KR101806780B1 - Electric heater having air-cleaning function - Google Patents

Abstract

The present invention relates to an electric heater which comprises: a ceramic plate including a groove part; a heating body inserted into the groove part of the ceramic plate to emit heat; a reflecting plate delivering the heat to the front; a body supporting the ceramic plate and the reflecting plate; a heat storage cover covering the surface of the ceramic plate with the heating body, inserted into the plate, at a predetermined distance from the plate; a combustion space formed between the ceramic plate and the heat storage cover to enable the flow of gas, and storing the heat of the heating body; an air blowing tube having a side connected to the combustion space, and having the other side formed on the rear side of the reflecting plate while penetrating the reflecting plate; and a blower blowing air to the combustion space through the air blowing tube. The heating body combusts pollutants of air in the combustion space and heated gas from the combustion space is supplied to the front by the reflecting plate, and thus, the electric heater is able to perform a heating function.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric heater having an air-

The present invention relates to an electric heater having a function of purifying contaminants. More specifically, the present invention relates to an electric heater that performs two functions, that is, a heating element provided in an electric heater supplies the heat to heat and simultaneously burns contaminants contained in the air.

Electric heaters that heat by the heat emitted by the electric heating element are often used. Generally, the heat radiator conveys the air around the heating element forward by using a blowing fan to send the heat of the heating element to a desired place, or installs a reflector around the heating element to send heat in a desired direction. The heating element, which is used for heating the room, has a surface temperature between 700 ° C. and 1,000 ° C. The temperature of the heating element, which is used for indoor heating, is determined by the surface temperature of the heating element Lt; / RTI >

On the other hand, in the US Environmental Protection Agency (EPA-452 / F-03-022: Air Pollution Control Technology Fact Sheet, page 3), general volatile organic compounds (VOCs) Lt; RTI ID = 0.0 > C, < / RTI >

According to the above data, heating elements used in most electric heaters already have the ability to pyrolyze contaminants. In other words, the electric heater has the potential to perform two functions of pyrolyzing and purifying the pollutants using the heat of 700 ° C. or more, which is emitted by the heating element, and also heating the air by the radiant heat.

In many cases, the electric heater supplies the hot air generated by the air blowing fan through the heating element quickly to the front. The surface temperature of a heating element installed in such an electric heater may rise by 700 ° C or more if there is no wind blowing by the blowing fan. However, the temperature of the air for heating effect is preferably 100 ° C or less. Therefore, the strong airflow blown by the blowing fan causes heat exchange with the heating element, and the actual temperature of the heating element is much lower than 700 ° C., so that it can not pyrolyze the pollutant. This type of heating is similar to that of a hair dryer.

The surface temperature of the heating element can be increased by 700 ° C or more even though the reflector reflects the radiation of the heating element to the front surface. However, the probability that the contaminant contained in the air volatilizes to the surface of the heating element and is thermally decomposed is very low.

Conventional electric heaters have been designed to heat the room air and have not been used for the purification of contaminants contained in the air by utilizing the potential thermal decomposition function of the heating body. An electric heater, which keeps the heating function and purifies the pollutants around it, is economical in that it uses various kinds of heat energy of the heating body.

Also, the electric heater that purifies the pollutants by the pyrolysis method is convenient because it does not need replacement parts such as a filter mounted on the air cleaner.

The amount of pollutants that can be pyrolyzed per unit of time by a heater with air purifying function is less than that of an air purifier that purifies the air with a filter. However, it has an effect of purifying air as compared with a conventional electric heater which only performs heating, and particularly has an effect of purifying fine dust which can not reduce the filter.

The present invention provides an electric heater capable of purifying contaminants without reducing the heating efficiency of the air at all, thereby helping to solve the indoor air pollution problem.

Registered patent: 10-1212955 (electric stove with prefabricated reflector). Registered patent: 10-1091840 (electric stove with enhanced thermal conductivity). Published patent: 10-2009-0104756 (electric stove). Registered patent: US 8,467,668 B2 (Infrared room heater system). Registered patent: US 4,626,659 (Electric infra-red ray generator constituting atmosphere purifier).

Conventional electric heaters using heating as a main function can purify the contaminants contained in the air utilizing the potential pyrolysis function that has not been utilized yet. In addition to increasing the energy utilization of conventional electric heaters, which use only expensive heating power, they are trying to improve the living environment by purifying pollutants in the air

A ceramic plate having a groove portion; A heating element fitted in a groove portion of the ceramic plate to radiate heat; A reflector for transmitting the heat of the heating element forward; A body for supporting the ceramic plate and the reflection plate; A heat storage cover which covers the surfaces of the ceramic plates fitted with the heat generating elements in parallel to each other at a predetermined interval to confine the heat; A combustion space formed between the ceramic plate and the heat storage cover so as to allow gas flow therethrough, the heat of the heat generating element being stored and maintained at a high temperature; A blowing pipe communicating with the combustion space on one side and passing through the reflection plate and the other side formed on the rear surface of the reflection plate; And a blower that sucks the surrounding air and blows it back into the combustion space through the blower pipe,

Wherein the heating element burns the contaminants contained in the air in the combustion space and the heated gas exiting the combustion space is forwardly reflected by the reflector so that heating is achieved.

Here, the blowing pipe is connected to the central portion of the combustion space, and the gas introduced into the combustion space moves from the central portion of the combustion space to the edge direction and is discharged.

Further, it is preferable that the heat storage cover does not transmit light or its surface is coated with a material that does not transmit light.

It is also preferable that the spacing distance between the ceramic plate and the heat storage cover is between 5 and 30 mm.

Further, it is preferable to further include a temperature sensor for controlling on / off operation of the heating element.

In addition, it is preferable that the time during which the air containing the pollutant stays in the combustion space can be controlled by controlling the rotational speed or air volume of the blower.

The electric heater according to the present invention has the following effects.

First, the heating element provides heat to both heat and combust the pollutant, thereby enhancing energy utilization and improving the living environment.

Second, the heaters that purify the pollutants by the combustion method are economical because they do not require replacement parts such as filters mounted on the air cleaner.

1 is a side cross-sectional view of an electric heater 10 according to Embodiment 1. Fig.
2 is a cross-sectional view of FIG.
3 is a side sectional view of the electric heater 10 'according to the second embodiment.

Other features and actions of the present invention will be described in detail with reference to the following examples.

1 and 2, the electric heater 10 according to the first embodiment includes a reflection plate 25, a heating body 30, a ceramic plate 50, a heat storage cover 40, a blowing tube 70, a blower 60, and a temperature sensor 80.

The reflection plate 25 accommodates the ceramic plate 50 and the heating body 30 in a space in the center of the concave rectangular plate and reflects the heat radiated by the heating body 30 to the front surface where the opening is formed. The reflector 25 concentrates and diffuses the heat of the heating element 30 toward the front, and a protective net 90 is installed on the entire surface of the opening.

The ceramic plate 50 has a flat plate-like shape and has a plurality of grooves formed on one side thereof with a predetermined gap. The heat generating element 30 is fixed in the groove portion by a coil-shaped heat line and receives heat to dissipate heat. The heating element 30 is heated to a surface temperature between 700 ° C. and 1,000 ° C. and emits radiant heat corresponding to a peak wavelength of 2 to 3 micrometers (μm).

The heat storage cover 40 serves to cover the surface of the ceramic plate 50 fitted with the heat generating element 30 in parallel with a predetermined cross section to confine heat of the heat generating element 30. The heat accumulation cover 40 is made of ceramic, ceramic glass, or heat resistant metal, or a combination thereof.

Between the ceramic plate 50 and the heat storage cover 40, a combustion space 35 capable of gas flow and storing the heat of the heat generating element 30 is formed. The combustion space 35 is maintained at a high temperature close to the surface temperature of the heating element 30, and the contaminant introduced into the combustion space 35 is burned by the heating element 30.

In the middle of the combustion space 35, a blowing tube 70 having a tube shape capable of flowing gas therein is connected. One side of the blowing pipe (70) passes through the ceramic plate (50) and communicates with the center of the combustion space (35). The other end of the blowing pipe 70 is connected to the blower 60 located on the rear surface of the reflection plate 25 while passing through the reflection plate 25. The blower 60 sucks the ambient air and sends it to the combustion space 35 through the blowing pipe 70 by rotating the blades to make a flow of air.

The reflection plate 25 is provided with a temperature sensor 80 for sensing the temperature around the heating element 30. [ The temperature sensor 80 controls the on / off operation of the heating element 30 to prevent the electric heater 10 from overheating.

Referring to FIG. 3, the electric heater 10 'according to the second embodiment includes a reflector 25', a heating element 30 ', a ceramic plate 50', a heat storage cover 40 ' A blowing pipe 70 ', a blower 60' and a temperature sensor 80 '.

The reflector 25 'is a parabolic concave mirror. The reflector 25' accommodates the ceramic plate 50 'and the heating element 30' in a space in the center of the interior thereof. The reflecting plate 25 'reflects the heat radiated by the heating element 30' do. The reflecting plate 25 'collects and diffuses the heat of the heating element 30' toward the front, and a protective net 90 'is installed on the entire opening.

The ceramic plate 50 'has a conical shape tapered toward the reflection plate 25'. On the outer circumferential surface of the ceramic plate 50 ', a coil-shaped heating element 30' is wound around the spiral groove. The heating element 30 'receives heat and dissipates heat.

The heat storage cover 40 'serves to cover the heat of the heating element 30' by covering the surface of the ceramic plate 50 'fitted with the heating element 30' in parallel with a predetermined diameter. The heat storage cover 40 'may be made of ceramic, ceramic glass, or a heat resistant metal, or a combination thereof.

Between the ceramic plate 50 'and the heat accumulating cover 40', a combustion space 35 'in which gas flow is possible and heat of the heat generating element 30' is stored is formed. The combustion space 35 'is maintained at a high temperature close to the surface temperature of the heating element 30', and contaminants introduced into the combustion space 35 'are burned by the heating element 30'.

In the middle of the combustion space 35 ', a blowing tube 70' having a tube shape capable of flowing gas therein is connected. One side of the blowing pipe 70 'communicates with the center of the combustion space 35' through the ceramic plate 50 '. The blowing pipe 70 'is connected to the blower 60' located on the rear side of the reflector 25 'with the other side passing through the reflector 25'. The blower 60 'sucks the ambient air and sends it to the combustion space 35' through the blowing pipe 70 'by rotating the blades to make a flow of air.

The reflector 25 'is provided with a temperature sensor 80' for sensing the temperature around the heating element 30 '. The temperature sensor 80 'controls on / off operation of the heating element 30' and prevents overheating of the electric heater 10 '.

In order to effectively burn the pollutants, it is desirable to allow the combustion spaces 35, 35 'in which the air is maintained at 590 DEG C or higher to stand for a predetermined time or 0.5 second or more. It is possible to control the flow rate of the air flowing into the combustion spaces 35 and 35 'per unit time and the time at which the air stays in the combustion spaces 35 and 35' by controlling the rotational speed or the air flow rate of the blowers 60 and 60 ' have.

The electric heaters 10 and 10 'burn the contaminants contained in the air through the following process and simultaneously warm the air in front of the reflectors 25 and 25'.

First, when power is supplied, the heat generating elements 30 and 30 'radiate heat to heat the combustion spaces 35 and 35' and the heat accumulating covers 40 and 40 '. Air around the rear surface of the reflectors 25 and 25 'is sucked into the blowers 60 and 60' and flows into the center of the combustion spaces 35 and 35 'through the blowing pipes 70 and 70'. The pollutants contained in the introduced air are burned by the heating elements 30 and 30 'during the movement (F1, F1') toward the edge from the center of the combustion spaces 35 and 35 '. The hot gas escaping through the edges of the combustion spaces 35 and 35 'is forwardly reflected by the reflectors 25 and 25' to be heated.

The heat accumulating covers 40 and 40 'are provided to confine the heat of the heat generating bodies 30 and 30' to keep the temperatures of the combustion spaces 35 and 35 'close to the surface temperature of the heat generating bodies 30 and 30' The distance d and d 'between the ceramic plates 50 and 50' and the ceramic plates 50 and 50 'is preferably between 5 and 30 mm. When the clearances d and d 'are greater than 30 mm, it is difficult to maintain the temperature of the combustion spaces 35 and 35' at a temperature high enough to effectively burn the pollutants. When the clearances d and d 'are smaller than 5 mm, the radiant heat supplied to the front surface through the heat storage covers 40 and 40' increases, thereby reducing the combustion capacity of the combustion spaces 35 and 35 '.

It is preferable that the heat storage covers 40 and 40 'do not transmit light. The heat storage covers 40 and 40 'do not transmit light or the surface of the heat storage covers 30 and 30' is made of a material that does not transmit light in order to effectively block the heat and light emitted from the heat emitting bodies 30 and 30 ' Coated.

In the conventional reflector type electric heaters, radiant heat of a heating element is reflected forward and heated, and there is no forced air movement. Therefore, the surface temperature of the heating element is maintained at a relatively high temperature (700 ° C. to 1,000 ° C.) to have the ability to pyrolyze contaminants. However, the pollutants contained in the air do not go to the surface of the heating element voluntarily but move away from the heating element, and the probability of practically pyrolyzing is very small.

In the conventional hot air type electric heaters, the hot air blown by the blowing fan blowing air around the heat generating element is fed forward and heated. Thus, the heating element does not reach a high temperature at which it can exchange contaminants with the air passing through the environment at high speed. There is no support to block or inhibit air movement around the heating element in order to move the air quickly around the heating element and forward.

The electric heaters 10 and 10 'according to the present invention cover the heat generating elements 30 and 30' and prevent the radiant heat supplied to the front side, and instead, the air blown by the blowers 60 and 60 ' Is formed in the combustion spaces 35 and 35 'to be a high-temperature gas and is forwardly reflected, which is different from the conventional reflector plate type electric heaters. In addition, since the ceramic plates 50 and 50 'and the heat storage covers 40 and 40' provided around the heat generating elements 30 and 30 'transmit high temperature gas to the other side than the front side, the electric heaters 10 and 10' And the difference between the two types of heat exchangers is large.

The electric heaters 10 and 10 'according to the present invention allow the heat storage covers 40 and 40' to block the heat of the heat generating elements 30 and 30 ' So that contaminants contained in the air are burned in the combustion spaces 35 and 35 'and the high-temperature gas exiting through the edges of the combustion spaces 35 and 35' is supplied to the reflectors 25 and 25 ' 'Are functionally different from the conventional electric heaters in that they are forwardly reflected and heated.

The scope of the present invention is not limited to the above-described embodiments, and various changes and modifications may be made by those skilled in the art. Accordingly, the invention is limited only by the following claims.

10, 10 ': electric heater 20, 20': body
25, 25 ': reflector 30, 30': heating element
35, 35 ': combustion space 40, 40': heat storage cover
50, 50 ': ceramic plate 60, 60': blower
70, 70 ': blowing pipe 80, 80': temperature sensor
90, 90 ': Protective net
F1, F1 ': the flow of air moving toward the edge from the center of the combustion space 35, 35'.

Claims (7)

1. An electric heater comprising a ceramic plate having a groove formed therein, a heating element inserted in a groove of the ceramic plate to radiate heat, a reflecting plate for forwarding heat of the heating element, and a body for supporting the ceramic plate and the reflecting plate,
A heat storage cover which covers the surfaces of the ceramic plates fitted with the heat generating elements in parallel to each other at a predetermined interval to confine the heat;
A combustion space formed between the ceramic plate and the heat storage cover so as to allow gas flow therethrough, the heat of the heat generating element being stored and maintained at a high temperature;
A blowing pipe communicating with the combustion space on one side and passing through the reflection plate and the other side formed on the rear surface of the reflection plate;
And
And a blower which sucks the surrounding air and blows it back into the combustion space through the blower pipe,
The heating element burns contaminants contained in the air in the combustion space,
And the heated gas exiting the combustion space is fed forward by the reflector to perform heating. The electric heat exchanger according to claim 1, wherein the blowing pipe is connected to a central portion of the combustion space. 2. The heat exchanger according to claim 1, characterized in that the gas introduced into the combustion space moves from the central portion toward the edge, The electric heater according to claim 1, wherein the heat storage cover does not transmit light. 2. The electric heater according to claim 1, wherein the spacing d and d 'between the ceramic plate and the heat storage cover is between 5 and 30 mm. delete delete

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