KR200406514Y1 - Electric heater - Google Patents

Abstract

The present invention relates to a radiator, and more particularly, to a radiator capable of reducing the power consumption while heating faster and more efficiently by using near carbon and carbon ribbon heaters as heat sources.

To this end, the present invention has a body having a grill, a hot air balloon, and an air inlet; Nanocarbon heater installed in the rear of the grille of the inside of the body; A reflection plate installed at the rear of the nanocarbon heater; A blower installed at the rear of the inlet port of the inside of the body; A carbon ribbon heater having a function of sterilizing bacteria contained in the air and removing foreign substances while heating the air blown through the blower; It provides a radiator comprising a hot air guide duct for guiding the hot air passing through the carbon ribbon heater toward the tuyeres.

Therefore, the present invention improves the heating efficiency while reducing power consumption, improving the indoor environment by releasing near-infrared rays and negative ions and disinfecting harmful germs and dust contained in the indoor air, while improving the user's health. have.

Radiator, Nano Carbon Heater, Carbon Ribbon Heater, Blower, Grill.

Description

Radiator {Electric heater}

1 is a perspective view showing a radiator of the present invention,

2 is a cross-sectional view showing a radiator structure of the present invention;

Figure 3 is a partial perspective view showing a carbon ribbon heater of the radiator of the present invention,

Figure 4 is a cross-sectional view of the installation state showing another use state of the radiator according to the present invention.

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

100: radiator 200: body

210: grill 220: hot air balloon

230: intake port 300: nano carbon heater

400: reflector 500: blower

600: carbon ribbon heater 610: carbon ribbon

620: pin 700: hot air guide duct

The present invention relates to a radiator, and more particularly, to a radiator capable of reducing power consumption while providing faster and more efficient heating by near-infrared rays and hot air using nanocarbon heaters and carbon ribbon heaters as heat sources.

In general, heating appliances used for indoor heating are largely classified into petroleum heaters using petroleum, gas heaters using gas, and electric heaters using electricity.

Among them, in the case of oil heater or gas heater, there is an advantage that the price of the product is somewhat lower than that of the electric heater, but the composition is relatively complicated, making the production cumbersome and polluting indoor air due to incomplete combustion. In addition, there is a high risk of fire in the fuel injection process, cumbersome fuel injection work, and in particular, the recent increase in oil prices has greatly increased the expenditure of oil and gas costs, causing a serious problem that increases the economic burden on the oil heater or gas heater users. It became.

On the other hand, the electric heater is a device that uses electricity as a heat energy source, the composition of the product is simple and can be manufactured easily, the handling is extremely simple, the fire risk is relatively low, and the fuel needs to be replenished at any time. Since there is no easy maintenance, the use of indoor heating means has recently increased.

Most of these conventional electric heaters are formed by arranging one or more transparent heat-resistant quartz tubes or opaque heat-resistant ceramic tubes incorporating a nichrome coil-type electric heating element in front of the case, or wired electric wire of tungsten. It is mainly used to install a ceramic plate with a heating element installed in the front of the inside of the case.

However, among conventional heat transfer heaters, products using quartz tubes or ceramic tubes with a built-in nichrome coil electric heating element involve excessive electricity bills due to high power consumption, and also heat radiation due to the small heating surface area of the quartz or ceramic tubes. There was a problem that the efficiency is reduced. In addition, the use of a ceramic plate in which the tungsten linear heating element is embedded has a problem that it takes a long time until the ceramic plate is heated, so that rapid heating is difficult.

In addition, the conventional electric heater is a heating method that directly conducts heat conduction by heating the air through the heat generated from the quartz or ceramic tube with an electric heating element of nichrome coil. Therefore, there is an inefficient problem of limited heating in a short distance. As a result, almost no circulation of air is made for efficient heating, resulting in a significant drop in heating efficiency.

Furthermore, since the conventional electric heater uses an electric heating element of nichrome coil, it is inevitable to generate a lot of electromagnetic waves, and this causes a problem of gradually failing to meet the recent consumer demand for health.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to provide a radiator that can increase the heating efficiency while reducing power consumption.

Another object of the present invention is to provide a near-infrared radiation during heating and to remove the harmful bacteria and dust contained in the indoor air to provide a radiator that can improve not only the heating but also the indoor environment and the user's health. .

Radiator of the present invention for achieving the above object and the body having a grill and a hot air balloon and the intake vent on the front; Nanocarbon heater installed in the rear of the grille of the inside of the body; A reflection plate installed at the rear of the nanocarbon heater; A blower installed at the rear of the inlet port of the inside of the body; A carbon ribbon heater having a function of sterilizing bacteria contained in the air and removing foreign substances while heating the air blown through the blower; It characterized in that it comprises a hot air guide duct for guiding the hot air passing through the carbon ribbon heater toward the tuyere.

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

1 is a perspective view showing a radiator of the present invention, Figure 2 is a cross-sectional view showing the structure of the present radiator, the radiator 100 of the present invention as shown is large body 200, nano carbon heater 300, reflector 400, a blower 500, a carbon ribbon heater 600, and a hot air guide duct 700.

First, the body 200 serves as a case, and installs a grill 210 to adjust the direction of heat transfer on the front surface, and forms a hot air balloon 220 through which hot air can be blown on the grill 210. In the lower portion of the grill 210 is formed an inlet port 230 for sucking the air in the room.

The nano carbon heater 300 is a heating element in which nano carbon is installed in a tube such as a quartz tube or a ceramic tube, and is installed in the rear of the grill 210 in the inside of the body 200. The nano carbon heater 300 is supplied with power by a conventional power supply and a control device installed inside the body 200 to emit near infrared rays.

Reflector 400 serves to reflect the heat generated from the nano carbon heater 300 to the front of the body 200, a plurality of nano on the rear side of the nano carbon heater 300 of the inside of the body 200 The carbon heater 300 is installed to cover the whole.

The blower 500 sucks cold air in the lower part of the room and blows it toward the carbon ribbon heater 600. The blower 500 is installed to be connected to the inlet port 230 at the rear side of the inlet port 230 formed at the lower front of the body 200. .

The carbon ribbon heater 600 sterilizes bacteria contained in the air while burning cold air blown through the blower 500 with hot air, and burns and removes foreign substances and odors. The carbon ribbon heater 600 is installed so as to be located above the exhaust folder of the blower 500, and its structure is a plurality of fins 620 of the ribbon-shaped ribbon carbon ribbon 610 as shown in FIG. It is preferable to make a multi-layer between) but arranged in a zigzag form so that the ventilation and heat transfer is good.

The hot air guide duct 700 is installed inside the body 200 to guide the hot air generated through the carbon ribbon heater 600 to the air outlet side. The hot air guide duct 700 is heated by the body 200 due to the hot air. It is preferable to use a non-heat-resistant material to prevent it from being, but it is also possible to use a heat-resistant insulation is installed on the back.

When described in detail with reference to the accompanying drawings the operation and effects of the present invention configured as described above.

As shown in FIG. 1, the radiator 100 of the present invention emits near infrared rays of about 600 ° C. through the nanocarbon heater 300 when the power is applied, and the near infrared rays are front of the radiator 100 through the reflector 400. It is reflected to the side to heat the room, in particular the near-infrared ray generated through the nano carbon heater 300 has the advantage of transmitting the heat even a relatively long distance.

In addition, the radiator 100 of the present invention operates the blower 500 and the carbon ribbon heater 600 installed inside the radiator 100 in addition to the heating through the nano carbon heater 300, so that hot air flows through the hot air balloon 220. Will be provided. In particular, the hot air blown through the hot air outlet 220 heats cold air in the lower part of the room sucked through the inlet 230, and has a great advantage of evenly heating the indoor air. It will play a role to make things faster, more effective and faster.

In addition, since the carbon ribbon heater 600 has a plurality of carbon ribbons 610 arranged in a zigzag form while being installed in multiple layers between the fins 620, as shown in FIG. 3, the carbon ribbon heater 600 increases the contact area with the blown air as much as possible. On the other hand, since the air resistance is reduced, a smooth blowing is achieved. In addition, the carbon ribbon heater 600 removes or burns various bacteria, odors and foreign substances contained in the air to be blown by heat of approximately 250 ° C., and also cleans indoor air, and in the process, the carbon ribbon 610. Due to its characteristics, far infrared rays and negative ions are emitted, thereby making heating more comfortable and beneficial to the human body.

In addition, since the heat sink 100 of the present invention uses the nanocarbon heater 300 and the carbon ribbon heater 600 as the heat source, the power consumption when compared to the electrothermal heater using the conventional nichrome coil-type electric heating element because of its characteristics It is greatly reduced by more than 12 ~ 15%, which can greatly reduce the electricity bill.

On the other hand, Figure 4 shows another use state of the radiator 100 according to the present invention, it is also possible to perform the role of the fireplace because it (Builtin) built in the place where the fireplace is installed in the interior walls of the living room and the like. In addition, in addition to changing the size of the radiator 100 may be implemented to use for the purpose of the heater or personal heater used in the office.

Such an embodiment of the present invention is merely to describe a preferred example, the scope of application of the present invention is not limited to such, and can be changed appropriately within the scope of the same thought.

As described above, the radiator of the present invention can provide near-infrared rays and hot air through the nanocarbon heater and the carbon ribbon heater, thereby making the heating of the room faster and more efficient.

Furthermore, since the radiator of the present invention provides a heat source by nano carbon heater and carbon ribbon heater, it generates very little electromagnetic waves during heating. There is an effect to plan more comfortable and beneficial heating.

In addition, the radiator of the present invention can not only greatly reduce the electric charges due to the reduction of power consumption due to heating, but also can be expected to be widely used in the use of fireplaces, warmers, small electric heaters installed in the living room.

Claims (3)

A body 200 having a grill 210, a hot air balloon 220, and an air inlet 230 on the front surface thereof; Nanocarbon heater 300 installed in the rear of the grill 210 of the inside of the body 200; A reflection plate 400 installed at the rear of the nanocarbon heater 300; A blower 500 installed at the rear of the inlet port 230 of the inside of the body 200; A carbon ribbon heater 600 having a function of sterilizing bacteria contained in the air and removing foreign substances while heating the air blown through the blower 500; Hot air guide duct 700 for guiding hot air passing through the carbon ribbon heater 600 to the tuyere side Radiator comprising a. The radiator of claim 1, wherein the hot air guide duct (700) is a non-heating body so as to prevent the body (200) from being heated. According to claim 1, wherein the carbon ribbon heater 600 comprises a ribbon-shaped carbon fiber 610 made of a carbon fiber material between the plurality of fins 620 in a multi-layered configuration comprising a zigzag arrangement. Radiator made.

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