KR100734357B1 - Radiation Gas Burner - Google Patents

Abstract

The present invention relates to a gas radiation burner, so that the amount of air supplied into the burner can be increased without reducing the amount of fuel gas supplied into the burner.

The present invention for this purpose, the burner housing is installed in the housing; A burner pot installed at a lower portion of the burner housing and having a space in which a mixed gas of gas and air is supplied; A glass for shielding an upper portion of the burner housing; A plurality of mixing tubes having one end connected to the burner port to supply gas and air from the outside; Provided is a gas radiation burner comprising a plurality of gas nozzles for injecting gas into the respective mixing tubes.

Gas Radiant Burners, Ceramic Glass, Mixing Tubes, Gas Nozzles

Description

Radiation Gas Burner

1 is a sectional view showing the main parts of a conventional gas radiation burner;

Figure 2 is a perspective view showing the configuration of the gas radiation burner according to the present invention

3 is a cross-sectional view of main parts of the gas radiation burner of FIG.

4 is a plan view showing a main part of the gas radiation burner of FIG.

Explanation of symbols on the main parts of the drawings

100: gas copy burner 110: ceramic glass

120: burner housing 130: burner port

140: burner mat 150: mixing tube

160: gas nozzle

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas radiation burner, and more particularly, to a gas radiation burner that is capable of supplying sufficient air for combustion to a gas radiation burner that is heated by using radiant heat through glass to improve combustion efficiency.

As is well known, a gas radiation burner is a burner which heats and cooks a to-be-heated object by the radiation wave which generate | occur | produces the heating of a radiator by combustion of the mixed gas which mixed fuel and air.

Referring to Figure 1 of the accompanying drawings, a brief description of the structure of a conventional gas radiation burner as follows.

First, the conventional gas radiation burner 10 is installed to be in contact with the lower surface of the ceramic glass 11, the burner housing 12 to form a space in which the mixed gas is burned, and the screw and the lower portion of the burner housing 12 The burner port 13 coupled by the same fastening means and supplied with fuel gas and air, the burner mat 14 seated on the burner port 13, and one end communicate with the burner port 13. And the other end is opened to the outside into one mixing tube (15) for supplying a mixed gas of fuel gas and air into the burner port (13), and the outside of the other end of the mixing tube (15) into the mixing tube (15) It consists of the gas nozzle 16 which injects fuel gas.

The conventional gas radiation burner configured as described above operates as follows.

When the user places the heated object on the upper surface of the ceramic glass 12 and operates the burner, fuel gas is injected into the mixing tube 15 through the gas nozzle 16 at high speed. At this time, according to Bernoulli's theorem, the peripheral pressure of the fuel gas injected by the fuel gas is injected at high speed through the gas nozzle 16, so that the open end of the mixing tube 15 is lowered. Outside ambient air is sucked into the mixing tube.

Fuel gas and air introduced into the mixing tube 15 are introduced into the burner port 13 and mixed, and the mixed gas of the fuel gas and air is ejected through the burner mat 14. At the same time, the mixed gas is ignited by the ignition spark generated by the predetermined ignition and salt detection means (not shown), and burned on the surface of the burner mat 14, and the radiation wave caused by the combustion passes through the ceramic glass 11. To heat the heated object.

However, since the upper surface of the gas radiation burner is shielded by ceramic glass, external air does not naturally enter into the burner during combustion, and the combustion gas is discharged along a predetermined exhaust flow path. There is a problem that the air volume is insufficient due to the increase in heat load and the flow path resistance.

Accordingly, the present invention has been made to solve the above problems, to provide a gas radiation burner that improves the combustion efficiency by increasing the amount of air supplied into the burner without reducing the calorific value of the burner in a simple configuration There is a purpose.

The present invention to achieve the above object, the burner housing is installed in the housing; A burner pot installed at a lower portion of the burner housing and having a space in which a mixed gas of gas and air is supplied; A glass for shielding an upper portion of the burner housing; A plurality of mixing tubes having one end connected to the burner port to supply gas and air from the outside; Provided is a gas radiation burner comprising a plurality of gas nozzles for injecting gas into each mixing tube.

Hereinafter, a preferred embodiment of a gas radiation burner according to the present invention will be described in detail with reference to the accompanying drawings.

2 to 4 are views showing a preferred embodiment of the gas radiation burner according to the present invention, the gas radiation burner 100 of the present invention is installed in contact with the lower surface of the ceramic glass 110, the mixed gas is burned A burner port 130 having a burner housing 120 forming a space therein, and a burner port 130 formed at a lower portion of the burner housing 120 by a fastening means such as a screw and having a space where fuel gas and air are supplied and mixed; The burner mat 140 seated on the burner port 130 and one end of the burner port 130 communicate with the burner port 130 and the other end is opened to the outside so that the mixed gas of fuel gas and air is introduced into the burner port 130. It consists of two mixing tubes 150 to be supplied and two gas nozzles 160 for injecting fuel gas into the mixing tube 150 from the outside of the other end of each of the mixing tubes 150.

The mixing tube 150 forms a throttling portion 151 with its open end being smaller than the diameter of the other portion. Therefore, the speed of the fuel gas injected through the gas nozzle 160 passes through the throttle part 151, and thus the pressure in this portion becomes smaller than the other portions, so that the mixing tube ( 150, air is naturally sucked from the outside toward the throttle 151.

In addition, the diameter Di of each gas nozzle 160 includes approximately 1/2 of the gas nozzle diameter Dp of the gas radiation burner having one mixing tube. Therefore, since the velocity of the fluid is inversely proportional to the flow path area, the injection speed of the fuel gas injected through the gas nozzle 160 is increased than that of the conventional gas nozzle.

As the injection speed of the fuel gas through each of the gas nozzles 160 increases, the pressure difference between the throttling portion and the opening portion of each mixing tube 150 increases, and thus, around the end of the mixing tube 150. More air is sucked in than before. This can be easily confirmed by Bernoulli's theorem.

On the other hand, if the diameter (Di) of the gas nozzle 160 is reduced as described above, the flow rate of the injected fuel gas is increased to increase the intake air amount, but the amount of fuel gas supplied from the gas nozzle 160 is reduced to reduce the required heat quantity. As described above, in the present invention, the mixing tube 150 and the gas nozzle 160 are configured in two or more numbers so as to provide a sufficient amount of fuel gas.

Referring to the operation of the gas radiation burner of the present invention configured as described above are as follows.

When the user puts the heating element on the upper surface of the ceramic glass 20 and operates the burner, fuel gas is injected at high speed into each mixing tube 150 through each gas nozzle 160, Air is sucked into the mixing tube 150 together.

The fuel gas and air introduced into the mixing tube 150 are introduced into the burner port 130 and mixed, and the mixed gas of the fuel gas and air is ejected through the burner mat 140. At the same time, the mixed gas is ignited by the ignition spark generated by the predetermined ignition and salt detection means (not shown), and is burned on the surface of the burner mat 140, and the radiation wave caused by the combustion passes through the ceramic glass 110. To heat the heated object.

As described above, when fuel gas is injected into the mixing tube 150 through the gas nozzles 160, the diameter of each of the gas nozzles 160 is smaller than that of the existing gas nozzles 160. The flow rate of the fuel injected through the gas nozzle 160 is further increased, thereby increasing the amount of air sucked out of the mixing tube 150 into the mixing tube 150. At this time, since the mixing tube 150 and the gas nozzle 160 are configured by two, the amount of air is further increased, and the amount of fuel may be provided in the same manner as before.

As described above, according to the present invention, the amount of air can be increased while maintaining the amount of fuel gas supplied to the burner at the same level as the existing one, thereby preventing incomplete combustion due to insufficient air amount and improving combustion efficiency and exhausting. It is possible to reduce the carbon monoxide concentration in the gas.

Claims (2)

A burner housing installed inside the housing to form a space in which the mixed gas of gas and air is combusted; A burner pot installed at a lower portion of the burner housing and having one space in which gas and air are supplied; A plurality of mixing tubes, one end of which is installed in communication with the outside of the burner port, the other end of which is open and the throttling portion is smaller in diameter, and supplies gas and air from the outside; Gas radiation burner including a gas nozzle for injecting gas into the plurality of mixing tubes, respectively The gas radiation burner according to claim 1, wherein each gas nozzle is disposed outside the other end of each mixing tube.

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