KR20040101129A - surface burning burner - Google Patents

Abstract

PURPOSE: A gas radiation burner is provided to enhance the radiation efficiency of a gas radiation burner by improving the structure of a burner housing. CONSTITUTION: A gas radiation burner comprises a burner port(20) to which mixed gas flows in through an inlet(23), a burner mat(30) placed on the upper surface of the burner port and performing surface combustion, a burner housing(50) having a specific combustion space, having an open hole(52) on the lower surface for opening the burner mat, and having a receiving portion(51) around the open hole for receiving the upper face of the burner port, and a glass(60) installed on the upper surface of the burner housing.

Description

Gas burning burner {surface burning burner}

The present invention relates to a gas radiation burner, and more particularly to the structure of the burner housing.

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

Referring to the gas radiation burner according to the prior art in detail with reference to the accompanying drawings as follows.

1 is a plan view showing a gas radiation burner according to the prior art, Figure 2 is a cross-sectional view along the line I-I showing the separated state of the gas radiation burner of FIG.

As shown in Fig. 1 and Fig. 2, the gas radiation burner according to the prior art is largely the mixing tube 1, the burner port 2, the burner mat (3), the burner housing (5) and the glass (6) It is configured to include).

Here, the mixing pipe 1 is mixed with the fuel and air is introduced.

At this time, the mixing pipe 1 communicates with the burner port 2 through the inlet port 2a of the burner port 2.

The burner mat 3 is seated on a seating portion 2b formed on the burner port 2 and is a portion where the mixed gas in the burner port 2 is surface burned.

The burner housing 5 is screwed with the burner port 2 while forming a space in which the mixed gas is burned.

The glass 6 is a portion that is installed on the burner housing 5 and heats the food by radiant heat.

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

First, when the user places the heating element on the upper surface of the glass 6 and operates the burner, the fuel and air are introduced into the mixing tube 1 and mixed, respectively, and the mixed gas in which the fuel and air are mixed is inlet 2a. It is supplied to the burner port (2) through the mixing pipe (1) connected to and ejected through the burner mat (3).

At the same time, the mixed gas is ignited and combusted by an ignition flame generated by a predetermined ignition and salt detecting means, and the burner mat 3 is heated by the combustion of the mixed gas to generate radiation waves. Cooking is performed by the wave passing through the glass 6 and heating the object to be heated.

On the other hand, a method for increasing the radiation intensity of the gas radiation burner is supplied to the glass by reducing the height (hereinafter referred to as the radiation height) between the radiator that emits radiant energy, that is, the burner mat (3) and the glass (6) There is a way to increase the amount of radiant heat.

3 is a graph showing the relationship between the radiation height and the radiation efficiency of the burner in a general gas radiation burner. As shown in FIG. 3, the radiation efficiency of the burner decreases as the radiation height increases.

On the other hand, the smaller the radiation height, the greater the amount of radiant heat supplied to the glass 6, thereby increasing the radiation efficiency of the burner.

However, the burner housing 5 is formed with a discharge passage F for discharging high-temperature convection heat and exhaust gas generated after combustion of the mixed gas.

Therefore, by reducing the height of the burner housing 5 in order to smoothly discharge high-temperature convection heat and exhaust gas, there is a limit in reducing the radiation height.

Since the burner port 2 is fastened to the bottom surface of the burner housing 5 so that the radiation height H and the height H 'of the exhaust passage F are the same in the above-described gas radiation burner, In order to reduce the height between the burner mat 3 and the glass 6 installed on the burner port 2, that is, the copy height H, there is a limit in reducing the height of the burner housing 5 or more.

Therefore, there has been a demand for the development of a gas radiation burner capable of reducing only the radiation height H while maintaining the height H 'of the exhaust passage F formed in the burner housing 5 to be the same as the existing height.

In addition, when screwing the burner housing 5 and the burner port 2 in the gas radiation burner according to the prior art, the user has to align the screw holes of the burner housing 5 and the burner port 2 depending on the naked eye. Since the assembly of the screw, the center of the opening 5a of the burner housing 5 and the burner port 2 do not exactly coincide, and there is a problem such that the efficiency of the burner is lowered.

The present invention has been made in order to solve the above problems, by improving the structure of the burner housing bottom surface while maintaining the height of the exhaust passage formed in the burner housing while reducing the radiation height to increase the amount of radiant heat supplied to the glass and burner The purpose is to prevent port eccentricity.

1 is a plan view showing a gas radiation burner according to the prior art

Figure 2 is a cross-sectional view taken along line I-I showing the separated state of the gas radiation burner of FIG.

3 is a graph showing the relationship between the radiation height and the radiation efficiency of the burner in a typical gas radiation burner

Figure 4 is a plan view showing a gas radiation burner according to a first embodiment of the present invention

FIG. 5 is a view illustrating a separated state of the gas radiation burner of FIG. 4 along a line II-II. FIG.

FIG. 6 is an enlarged cross-sectional view showing main parts of a state in which the gas radiation burner of FIG. 5 is coupled; FIG.

7 is an exploded view showing another example of the configuration of the accommodation portion of the configuration for the gas radiation burner of FIG.

8 is an enlarged cross-sectional view of a main portion showing a coupling state of the example of FIG. 7;

9 is a cross-sectional view showing a combined state of a gas radiation burner according to a second embodiment of the present invention.

10 is an enlarged cross-sectional view of a main portion showing another example of the accommodation part of FIG. 9;

11 is a configuration diagram showing a separated state of the gas radiation burner according to a third embodiment of the present invention

12 is a cross-sectional view showing a coupling state to the gas radiation burner of FIG.

Explanation of symbols on the main parts of the drawings

10,310. Mixing tube 20,120,320. Burner pot

23,123,323. Inlet 25,125,325. Seating part

30,130,330. Burner Mat 50,150,350. Burner housing

52,152,352. Aperture 60,160,360. Glass

F: Exhaust passage H1, H2, H3: Copy height

H ′: Exhaust Channel Height

One embodiment of the present invention for achieving the above object is a burner port through which the mixed gas is introduced through the inlet; A burner mat seated on an upper surface of the burner port and performing surface combustion; A burner having a predetermined combustion space and having an opening formed on the bottom thereof so as to open the burner mat, and having an accommodating portion bent upward so that the upper surface of the burner port can be coupled around the opening. housing; And, it provides a gas radiation burner comprising a glass: installed on the upper surface of the burner housing.

In addition, another embodiment of the present invention for achieving the above object is a burner port through which the mixed gas is introduced through the inlet; A burner mat seated on an upper surface of the burner port and performing surface combustion; A burner housing having a predetermined combustion space and having an opening formed in the bottom thereof so as to open the burner mat, and having a receiving portion bent upwardly so that the burner mat is received around the opening hole; And, it provides a gas radiation burner comprising a glass: installed on the upper surface of the burner housing.

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

4 is a plan view illustrating a gas radiation burner according to a first embodiment of the present invention, FIG. 5 is a cross-sectional view illustrating a separated state of the gas radiation burner of FIG. 4 along a line II-II, and FIG. A cross-sectional view showing a state in which a gas radiation burner is coupled.

That is, the gas radiation burner according to the first embodiment of the present invention includes a burner port 20, a burner mat 30, a burner housing 50, and a glass 60. The housing 50 is characterized in that it is provided with a receiving portion 51 formed to be coupled to the upper surface of the burner port 20 is accommodated.

The burner port 20 is configured to receive the mixed gas through the inlet 23 and is connected to the mixing pipe 10 into which fuel and air are introduced and mixed with each other.

At this time, a seating portion 25 coupled to the burner housing 50 is integrally formed on the upper surface of the burner port 20 with the recess groove 25a seated in the state where the burner mat 30 is recessed. Is formed.

In addition, the burner mat 30 is formed in the surface of the recess 25a of the seating portion 25 by the configuration in which the mixed gas is burned.

At this time, the height of the concave groove 25a and the burner mat 30 is preferably formed to be substantially the same.

The burner housing 50 has a top surface and a bottom surface to form a space in which the mixed gas is burned, and one side thereof has an exhaust passage F through which exhaust gas is exhausted, and an inside of the accommodating portion 51. The opening hole 52 is formed so that the burner mat 30 is in communication with the combustion space which is the inner space thereof.

At this time, the accommodating part 51 is bent upward so that the seating part 25 of the burner port 20 may be coupled in the accommodated state.

Here, the accommodating part 51 is formed by bending the bottom surface of the burner housing 50 as shown in FIGS. 5 and 6.

Of course, the accommodating part 51 may be manufactured separately from the bottom of the burner housing 50 and attached to the bottom of the burner housing 50 to be integrally formed as shown in FIGS. 7 and 8. have.

In this case, the accommodating part 51 is configured to be detachable from the burner housing 50, so that the upper surface of the burner port 20 is recessed upwardly compared to the bottom surface of the burner housing 50, that is, the accommodating part 51 is detachable from the burner housing 50. It is preferable to be able to be assembled in the state accommodated in the part (51).

In addition, the receiving portion 51 and the seating portion 25 of the burner port 20 are fastened to each other by a fastening member to enable stable fixing of the burner port 20.

At this time, the fastening member may be made in various ways, but the screw is easy to assemble the embodiment.

In addition, the accommodation height of the accommodation portion 51 is preferably formed to be substantially the same or higher than the thickness of the burner mat (30).

This is to shorten the distance between the glass 60 and the burner mat 30, that is, the radiation height H1, so that the overall heat load can be increased, but the exhaust gas is smoothly discharged.

At this time, the glass 60 is seated on the upper surface of the burner housing 50 serves to heat the food by radiant heat.

An operation process according to the first embodiment of the present invention configured as described above, that is, a process in which the mixed gas flows into the burner port 20 for heating the food, and the gas in the burner port 20 is burner mat ( The process of burning on the surface of the burner mat 30 by the ignition spark in the process of passing through 30 is performed in the same manner as in the prior art.

However, in the configuration according to the first embodiment of the present invention, the surface of the burner mat 30 is closer to the glass 60 by the height at which the accommodating portion 51 of the burner housing 50 is formed. An increase in the amount of radiant heat provided to (60) can be obtained.

Of course, the exhaust gas generated as the mixed gas is surface burned in the burner mat 30 is discharged through the exhaust passage F. At this time, since the height of the exhaust passage F does not change from the existing, the exhaust gas is exhausted. It is possible to discharge gas smoothly.

On the other hand, Figure 9 is shown the structure of a gas radiation burner according to a second embodiment of the present invention.

That is, the gas radiation burner according to the second embodiment of the present invention includes a burner port 120, a burner mat 130, a burner housing 150, and a glass 160. The 150 is presented as a feature that is provided with a receiving portion 151 bent to be coupled to the burner mat 130 is accommodated.

Here, the burner port 120 is configured to receive the mixed gas through the inlet 123 and is connected to a mixing tube (not shown) in which fuel and air are introduced and mixed with each other.

The burner mat 130 is mounted on the top surface of the burner port 120 and has a mounting portion 125 coupled to the burner housing 150.

At this time, the seating portion 125 is preferably formed to form a plane, as in the first embodiment of the present invention, the indentation groove (125a) may be formed so that the burner mat 130 is indented, in this case More preferably, the depth of the mouth groove 125a is lower than the thickness of the burner mat 130.

The reason for forming the recess groove 125a is to facilitate the positioning of the burner mat 130.

That is, without the need for a separate operation for exactly matching the center of the burner mat 130 and the center of the burner port 120, only by inserting the burner mat 130 into the recess groove 125a. The centers can be aligned with each other.

In addition, the burner mat 130 is formed to burn the mixed gas on the surface thereof and is seated in the recess groove 125a.

The burner housing 150 has an upper surface and a lower surface so as to form a space in which the mixed gas is burned, and one side thereof has an exhaust passage through which exhaust gas is exhausted (not shown in FIG. 9). .

At this time, an opening hole 152 is formed in the bottom of the burner housing 150 so that the burner mat 130 communicates with the combustion space which is an inner space thereof.

In addition, around the portion of the opening hole 152 is formed is provided with a receiving portion 151 is formed of a multi-stage bent so that the seating portion 125 of the burner port 120 can be coupled.

At this time, the height of the receiving portion 151 is preferably formed to be approximately equal to the height of the burner mat 130 protrudes from the surface of the mounting portion 125 of the burner port 120.

This, so that both surfaces of the burner mat 130 is in close contact with the inner surface of the receiving portion 151 and the recess groove 125a of the burner port 120, but the seat of the burner port 120 This is to close the portion 125 and the burner housing 150 so as to prevent the leakage of the mixed gas.

In addition, the receiving portion 151 is formed by bending the bottom of the burner housing 150.

In particular, the mounting portion 125 of the burner port 120 is fastened to the outside of the portion where the receiving portion 151 of the burner housing 150 is formed.

Of course, the accommodating part 151 may be manufactured separately from the bottom of the burner housing 150 and fixedly coupled to the bottom of the burner housing 150 as shown in FIG.

In this case, the receiving portion 151 is configured to be detachable from the burner housing 150, it is preferable to allow the burner mat 130 can be assembled on the burner housing 150, the seating It is preferable to form the recessed groove 125a in the portion 125 or to form an extremely low level to secure the height thereof.

In addition, the glass 160 is seated on the upper surface of the burner housing 150 serves to heat the food by radiant heat.

The second embodiment of the present invention as described above also performs the heating of the food in the same manner as the structure according to the first embodiment of the present invention, the burner mat 130 by the height of the receiving portion 151 of the burner housing 150 The surface of is close to the glass 160, it is possible to obtain an increase in the amount of radiant heat provided to the glass 160.

Of course, since the radiation height H2 at this time is higher than the radiation height H1 in the above-described first embodiment, it is possible to obtain an increase in the radiation heat amount lower than that of the first embodiment.

Meanwhile, FIGS. 11 and 12 show the structure of the gas radiation burner according to the third embodiment of the present invention.

In the third embodiment of the present invention described above, it is proposed to apply both the structure according to the first embodiment and the structure according to the second embodiment of the present invention.

That is, a first accommodating part 351 bent upwardly is formed at a portion where the opening hole 352 of the burner housing 350 is formed so as to accommodate the entire seating portion 325 of the burner port 320. Inside the first accommodating part 351 is to form a second accommodating part 353 bent upward so that the burner mat 330 can be accommodated.

At this time, the recess 325a of a predetermined depth is formed in the seating portion 325 of the burner port 320 so that the burner mat 330 may be seated, and the height of the second accommodating portion 353 may be increased. Preferably, the height of the burner mat 330 protrudes from the surface of the seating portion 325 of the burner port 320.

In particular, the depth of the recess 325a is more preferably formed lower than the thickness of the burner mat 330. Of course, the recess groove 325a does not have to be formed.

In addition, the first accommodating part 351 is formed by bending the bottom surface of the burner housing 350 as shown in FIG. 12.

In particular, the seating portion 325 of the burner port 320 is fastened to the first accommodating portion 351 of the burner housing 350.

In addition, the second accommodating part 353 is formed to be accommodated in the burner mat 330 by bending upward the inner side of the first accommodating part 351.

Of course, the second accommodating part 353 may be configured to be integral with the burner housing 350 by being fastened to the first accommodating part 351 of the burner housing 350 as shown. It may be.

Reference numeral 310 is a mixing tube in which the mixed gas is introduced, 323 is an inlet.

As a result, according to the structure of the gas radiation burner according to the third embodiment of the present invention described above, the height between the burner mat 330 and the glass 360, that is, the radiation height H3 is the height of the first accommodation portion 351. And a height closer to the height of the second accommodating portion 353, thereby increasing the amount of radiant heat provided to the glass 360.

As described above, according to the present invention, the mounting of the upper surface of the burner port or the burner mat is recessed by a predetermined height from the bottom of the burner housing, thereby maintaining the height of the exhaust passage formed in the burner housing. This will minimize the distance between the burner mat and the glass.

Therefore, the convection heat and exhaust gas generated by the combustion of the mixed gas are smoothly discharged into the exhaust passage, and the height between the burner mat and the glass becomes small, and the amount of radiant heat emitted from the burner mat to the glass is increased, thereby improving the radiation efficiency of the burner. There is.

Claims (6)

A burner port through which the mixed gas is introduced through the inlet; A burner mat seated on an upper surface of the burner port and performing surface combustion; A burner having a predetermined combustion space and having an opening formed on the bottom thereof so as to open the burner mat, and having an accommodating portion bent upward so that the upper surface of the burner port can be coupled around the opening. housing; And, Gas radiation burner comprising a glass: installed on the upper surface of the burner housing. The method of claim 1, Gas burner, characterized in that the upper surface of the burner port is fastened in a state accommodated in the receiving portion of the burner housing. The method of claim 1, The receiving portion is a gas radiation burner, characterized in that formed separately from the bottom of the burner housing is fastened to the bottom of the burner housing. A burner port through which the mixed gas is introduced through the inlet; A burner mat seated on an upper surface of the burner port and performing surface combustion; A burner housing having a predetermined combustion space and having an opening formed in the bottom thereof so as to open the burner mat, and having a receiving portion bent upwardly so that the burner mat is received around the opening hole; And, Gas radiation burner comprising a glass: installed on the upper surface of the burner housing. The method of claim 4, wherein Gas circulating burner, characterized in that the circumferential side of the portion of the burner port on which the burner mat is seated is fastened to the bottom of the burner housing. The method of claim 4, wherein The receiving unit is a gas radiation burner, characterized in that formed separately from the burner housing is configured to be detachable to the burner housing.