insulating member 22 to reflect the far infrared rays passing through the heat insulating member 22 to increase the reflection efficiency. have. As the material of the sub-reflective member 24, it is preferable to use a zinc plate or an aluminum plate having excellent reflection efficiency.

The control unit 13 is to control the far infrared radiation means 12 by the user's operation as shown in Figure 2, the printed circuit board is provided on one side of the heat insulating member 25 to block the heat of the radiation means 12 A plurality of knobs installed in front of the housing 11 are organically connected to the printed circuit board 26 so that the user controls the far infrared radiation means 12 by operating the knob 27. In addition, one side of the knob 27 is provided with a detection sensor 28 for detecting a remote control signal is configured to control the far-infrared generator 10 by a remote control.

Such a control unit 13 can adjust the driving time, temperature, air volume, etc. of the far infrared radiation means 12.

The blower 14 is for circulating the heated far infrared rays and the heated air by forcibly transporting the outside air into the housing 11 to be discharged to the outlet 17, the air inside the housing 11 It is installed on a flow path.

Since the far-infrared generator of the present invention configured as described above is coated with a radiation member for emitting far-infrared radiation on one side of the reflective member, the emitted far-infrared radiation has a directivity and is radiated in the exposed direction.

Therefore, the coating surface of the reflecting member can be disposed in a desired direction to radiate far infrared rays where necessary, thereby preventing unnecessary far infrared rays from being emitted, thereby reducing energy waste.

In addition, since the far infrared rays are emitted in a directional manner, there is an advantage that can be installed around the far infrared rays to protect the products that can be damaged by the far infrared rays.

Claims (5)

A housing detachably assembled on one side thereof, the housing being opened and closed by the cover, and having an outlet to which far infrared rays are radiated in front; Far-infrared radiation means installed in the housing and coated with a radiation member for emitting far infrared rays in front of the housing to emit far infrared rays through the housing outlet; A control unit installed at the housing such that a knob and a remote control signal receiving sensor are exposed to control each function of the far-infrared radiation means by a user's operation; And a blower installed inside the housing to allow the far infrared rays and heat radiated from the far infrared radiation means to be discharged smoothly through the outlet. The method of claim 1, wherein the radiating means 60 to 80 wt% of epoxy resin, 16.9 to 20.9 wt% of iron oxide (Fe ₂ O ₃ ), which is a radiation member that emits far infrared rays, ₂ to 4 wt% of manganese dioxide (MnO ₂ ), and 2 to 4 wt% of copper oxide (CuO) A reflecting member having 25 to 35% by weight of a synthetic ceramic powder including 4.1 to 6.1% by weight of cobalt oxide mixed and coated on the front surface of the body, wherein the coating surface is disposed toward the housing outlet; A heating member disposed behind the reflective member to heat the reflective member; And a heat insulation member disposed behind the heating member to block heat generated from the heating member from being transmitted to the rear of the heating member. The far-infrared generator using the reflective plate coated with the far-infrared radiation material. The apparatus of claim 1, wherein the cover of the housing is made of an aluminum material having a good far infrared reflectance. The apparatus of claim 1, wherein the reflecting member has a plate-shaped body bent in an arc shape. The apparatus of claim 2, wherein the radiation means further includes a sub-reflective member reflecting far infrared rays behind the heat insulating member.