KR20120136702A - Infrared radiating electric zone heater device - Google Patents

Abstract

PURPOSE: An electric heating apparatus is provided to prevent thermal losses by blocking heat applied to a ceiling or wall, and to remove harmful gas and mold in a room by generating negative ions. CONSTITUTION: An electric heating apparatus comprises a frame(10), a heating element(20), a radiating plate(30), an insulating member(40), and a guide vane(50). The heating element is installed in the inner space of the frame. A heating wire is embedded in the heating element to emit heat. The radiating plate comprises a coated surface on the surface, and radiates infrared rays. The insulating member wraps the heating element, and blocks the heat discharged to a ceiling or wall. The guide vane is connected to the edge of the frame. The guide vane radiates the infrared rays to a restricted section.

Description

Infrared Radiating Electric Zone Heater device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heating electric heating device installed on an indoor ceiling or a wall of a house, apartment, building, hospital, agricultural and livestock facility, restaurant, or the like, and more specifically, a heat generation that emits heat for converting electrical energy into thermal energy. An element, a radiation plate that spreads the radiation surface of the thermal energy widely, a radiation radiation plate that converts the radiated thermal energy into infrared radiation to radiate infrared rays, and radiation beam guide vanes that radiate infrared rays into a limited area, thereby limiting infrared rays By copying to the area and irradiating to the human body, it promotes blood circulation and metabolism of the human body, activates cellular tissue and generates negative ions to remove various harmful bacteria, gases and molds in the room to keep the indoor environment warm and comfortable To prevent heat loss by blocking the heat to the ceiling or wall as much as possible. With this indoor temperature related to lower winter electric infrared heating zones copy devices that provide heating effect of high efficiency at low power consumption.

In general, heating devices used in low-temperature winters include wood-fired stoves, wood-fired boilers, gas-fired stoves, gas-fired boilers, oil-fired oil boilers, oil boilers, and electricity. Various types such as floor coverings, electric stoves and electric boilers.

Oil heaters and oil boilers in recent years are widely used, and heating costs are about 40-50% higher than gas stoves and gas boilers, which puts a heavy burden on consumers in the era of high oil prices. The city emits large amounts of greenhouse gases such as carbon dioxide and harmful gases, which are the main causes of global warming, causing serious social problems.

In recent years, due to high oil prices and economic recession, electric heating plates and stoves are the most preferred heating appliances for consumers. Thus, electric plates and stoves that use electricity do not generate greenhouse gases such as carbon dioxide and harmful gases. Many useful functions are applied to the human body.

Among conventional electric stoves, an electric stove using a nichrome wire has an advantage of low purchase price, but when the power switch is turned on, the ambient air temperature is increased by heat generated from the nichrome wire, and according to the air flowing by convection Since heat energy is transmitted, the heat transfer rate is slow, and the amount of heat transferred to the human body or an object is low, and thus the temperature is relatively low, and power consumption is high compared to the heat generation amount.

In addition, the electric stove using a near-infrared heater, called a halogen (halogen) has a disadvantage that the purchase price is expensive, but when the power switch is turned on, the heat generated from the near-infrared heater (bulb) is relatively high, heat transfer rate is not only fast, heat generation amount Compared with the low power consumption.

Such a conventional electric stove has a heating effect by heating indoor air at a low indoor temperature, but the amount of infrared radiation useful for the human body is significantly reduced, and various harmful bacteria, gases, and molds remaining in the room cannot be removed. There were problems that could not be kept warm and comfortable.

Therefore, as a prior art for heating and heating indoor air at low indoor temperature and emitting infrared rays useful to the human body, Korean Patent No. 10-0800119 (electric heating device for radiant heat radiation) and No. 10-1003751 A coating composition comprising an apatite coated photocatalyst and a radiant heat radiating device comprising the same has been proposed.

However, when the above-described prior art is applied to an indoor heating device, as the emitted infrared rays are diffusely reflected from the indoor space to the wall and the floor, the radiation dose to the human body is extremely insignificant, and there is no effect on the human body. However, as heat is transferred to the wall, the heat loss is relatively high, and in particular, the power consumption is higher than the heat generation.

The present invention is a problem that the infrared radiation is diffusely reflected to the wall and the floor in the interior space in the prior art, the amount of infrared radiation to the human body is extremely insignificant, heat is transferred to the indoor ceiling or wall, the heat loss is high, compared to the heat generation power consumption As a technology designed to improve these high problems, by radiating infrared rays into a limited area and irradiating the human body, it promotes blood circulation and metabolism of the human body and generates negative ions to remove various harmful bacteria, gases and molds in the room. In order to keep the indoor environment warm and comfortable, and to cut off the heat applied to the ceiling or wall as much as possible to provide high-efficiency heating effect with low power, a heating element that emits heat, a radiation radiator that radiates infrared rays, and infrared rays Radiation beam guide vanes that radiate into confined areas are constructed, and the heating element is insulated. An object is to provide an infrared zone radiant electric warmer.

The present invention is to realize the desired object as described above,

A frame embodied in a border form to have a space therein; A heating element installed in an inner space of the frame and having a built-in heating wire to emit heat; A radiation radiating plate installed on one side of the heating element, and having a coating layer formed on a surface of the substrate to radiate infrared rays; A heat insulating material surrounding the heat generating element installed in the inner space of the frame to block heat emitted to the ceiling or the wall; And a radiation beam guide vane coupled to the edge of the frame and radiating infrared rays radiated from the radiation radiator to a limited area.

In addition, as a preferred embodiment of the present invention, the coating layer of the radiation plate is 10 to 15% by weight of titanium dioxide (TiO ₂ ), 25 to 30% by weight of silicon dioxide (SiO ₂ ), 5-10% by weight of zirconium silicate (ZrSiO ₄ ) Silver nano powder (100nm), 1 to 5% by weight, precious stone powder 10-15% by weight, dimethyl silicone oil 3-6% by weight, silane 20-25% by weight, zeolite (zeolite) 5-10% by weight do.

According to an embodiment of the present invention, by irradiating the human body by radiating infrared radiation to a limited area, it promotes blood circulation and metabolism of the human body and generates negative ions to remove various harmful bacteria, gases and molds in the room, thereby reducing the indoor environment. It keeps warm and comfortable and prevents heat loss by blocking the heat applied to the ceiling or wall as much as possible to provide high efficiency heating effect with low power in winter when the room temperature is low.

1 is a bottom perspective view of an electric heating apparatus showing an embodiment of the present invention.
2 is a cross-sectional view showing an embodiment of the present invention.
Figure 3 is a sectional view of the main portion showing a heat generating element and a radiation radiating plate in an embodiment of the present invention.
Figure 4 is a sectional view of the main portion showing a heat generating element and a radiation radiating plate in an embodiment of the present invention.
Figure 5 is a sectional view of the main portion showing the installation state in an embodiment of the present invention.
Figure 6 is a cross-sectional view showing the main portion of the radiation guide vane in the embodiment of the present invention.
7 is a state diagram used in accordance with an embodiment of the present invention.

The main point in the embodiment of the present invention is to irradiate the human body by radiating infrared radiation to a limited area to promote blood circulation and metabolism of the human body while generating negative ions to remove various harmful bacteria, gases and molds in the indoor environment To keep warm and comfortable while blocking the heat applied to the ceiling or wall as much as possible to provide a high efficiency heating effect with low power.

Looking at the main configuration of the infrared zone radiant electric heating apparatus according to an embodiment of the present invention, the frame 10 is implemented in the form of a border to be provided with a space therein; A heating element 20 installed in an inner space of the frame 10 and having a heating line 21 installed therein to dissipate heat; A radiation radiating plate 30 installed on one surface of the heating element 20 and having a coating layer 32 formed on a surface of the substrate 31 to radiate infrared rays; A heat insulating material 40 surrounding the heat generating element 20 installed in the inner space of the frame 10 to block heat emitted to the ceiling or the wall; It is coupled to the edge of the frame 10, the radiation beam guide vane 50 for radiating the infrared radiation radiated from the radiation radiating plate 30 to a limited area; comprises a.

In the main configuration of the frame 10 as shown in Figures 1 to 2, in the form of various shapes such as square or round according to the needs of the consumer, it is made of a lightweight (aluminum) alloy material excellent in durability Preferably, the hollow hole 11 is formed as an empty space on the outside to reduce the load while being implemented in the form of a border so that the empty space is provided inside.

The frame 10 constitutes the overall frame of the present invention infrared zone radiant electric heating apparatus, is attached to the ceiling or the wall in the interior space, or installed in the form of a buried in the ceiling or wall, the bin provided inside The heat generating element 20, the radiation radiating plate 30, and the heat insulating material 40 are provided in the space.

In addition, in the above main configuration, the heat generating element 20 is a function of generating heat at a high temperature by receiving power, and as shown in FIGS. 2 to 4, is installed in the inner space of the frame 10, and the heat reflecting plate 22. A plurality of heating wires 21 are installed at regular intervals so as to be positioned below the heating wires 21, where the heating wires 21 are preferably inexpensive nichrome wires.

In the above, the heating element 20 is spaced apart from the frame 10 as much as possible, and is installed to be in close contact with the radiation radiating plate 30, and the heat reflection plate 22 positioned above the heating line 21 is emitted from the heating line 21. The heat is reflected to the bottom of the frame 10 to prevent the hot heat emitted from the heating line 21 from being emitted to the top of the frame 10.

In addition, in the above-described main configuration, the radiation radiating plate 30 is a function of radiating infrared rays by receiving heat emitted from the heating element 20, in the empty space inside the frame 10 as shown in FIG. A substrate 31 having a coating layer 32 is installed to be attached to a bottom surface of one side of the heat generating element 20 and positioned below the heat generating line 21.

The substrate 31 is preferably made of aluminum (aluminum) material having excellent thermal conductivity, the coating layer 32 is applied to the bottom portion of the substrate 31 is a heating element (300-960W) when supplying power It is preferable to apply a material capable of maintaining a temperature of 85 to 100 ° C. by 20) or a material capable of maintaining a temperature of 360 to 380 ° C. by the heating element 20 when supplying power of 1,300 to 3,900W.

In the embodiment of the present invention, the coating layer 32 includes titanium dioxide (TiO ₂ ), silicon dioxide (SiO ₂ ), zirconium silicate (ZrSiO ₄ ), silver nanopowder (100 nm), precious stone powder, dimethyl silicon oil, silane (alkoxy, Epoxy) and zeolite, wherein titanium dioxide (TiO ₂ ), zirconium silicate (ZrSiO ₄ ), gemstone powder, and silane (alkoxy, epoxy) have excellent emission of infrared rays and anions, and silver nano powder. Zeolites are excellent in antibacterial and deodorizing action.

As an example of the coating layer 32, titanium dioxide (TiO ₂ ) 10-15% by weight, silicon dioxide (SiO ₂ ) 25-30% by weight, zirconium silicate (ZrSiO ₄ ) 5-10% by weight, silver nano powder (100 nm) 1 to 5% by weight, 10 to 15% by weight of precious stone, 3 to 6% by weight of dimethyl silicone oil, 20 to 25% by weight of silane (alkoxy, epoxy), zeolite (zeolite) is preferably applied to 5 to 10% by weight Do.

In addition, in the above main configuration, the heat insulating material 40 is a function of blocking heat emitted from the heat generating element 20, as shown in Figure 5 and the upper portion of the heat generating element 20 installed in the inner empty space of the frame 10 and It is installed to surround both sides, and in this case, the heat emitted from the heating element 20 is blocked from being transferred to the upper and both sides of the frame 10.

Insulating material 40 is to block the heat emitted from the heat generating element 20 to block the heat transmitted to the upper and both sides of the frame 10 as a result to block the heat emitted to the ceiling or wall to the maximum.

In addition, insulated pads 41 are installed between the edge of the radiation radiating plate 30 and the lower inner side of the frame 10 to block radiant heat emitted from the radiation radiating plate 30 from being transferred to the frame 10. In this case, the heating effect is increased by blocking the heat transmitted to the frame 10 as much as possible.

In addition, in the above main configuration, the radiation beam guide vane 50 is a function of radiating the infrared radiation radiated from the radiation radiating plate 30 to a limited area, as shown in Figs. Part 51 is fitted to the edge of the frame 10 is coupled to the installation, and the lower part is implemented in the form of fallopian tube gradually widening, radiating the infrared radiation radiated from the radiation radiating plate 30 to a limited area to irradiate the human body.

As the radiation beam guide vane 50 radiates infrared rays into a limited area, the infrared rays are not diffused in all directions from the indoor space, and the radiation dose to the human body is increased, thereby promoting blood circulation and metabolism of the human body, thereby improving health. useful.

In addition, the radiation beam guide vane 50 may be provided with a built-in thermal insulation pad (53) inside the coupling portion 51 is fitted to the edge of the frame 10 to block the heat transmitted to the frame 10, such In this case, the radiating beam guide vane 50 blocks the heat transmitted to the frame 10 to increase the heating effect.

In addition, the radiation beam guide vane 50 is a coating layer 52 is implemented on the inner surface to receive the heat emitted from the heating element 20 to increase the radiant heat of infrared rays, where the coating layer 52 is a radiation radiating plate 30 It can be implemented in the same manner as the coating layer 32 implemented in.

Infrared zone radiant electric heating apparatus according to an embodiment of the present invention having such a configuration is selectively installed on the ceiling or wall of the interior space, as shown in Figure 7, the heating element 20 and the radiation plate 30 As the radiation beam guide vane 50 is radiated to the limited area by radiating the infrared radiation, the radiation dose to the human body is increased.

Hereinafter will be described in detail through an embodiment of the present invention.

In the radiating radiating plate 30, 10 wt% of titanium dioxide (TiO ₂ ), 25 wt% of silicon dioxide (SiO ₂ ), 10 wt% of zirconium silicate (ZrSiO ₄ ), and silver nano powder on an aluminum substrate 31 having a thickness of 0.5 mm 100 nm), a mixture of 5% by weight, 10% by weight of precious stone powder, 5% by weight of dimethyl silicone oil, 25% by weight of silane, and 10% by weight of zeolite were applied to form a coating layer 32.

In addition, the coating layer 52 was formed by applying the same mixture as the coating layer 32 of the radiation radiating plate 30 on the inner surface of the radiation guide vane 50.

In the infrared zone radiant electric heating device manufactured as described above, when 300 to 960W of power was supplied to the heating element 20, the surface temperature of the coating layer 32 was maintained in the range of 85 to 100 ° C after 5 minutes, and the frame The upper temperature of (10) was maintained in the range of 20-25 degreeC.

In the radiation radiating plate 30, 15% by weight of titanium dioxide (TiO ₂ ), 30% by weight of silicon dioxide (SiO ₂ ), 5% by weight of zirconium silicate (ZrSiO ₄ ), and silver nano powder on an aluminum substrate 31 having a thickness of 0.5 mm 100 nm) 5% by weight, 15% by weight of precious stone powder, 5% by weight of dimethyl silicone oil, 20% by weight of silane, 5% by weight of zeolite (zeolite) was applied to form a coating layer (32).

In addition, the coating layer 52 was formed by applying the same mixture as the coating layer 32 of the radiation radiating plate 30 on the inner surface of the radiation guide vane 50.

In the infrared zone radiant electric heating device manufactured as described above, when 1,300 to 3,900W of power was supplied to the heating element 20, the surface temperature of the coating layer 32 was maintained in the range of 360 to 380 ° C after 5 minutes. The upper temperature of the frame 10 was maintained in the range of 40 ~ 45 ℃.

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, It is possible to carry out various changes in the present invention.

10: frame 11: longevity
20: heating element 21: heating line
22: heat radiation plate 30: radiation radiation plate
31: substrate 32: coating layer
40: insulation 41: insulation pad
50: radiation beam guide vane 51: coupling portion
52: coating layer 53: insulation pad

Claims (6)

Frame 10 is implemented in the form of a border to be provided with a space therein;
A heating element 20 installed in an inner space of the frame 10 and having a heating line 21 installed therein to dissipate heat;
A radiation radiating plate 30 installed on one surface of the heating element 20 and having a coating layer 32 formed on a surface of the substrate 31 to radiate infrared rays;
A heat insulating material 40 surrounding the heat generating element 20 installed in the inner space of the frame 10 to block heat emitted to the ceiling or the wall;
Infrared zone radiant electric heating, characterized in that it comprises a; is installed coupled to the edge of the frame 10, the radiation beam guide vanes 50 for radiating the infrared radiation radiated from the radiation radiating plate 30 to a limited area Device.
The method of claim 1, further comprising:
The coating layer 32,
10-15% by weight of titanium dioxide (TiO ₂ ), 25-30% by weight of silicon dioxide (SiO ₂ ), 5-10% by weight of zirconium silicate (ZrSiO ₄ ), 1-5% by weight of silver nanopowder (100nm), precious stone powder An infrared zone radiant electric heater comprising 10 to 15% by weight, 3 to 6% by weight of dimethyl silicone oil, 20 to 25% by weight of silane, and 5 to 10% by weight of zeolite.
The method of claim 1, further comprising:
The radiation guide vane 50,
The coupling portion 51 formed in the upper portion is fitted to the edge of the frame 10 and installed to be coupled, the lower portion is gradually implemented in the form of a fallopian tube, radiating infrared radiation radiated from the radiation radiating plate 30 to a limited area Infrared radiation radiant electric heater, characterized in that.
The method of claim 1 or 3;
The radiation guide vane 50,
The coating layer 52 is implemented on the inner surface, and the coating layer 52 is implemented in the same manner as the coating layer 32 implemented on the radiation radiating plate 30, the infrared region radiant electric heating apparatus.
The method of claim 1 or 3;
The radiation guide vane 50,
Infrared zone radiant electric heating apparatus, characterized in that the thermal insulation pad 53 is installed inside the coupling portion 51 is fitted to the edge of the frame 10 is coupled.
The method of claim 1, further comprising:
Infrared radiation radiant electric heater, characterized in that the thermal insulation pad 41 is installed between the edge of the radiation radiating plate 30 and the lower inner side of the frame 10.

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