KR940009061B1 - Stove - Google Patents

Abstract

The infrared stove warms a room by radiant heat generated from a burner with holed burning plate. The apparatus reduces carbon dioxide gas without largely changing the inner strucure, function or type of the conventional infrared stove. The infrared stove comprises a case (12) having a front face with a open hole (12b) and an upper face installed with a exhaust gas passageway; the burnning plate (21) directed toward the open hole of the front face; porous materials attached on the inner part of the exhaust gas passageway. The porous materials, wire mesh or honeycomb type ceramic plate plays a role of increasing passage resistance of the exhaust gas.

Description

Infrared stove

1 is a broken perspective view of an infrared gas stove according to the present invention.

2 is a side cross-sectional view of an infrared gas stove.

3 is a state diagram of exhaust temperature and oxygen concentration at a specific position of the infrared gas stove.

4 is a detailed state diagram of the exhaust temperature.

* Explanation of symbols for main parts of the drawings

2: gas burner (burner) 3: exhaust port

4: Wire mesh (porous body) 5a, 5b: Indoor air (air)

6: ceramic plate 12: enamel (Virteous enamel) frame (case)

12b: open hole 21: burner plate (burning plate)

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to reducing the generation of nitrogen dioxide in an infrared stove for burning fuel such as gas and petroleum in a burner provided with a flame hole in a combustion plate and heating mainly by radiant heat.

In recent years, the infrared stove which used the burner which uses a ceramic combustion plate as a combustion surface in the case is used. Usually, the front surface of the case of such a stove is an open hole, and has a radiating surface of heat, and an exhaust port is provided in the upper surface of the case.

Further, in the combustion type heating devices is that the generation of nitrogen dioxide (NO ₂₎ problems due to combustion, it is proposed the following means to reduce the nitrogen dioxide.

환원 Place a reducing catalyst in the exhaust vent.

벽 An additional wall is provided to block the air drawn into the combustion section in order to prevent excess air from entering the vicinity of the hot flame and increasing the production of nitrogen dioxide.

However, the method of using a reduction catalyst has the drawback that the reduction catalyst is expensive and easy to deteriorate, and the air barrier wall to the combustion section has a drawback of decreasing radiation efficiency because the wall absorbs radiant heat. have.

An object of the present invention is to provide an infrared stove which can reduce the emission of NO ₂ without greatly changing the durability, function and shape of the conventional infrared stove.

In order to achieve the above object, the infrared stove of the present invention adopts the following configuration.

An infrared stove having a burner having a combustion plate provided toward the open hole in a casing having an open hole on its front surface and having an exhaust port on its upper surface, wherein a porous body is attached to the exhaust hole or above and below to provide ventilation resistance of the exhaust port. When the burner burns, air is prevented from invading from the front surface of the case and discharged to the exhaust port, and the exhaust flow velocity distribution near the porous body is uniformed.

By providing a porous body for adjusting and rectifying airflow resistance in the exhaust port, the following effects can be obtained.

(1) The ventilation resistance of the exhaust port is increased, and the exhaust air flows through the opening in the front of the case. Therefore, the state in which air intrudes and discharges from the front surface of the case does not occur. Therefore, there is no problem that indoor air is introduced from the exhaust high temperature portion under the porous body to produce NO ₂ . Therefore, generation of NO ₂ can be reduced without dropping radiant heat at the front surface.

(2) The exhaust flow of the exhaust port is rectified and the flow velocity distribution is uniform. Therefore, it is possible to prevent the generation of the exhaust high temperature portion that partially occurs during the exhaust in the vicinity of the exhaust port above the porous body. Since NO ₂ tends to be generated in the exhaust high temperature section, the amount of NO ₂ produced can be reduced above the porous body. Therefore, it is possible to reduce the amount of NO ₂ discharged without greatly changing the durability, function and shape of the conventional infrared stove.

A first embodiment of the present invention will be described with reference to FIGS.

1 shows an infrared gas stove. The stove is a gas burner 2 disposed in the main body 1 in which a thin metal plate is formed. The main body 1 exhibits a substantially rectangular parallelepiped shape having a long transverse side, and is a hot-breaking which is continuously opened from the front surface to the upper surface. The use window 1A is formed, and the leg 1B is attached to the lower part. In the window 1A, a reflecting plate 11 and a casing frame 12 serving as a case are fitted, and a protective net 13 is attached to the outside of the window 1A. The frame 12 has a short shape, and is composed of both sides, an upper plate portion having a width, and a bottom plate portion. An exhaust passage 12a is provided side by side in the upper plate portion to form an exhaust port 3. In addition, an open hole 12b is formed in the front surface of the frame 12, and the upper edge 12a of the open hole 12b is bent inward to limit the width of the passage to the exhaust port 3.

The gas burner 2 (two upper and lower stages) includes a burner plate 21 formed of ceramic plates and formed with several small flame holes. The burner plate 21 faces the window 1A and the combustion surface 21a. It is attached to abut the back surface of the frame 12 in the main body 1 so as to face slightly upward. Moreover, the back part of the burner plate 21 is the mixing chamber 22 of fuel gas and combustion air. In addition, a mixture of air and gas sucked from the inlet port Q is blown from the nozzle N into the mixing chamber 22.

4 is a porous mesh made of SUS 304 and has a thickness of 0.4 mm and 20 mesh. The wire mesh 4 is attached to the metal mold 41 fixed in the enamel mold 12.

Next, the effect of the infrared gas stove of this embodiment will be described with FIG. 3 and FIG.

By both when the ignition (the upper and lower two-stage burning), the concentration of NO ₂ is attached to the wire mesh (4) to a third-degree a to, the concentration of NO ₂ first to the third degrees, b if it is not attached to anything in the air outlet (3) As shown, it could be reduced to an average of 8PPM.

When nothing is attached to the exhaust port 3, as shown in a of FIG. 4, since the exhaust high temperature part of 600 degreeC or more exists locally to the upper side of the exhaust port 3, since it mixes with the surrounding indoor air 5a, , NO generated by combustion tends to change to NO ₂ . In this embodiment, since the nozzle N is on the right side, a local exhaust high temperature part is likely to occur on the left side. In addition, since the indoor air 5b easily flows into the mold 12 through the opening 12b, as shown in a of FIG. 3, the oxygen concentration near the exhaust port 3 is high (16-18%). is, NO generated by the combustion is mixed with the oxygen in the exhaust gas is then high-temperature portion easily changed into NO ₂ is a lot, the amount of generation of NO _2.

When the wire mesh 4 is attached, air resistance is generated, the exhaust flow of the exhaust port 3 is rectified, and the flow velocity distribution is cracked. Therefore, as shown in b of FIG. 4, the exhaust temperature distribution becomes almost the same and becomes uniform, the exhaust high temperature portion on the wire mesh 4 disappears, and even if the exhaust gas whose temperature has fallen is mixed with the surrounding indoor air 5a, NO is obtained. Becomes difficult to change to NO ₂ .

In addition, since the exhaust air overflows from the open hole 12b, and it becomes difficult for the indoor air 5b to flow into the frame 12 through the open hole 12b, as shown in b of FIG. 3) and the oxygen concentration is low (9.5~11.5%) in the vicinity of, NO generated by the combustion is difficult to change as NO _2, is generation of NO ₂ is be reduced. In addition, as shown in FIG. 3 and FIG. 4, even if the wire mesh 4 is attached, the average temperature in each specific position is not affected.

C of FIG. 3 and c of FIG. 4 are the second embodiment of the present invention, and this infrared gas stove has a honey-comb-shaped ceramic plate 6 instead of a metal mesh 4 on a metal frame 41. Is attached.

In this embodiment, the NO ₂ concentration when all were ignited was reduced to 6 PPM on average.

In the above embodiment, the thickness of the wire mesh 4, the size and the material of the mesh may be appropriately determined, and the wire mesh 4 may be double.

Claims (3)

An infrared stove having a burner having a combustion plate provided toward the open hole in a casing having an open hole on its front surface and provided with an exhaust port on its upper surface, wherein a porous body is attached to the inside of the exhaust path. Infrared stove, characterized in that to increase the ventilation resistance of the exhaust exhaust. The infrared stove of claim 1, wherein the porous body is made of a wire mesh. The infrared stove according to claim 1, wherein the porous body is a ceramic plate of honeycomb formation.