KR101302505B1 - Gas burner - Google Patents

Abstract

The present invention relates to a gas burner, wherein the air supplied through the air inlet of the exterior body is supplied to the outer surface of the mixing unit through the air inlet hole of the fuel mixing unit, and the gas supplied to the gas inlet of the exterior body is the gas guide of the fuel mixing unit. The gas is injected into the gas ejection hole of the gas guiding pipe through the pipe and supplied into the mixing unit, and the air and gas supplied into the mixing unit are mixed in the partition space inside the mixing unit partitioned by the partition wall of the combustion unit. The gas is blown upward through the gas ejection hole of the combustion part, and the fuel gas is ignited by the spark generated between the electrode rod exposed through the electrical pipe of the combustion part and exposed to the upper part of the upper plate and the ignition pin formed on the upper surface of the upper part of the combustion part to generate a spark. .
In the gas burner according to the present invention, the ignited flame is not affected by the pressure of the gas and the air supplied to the mixing part, and the air ejected through the gas ejection hole of the gas guide pipe is supplied through the air inlet hole of the mixing part. The mixing power is increased by mixing with, and the mixing time is shortened by quickly mixing the predetermined amount of gas and air in the compartment inside the mixing part, and the ignition and combustion efficiency is increased by increasing the mixing power of fuel gas. have.

Description

Gas burner

The present invention relates to a gas burner, and more particularly, gas and air are cross-mixed with each other while gas and air are supplied to a mixing unit having a space partitioned by a partition wall of a combustion section, and fuel gas mixed in the partitioned space is fuel of the combustion section. The present invention relates to a gas burner which is ejected upward through a blowhole and is ignited by a spark generated between an electrode and an ignition pin.

In general, a gas burner is a device for economically burning a gas to obtain a light source or a heat source. The gas burner is generally used because it is easy to control the air for complete combustion.

At this time, the gas burner ejects gas to the nozzle and sends air in a predetermined amount to spark through the spark plug in a state where air and gas are well mixed, and the fuel gas is ignited by sparks of the spark plug to generate sparks. The structure is divided into a diffusion type (premixed) gas burner and a premixed gas burner according to a method of mixing gaseous fuel and combustion air.

At this time, the pre-mixing method is ignited by the ignition plug while being ejected upward through the pipe in a state where the gas and air are mixed in advance, and there is a risk that the gas is exploded by burning the fuel gas mixed with the flame.

Therefore, FIG. 1 is a view illustrating a diffusion type (premixed) gas burner, and includes an air inlet pipe 10 through which air is introduced, and a hollow shape having an upper surface open at an end of the air inlet pipe 10. The mixing unit 20 is connected, and the nozzle 30 is coupled to be exposed to the inside of the mixing unit 20 to supply gas into the mixing unit 20, and the mixing unit 20 The burner head 40 is mounted on the upper surface, and the spark plug 50 is provided between the burner head 40 and the mixing unit 20.

At this time, when the air is supplied to the air inlet pipe 10, the gas is supplied through the nozzle 30, the air and gas is supplied to the mixing unit 20 is mixed, the mixed fuel gas to the top At the same time, the spark is ignited by the spark of the spark plug 50 to generate a spark and collide with the bottom of the burner head 40 to radially spread.

At this time, the air inlet pipe 10 is preferably connected to the air suction pump (not shown) to suck the outside air is supplied with air.

In addition, by adjusting the amount of air supplied to the air inlet pipe 10 according to the amount of the gas supplied to the mixing unit 20, it is possible to adjust the mixing ratio of the gas and air.

However, as described above, the gas and air are mixed in the mixing part 20 and ejected to the upper part, but the structure of sparking the spark plug 50 to ignite the fuel gas has a structure in the mixing part 20 having a predetermined area. Combustion force is lowered due to poor mixing of the air and the gas ejected from the unified nozzle 30 is mixed with the air, which takes a long time to mix, and the mixing force is lowered, and is supplied to the mixing unit 20. The spark ignited by the pressure of the gas and the air is incompletely burned, there is a problem that the spark is turned off because the ignition is not properly made due to a decrease in the mixing force of the gas and air.

The present invention is to solve the above problems, an object of the present invention is that the air supplied through the air inlet of the exterior body is supplied to the outer surface of the mixing section through the air inlet hole of the fuel mixing section, the gas inlet of the exterior body The supplied gas is ejected into the mixing section through the gas guiding pipe of the fuel mixing section and supplied to the mixing section, and the air and gas supplied into the mixing section are partitioned inside the mixing section partitioned by the partition wall of the combustion section. The gas is blown upward through the gas ejection hole of the combustion part in a mixed state in the space, and sparks are generated between the electrode rod exposed through the electrical pipe of the combustion part and exposed to the upper part of the upper plate and the ignition pin formed on the upper surface of the combustion part. The fuel gas is ignited to provide a gas burner that generates a spark.

In addition, an object of the present invention is to provide a gas burner through which the gas ejection hole of the gas guide pipe penetrates in the annular direction of the mixing section, so that the gas supplied through the gas ejection hole is easily mixed with the air supplied to the air inlet hole of the mixing section. It is.

In addition, an object of the present invention is to form a gas guide pipe of the fuel mixture in a radial shape, the gas ejected through the gas ejection hole of each gas guide pipe is easily mixed with the air supplied through the air inlet hole of the mixing section It is to provide a gas burner.

In order to achieve the object of the present invention as described above, the gas burner according to the present invention has a hollow inlet shape of the upper surface is formed with an air inlet for introducing air to one side, the gas inlet for supplying gas to the other side The outer body is formed; and the mixing portion is inserted and coupled to the upper portion of the outer body in a hollow shape having an upper surface, a plurality of air inlet holes are formed spaced apart a predetermined interval along the outer surface of the mixing portion, the mixing At least one electrode pipe hole is formed on the bottom of the part, and a gas guide tube connected to the gas inlet and the pipe of the exterior body is formed to protrude from the bottom of the mixing part, and spaced apart from the predetermined part in the annular space. The mixing unit is formed through at least one gas ejection hole for the gas supplied through the gas guide tube A fuel mixing part in which a gas guide pipe is ejected to the inside; and a top plate seated on an upper portion of the fuel mixing part in a plate shape to seal the mixing part, and spaced apart from each other at an annular interval on an upper surface of the top plate. A plurality of fuel ejection holes for passing the fuel gas mixed in the upper portion is formed therein, and a plurality of partition walls for partitioning the inside of the mixing portion are formed on the bottom surface of the upper plate so as to be spaced apart at a predetermined interval in an annular shape. An electrode pipe passing through the electrode pipe hole and passing the electrode rod therein is formed to protrude, and a combustion part having an ignition pin formed on the upper surface of the upper plate through the electrode pipe and spaced apart from the electrode rod exposed at a predetermined interval to cause sparks. It is characterized by consisting of;

In the gas burner according to the present invention, the exterior body is formed so that the center penetrates along the inner circumference thereof, and a through hole through which the electrode pipe of the combustion unit passes is formed on the upper surface thereof, and the air supplied through the air inlet is centered. It characterized in that the air guide plate for guiding to move upward through the.

In the gas burner according to the present invention, the fuel mixing portion is characterized in that the auxiliary air inlet hole is formed on the bottom surface of the mixing portion spaced apart in a predetermined interval.

In the gas burner according to the present invention, the fuel mixing portion is characterized in that the gas guide pipe is formed to have a radial shape from the bottom surface of the mixing portion to the top.

In the gas burner according to the present invention, the fuel mixing section is characterized in that the gas ejection hole of the gas guide pipe for ejecting the supplied gas to the mixing section is formed in the annular direction.

In the gas burner according to the present invention, the combustion portion is spaced apart in a predetermined interval on the upper surface of the upper plate, the fuel gas guide plate is formed at a predetermined angle to flow the fuel gas ejected from the fuel injection hole in a predetermined direction is formed It is characterized by being.

In the gas burner according to the present invention, the combustion unit is characterized in that it further comprises a diffuser of the upper and lower narrow structure to disperse the spark ignited on the upper surface of the upper plate to the outside.

Gas burner according to the present invention as described above, the ignited flame is not affected by the pressure of the gas and the air supplied to the mixing portion, the gas ejected through the gas inlet hole of the gas guide pipe to the air inlet hole of the mixing portion The mixing power is increased by cross-mixing with the air supplied through the mixture, and the mixing time is shortened by rapidly mixing a predetermined amount of gas and air in the compartment inside the mixing section, and the ignition and combustion efficiency is increased by increasing the mixing power of fuel gas. There is a rising advantage.

1 is a schematic diagram showing a gas burner according to the prior art.
Figure 2 is a perspective view of a gas burner according to the present invention.
3 is an exploded perspective view of Fig.
4a to 4b are views showing a state in which the gas burner according to the present invention is operated.
5 is a view showing a state in which a diffusion port is installed in the gas burner according to the present invention.

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

Figure 2 is a perspective view showing a gas burner according to the present invention, Figure 3 is an exploded perspective view of Figure 2, Figures 4a to 4b is a view showing a state in which the gas burner operating according to the present invention, Figure 5 is the present invention Figure is a view showing a state in which the diffusion port is installed in the gas burner according to.

The exterior body 100 has an air inlet 101 through which air is introduced into one side of the hollow body having an upper surface open, and a gas inlet 102 through which gas is supplied to the other side.

The exterior body 100 is provided with a high-voltage discharger (not shown) at the bottom to supply a current to the electrode B (B) passed through the electrode pipe 303 of the combustion unit 300.

Preferably, the exterior body 100 has a hole 104 formed therein through which electrical wiring connected to a high-voltage discharger (not shown) passes.

The exterior body 100 is preferably installed to be connected to the air suction pump (not shown) or the suction fan (not shown) to the air inlet 101 to force the suction of the outside air, the user's choice Accordingly, the outside air can be naturally supplied through the air inlet 101.

The exterior body 100 is formed so that the center penetrates along the inner circumference thereof, and a through hole 103a through which the electrode pipe 303 of the combustion unit 300 passes is formed on the upper surface thereof, and the air inlet 101 is formed. Air guide plate 103 for guiding the air supplied through the () to move upward through the center is formed.

The air guide plate 103 is formed to be spaced apart from the mixing portion 201 of the fuel mixing portion 200 by a predetermined height to form a space in which the air remains, the air inlet hole 202 of the mixing portion 201 The air in the remaining space is continuously supplied.

The air guide plate 103 may control the flow rate of air by forming a central shape through one of a circle, a hemisphere, and a polygon.

The fuel mixing part 200 includes a mixing part 201 which is inserted into and coupled to the upper part of the exterior body 100 in a hollow shape having an open upper surface, and a plurality of spaced intervals along the outer surface of the mixing part 201. Air inlet holes 202 are formed, and at least one electrode pipe hole 203 is formed at the bottom of the mixing part 201, and the appearance body 100 is formed on the bottom of the mixing part 201. A gas guide tube 204 connected to the gas inlet 102 of the pipe (P) is formed to protrude, and is formed spaced apart in a predetermined interval in the annular inside the mixing unit 201 through the gas guide tube 204 A gas guide pipe 205 for ejecting the supplied gas into the mixing unit 201 through the gas ejection hole 205a is formed.

The fuel mixing unit 200 receives air through the air inlet hole 202 and air is introduced into the mixing unit 201.

The fuel mixing unit 200 receives the gas from the gas inlet 102 of the outer body 100, the gas guide pipe 204 is moved to the upper, the gas moved to the upper each of the gas guide pipe Guided to 205 is ejected into the mixing unit 201 through the gas blowing hole (205a).

The fuel mixing unit 200 is formed such that the gas guide pipe 205 has a radial shape from the bottom of the mixing unit 201 to the top.

The fuel mixing unit 200 preferably has a distal end of the gas guide pipe 205 having a radial shape, and a distal end thereof protrudes upward from the outer surface of the mixing unit 201.

The fuel mixing unit 200 has a gas ejection hole 205a of the gas guide pipe 205 for ejecting the supplied gas to the mixing unit 201 in an annular direction.

The fuel mixing unit 200 is an annular gas is ejected from the gas ejection hole 205a of each of the gas guide pipes 205 so that the gas ejected from the gas ejection hole 205a is mixed with the mixing unit 201. Cross-mixed orthogonally with the air flowing into the air inlet hole 202 of the.

The fuel mixing unit 200 is partitioned inside the mixing unit 201 by the partition wall 302 of the combustion unit 300, the gas supplied to the mixing unit 201 in each partitioned space And air are mixed.

The fuel mixing unit 200 has an auxiliary air inlet hole (202a) is formed on the bottom surface of the mixing unit 201 to be spaced apart in a predetermined interval.

The auxiliary air inlet hole 202a vertically supplies air into the mixing unit 201, thereby assisting gas and air cross-mixed in the orthogonal direction in the mixing unit 201 to be easily mixed up and down. .

The fuel mixing unit 200 passes through the electrode pipe 303 of the combustion unit 300 to at least one electrode pipe hole 203 formed on the bottom surface of the mixing unit 201.

Combustion unit 300 is provided with a top plate 301 that is seated on the fuel mixing unit 200 in the shape of a plate to seal the mixing unit 201, spaced apart intervals predetermined in the upper surface of the top plate 301 And a plurality of fuel ejection holes 301a through which the fuel gas mixed in the mixing unit 201 passes upward, and partition walls for partitioning the inside of the mixing unit 201 on the bottom surface of the upper plate 301 ( 302 is formed in a plurality of annular spaced intervals, the upper surface of the upper plate 301 is passed through the electrode pipe hole 203 and the electrode pipe 303 for passing the electrode bar B therein is formed protruding and On the upper surface of the upper plate 301, an ignition pin 304 is formed to be sparked by being spaced apart from the electrode rod B exposed upward through the electrode pipe 303.

The combustion unit 300 has a diameter of the upper plate 301 to seal the upper portion of the mixing unit 201 of the fuel mixing unit 200, the coupling is inserted into the opened portion of the exterior body 100, the exterior body It is preferable to be manufactured to a size that can block the opened portion of the (100).

The combustion unit 300 has the partition wall 302 inserted into the mixing unit 201 of the fuel mixing unit 200 so that the gas guiding pipe 205 is connected to each of the mixing unit 201. Preferably, the gas guide pipe 205 may be divided into two or three sets by adjusting the number of partition walls 302 according to a user's selection.

The combustion unit 300 may adjust the amount of the fuel gas is ejected by producing a diameter of the fuel injection hole (301a) in which the fuel gas is ejected in various sizes according to the user's selection.

The combustion unit 300 forms a protrusion 307 at a central portion of the upper plate 301 to prevent the spark ignited from being collected at the center.

The combustion unit 300 passes the electrode B to the inside of the electrode pipe 303 so that the electrode B is exposed to the upper surface of the upper plate 301, thereby the electrode B and the ignition pin 304. ) Is formed spaced apart from a predetermined interval.

The electrode pipe 303 is formed to surround the outer surface of the electrode B to prevent the current flowing to the outer surface of the electrode B from affecting the gas and air mixed in the mixing unit 201.

The electrode B is connected to a high-voltage discharger (not shown) provided in the lower portion of the exterior body 100 to receive a current, and sparks between the ignition pins 304 formed to be spaced at a predetermined interval. The fuel gas ejected through the ejection hole 301a is ignited.

The combustion unit 300 preferably has an interval of 3.5 mm between the ignition pin 304 and the electrode B, and may be adjusted to have various intervals according to a user's selection.

The combustion unit 300 is spaced in the annular interval on the upper surface of the upper plate 301, the fuel gas guide plate 305 is formed at a predetermined angle to flow the fuel gas ejected from the fuel injection hole (301a) in a predetermined direction ) Is formed.

The combustion unit 300 is preferably ignited so that the fuel gas collided with the fuel gas guide plate 305 and moved in a predetermined direction generates a tornado-shaped flame, and the flame ignited in the tornado is a food cooking utensil (not shown). When the bottom surface is heated annularly, the heat conduction efficiency is increased.

The combustion unit 300 may adjust the fire power by variously adjusting the direction and angle of the fuel gas guide plate 305 according to the user's selection.

The combustion unit 300 further includes a diffuser 306 having a light beam narrow structure for dispersing the spark ignited on the upper surface of the upper plate 301 to the outside.

The combustion unit 300 is preferably the diffusion port 306 is installed in close proximity to the fuel injection hole (301a) of the upper plate 301 to disperse the spark ignition to the outside, the diffusion according to the user's choice The sphere 306 and the top plate 301 may be formed to have a predetermined height.

The combustion unit 300 may adjust the diffusion angle of the fire dispersed through the diffusion hole 306 by the user selects and manufactures an angle of the diffusion hole 306 having an image light narrowing structure.

The combustion unit 300 is preferably the diffusion port 306 is coupled to the upper portion of the protrusion 307.

The combustion unit 300 may be manufactured in a circular shape in the shape of the diffusion hole 306, and may be manufactured in various shapes according to a user's selection.

The gas burner according to the present invention configured as described above is used as follows.

First, the air inlet 101 is formed on one side in a hollow shape, the high-pressure discharge (not shown) is provided below the outer body 100, the gas inlet 102 is formed on the other side, the air inlet 101 An air suction pump (not shown) is installed at the upper part, and the mixing part 201 of the fuel mixing part 200 is inserted into and coupled to the upper part of the exterior body 100, and the gas guide protrudes toward the bottom of the mixing part 201. The pipe 204 is connected to the gas inlet 102 and the pipe (P) of the exterior body 100, the gas guide pipe 205 is provided in the mixing portion 201 spaced apart in a predetermined interval in the annular shape The gas ejection hole 205a is formed on an outer surface of the gas guide pipe 205, and the partition wall 302 of the combustion unit 300 is inserted into the mixing unit 201 to be combined with the mixing unit ( 201) a partition space is formed inside the upper plate 301 formed above the partition wall 302 is the mixing unit 201 It is seated on the surface is the mixing unit 201 is sealed, the fuel injection hole (301a) for ejecting the fuel gas mixed in the mixing unit 201 to the upper spaced interval of the annular to the upper surface of the upper plate 301 to the top Is formed, the electrode plate 303 is passed through the electrode pipe hole 203 of the fuel mixing unit 200 on the bottom surface of the top plate 301 is formed to protrude through the electrode plate (B), the top plate 301 The ignition pin 304 is formed on the upper surface of the electrode bar 303 exposed to the upper portion through the electrode pipe 303 so as to be spaced apart from each other at a predetermined interval to cause sparks.

At this time, by operating the air suction pump (not shown) to suck the air into the air inlet 101 of the exterior body 100, the gas inlet 102 of the exterior body 100 through the gas pipe (not shown) When supplied to the air inlet, the air supplied to the air inlet 101 is moved upward through the exterior body 100 and passes through the air inlet hole 202 of the fuel mixing part 200 to the mixing part. The gas supplied to the inside 201 and supplied to the gas inlet 102 is moved upward through the gas guide tube 204 of the mixing unit 201 through the pipe P, respectively. The pipe 205 is moved and supplied to the mixing unit 201 through the gas ejection hole 205a, and the partition walls 302 of the combustion unit 300 form the respective partition spaces. Gas and air are mixed in the mixing unit 201, and the mixed fuel gas is the fuel powder formed on the upper plate 301. Blowed upward through the ball (301a), the fuel gas is ignited by sparks generated between the electrode (B) and the ignition pin 304 to cause a spark, the bottom surface of the food cooking utensils (not shown) Will be heated.

At this time, a high-voltage discharger (not shown) provided in the lower portion of the exterior body 100 supplies current to the electrode B, so that spark is generated between the electrode B and the ignition pin 304.

In this case, the electrode B is formed to be wrapped in the electrode pipe 303, the current flowing to the outer surface of the electrode B (B) is prevented from being exposed to the outside by the electrode pipe 303, the mixing unit 201 ) The gas and air mixed inside are not affected by the current.

In addition, the spacing between the ignition pin 304 and the electrode (B) is preferably 3.5mm, it can be adjusted to have a variety of intervals according to the user's selection.

In addition, it is preferable that the exterior body 100 has a hole 104 through which an electric wiring (not shown) connected to a high voltage discharger (not shown) is formed on a bottom surface thereof.

In addition, the exterior body 100 is preferably connected to the air suction pump (not shown) or the suction fan (not shown) installed in the air inlet 101 so that the external air is forcibly sucked, the user's Optionally, the external air may be naturally supplied through the air inlet 101.

In addition, the gas guide tube 204 of the mixing unit 201 guides the gas supplied through the pipe (P) to be distributed to the respective gas guide pipe 205 to the top.

At this time, the end of the gas guide pipe 205 is sealed so that the gas supplied to the gas guide pipe 205 is ejected into the mixing unit 201 through the gas ejection hole 205a.

In addition, the gas guide pipe 205 has a radial shape from the bottom surface of the mixing section 201 to the top, the end portion of the gas guide pipe 205 is close to the outer surface of the mixing section 201, the top The gas is ejected around the inner surface of the mixing unit 201 through the gas ejection hole 205a of the gas guide pipe 205.

At this time, the gas ejection hole 205a is penetrated in the annular direction so that gas is ejected in the annular direction, so that the gas ejected from the gas ejection hole 205a is transferred to the air inlet hole 101 of the mixing unit 201. Cross mixed orthogonally with the incoming air.

In addition, the mixing unit 201 is partitioned by the partition wall 302 of the combustion unit 300, and gas and air are mixed in each partition space to shorten the mixing time.

In this case, the gas guide pipe 205 of the mixing unit 201 is preferably partitioned into the mixing unit 201 by the partition wall 302 of the combustion unit 300, respectively, to the user's choice Accordingly, the number of partition walls 302 may be adjusted to partition the gas guide pipe 205 into two or three sets.

In addition, the diameter of the upper plate 301 of the combustion unit 300 seals the upper portion of the mixing unit 201 of the fuel mixing unit 200, and is inserted into the opened portion of the exterior body 100 to be coupled to the exterior body. It is preferable to be manufactured to a size that can block the opened portion of the (100).

At this time, the diameter of the fuel ejection hole 301a of the upper plate 301 may be manufactured in various sizes according to a user's selection to adjust the amount of fuel gas ejected.

On the other hand, the exterior body 100 is formed so that the center is penetrated along the inner circumference, the through hole 103a through which the electrode pipe 303 of the combustion unit 300 is formed, the air inlet An air guide plate 103 is formed to guide the air supplied through the 101 to move upward through the center portion.

In this case, the air guide plate 103 is formed to be spaced apart from the mixing portion 201 of the fuel mixing portion 200 by a predetermined height to form a space in which air remains, the air inlet hole of the mixing portion 201 ( The remaining air is supplied continuously to 202.

In addition, the air guide plate 103 may be formed in any one of a circular, hemispherical, polygonal shape of the center through which the air flow rate can be adjusted.

Subsequently, the fuel mixing part 200 forms the auxiliary air inlet hole 202a at a predetermined interval spaced in an annular shape on the bottom surface of the mixing part 201, whereby air is supplied through the auxiliary air inlet hole 202a. The gas is supplied vertically into the mixing unit 201 and cross-mixed in the orthogonal direction in the mixing unit 201 to easily mix up and down.

In addition, the combustion unit 300 is spaced at a predetermined interval in an annular shape on the upper surface of the upper plate 301, is formed at a predetermined angle fuel gas guide plate for flowing the fuel gas ejected from the fuel injection hole (301a) in a predetermined direction 305 is formed.

In this case, the fuel gas collided with the fuel gas guide plate 305 and moved in a predetermined direction is preferably ignited by sparks generated from the electrode B and the ignition pin 304 to generate a tornado-shaped flame.

At this time, the tornado flame is ignited as it rotates inward to continuously heat the bottom surface of the food cooking utensil (not shown) in an annular shape, thereby increasing heat transfer efficiency.

In addition, the direction and angle of the fuel gas guide plate 305 may be adjusted in various ways according to the user's selection to control the fire power.

In addition, the combustion unit 300 further includes a diffusion port 306 of a light beam narrowing structure for dispersing the spark ignited on the upper surface of the upper plate 301 to the outside.

At this time, the diffusion port 306 is preferably installed in close proximity to the fuel injection hole (301a) of the upper plate 301 to disperse the spark ignition to the outside, and the diffusion port 306 and the user's choice The upper plate 301 may be formed to have a predetermined height.

In addition, by selecting and manufacturing the angle of the diffuser 306 having an image light narrowing structure, it is possible to control the diffusion angle of the fire dispersed through the diffuser 306.

In addition, the combustion unit 300 is to make the shape of the diffusion port 306 in a circular shape to uniformly distribute the ignition flame to the outside, it is produced to have a variety of shapes according to the user's choice to distribute the flame The direction and amount can be adjusted.

In addition, the combustion unit 300 forms a protrusion 307 at the center of the upper plate 301 to prevent the ignition of the spark is collected in the center.

As described above, gas and air are mixed in the mixing part 201 having a space partitioned by the partition wall 302 of the combustion part 300, and the mixed fuel gas is the electrode rod B and the ignition pin 304. The structure ignited by the ignition by the ignited spark is ejected through the gas ejection hole 205a of the gas guide pipe 205 without being affected by the pressure of the gas and air supplied to the mixing unit 201. The gas is mixed with the air supplied through the air inlet hole 202 of the mixing unit 201 to increase the mixing force, and a predetermined amount of gas and air are rapidly mixed in the partition space inside the mixing unit 201. The mixing time is shortened.

What has been described above is just one embodiment for carrying out the gas burner according to the present invention, the present invention is not limited to the above-described embodiment, without departing from the gist of the invention claimed in the claims below Anyone with ordinary knowledge in the technical field of the present invention will have the technical spirit of the present invention to the extent that various modifications can be made.

100: appearance body 101: air inlet
102: gas inlet 103: air guide plate
103a: through hole 104: hole
200: fuel mixing unit 201: mixing unit
202: air inlet hole 202a: auxiliary air inlet hole
203: electrode piping 204: gas guide tube
205: gas guide pipe 205a: gas ejection hole
300: combustion unit 301: top plate
301a: fuel injection hole 302: partition wall
303: electrode piping 304: ignition pin
305: fuel gas guide plate 306: diffusion hole
307: protrusion B: electrode
P: Piping

Claims (7)

An outer body 100 having an air inlet 101 through which air is introduced into one side thereof with a hollow upper surface and a gas inlet 102 through which gas is supplied to the other side;
A mixing part 201 is inserted into and coupled to the upper part of the exterior body 100 in a hollow shape having an upper surface, and a plurality of air inlet holes 202 spaced apart from each other by a predetermined interval along the outer surface of the mixing part 201. Is formed, at least one electrode pipe hole 203 is formed on the bottom surface of the mixing unit 201, and the gas inlet 102 of the outer body 100 and the bottom of the mixing unit 201 A gas guide tube 204 connected to the pipe P is formed to protrude, and is formed at a predetermined interval spaced annularly in the mixing portion 201 to supply at least one gas supplied through the gas guide tube 204. A fuel mixing part 200 in which a gas guide pipe 205 is ejected into the mixing part 201 through the gas ejection hole 205a; and
The upper plate 301 is provided on the fuel mixing unit 200 in a plate shape to seal the mixing unit 201, and the mixing unit 201 is spaced apart from the upper surface of the upper plate 301 by an annular interval. A plurality of fuel ejection holes 301a through which the fuel gas mixed at the upper part is passed, and partition walls 302 for partitioning the inside of the mixing part 201 are formed in an annular shape on the bottom surface of the upper plate 301. Is formed in a plurality of spaced apart, the upper plate 301 is passed through the electrode pipe hole 203 and the electrode pipe 303 for passing the electrode rod B therein is formed to protrude, the top plate 301 A combustion unit 300 having an ignition pin 304 formed on the upper surface of the electrode bar B exposed through the electrode pipe 303 and spaced apart from each other at a predetermined interval to cause sparks;
Gas burner, characterized in that consisting of. The method of claim 1,
The exterior body 100 is formed so that the center penetrates along the inner circumference thereof, and a through hole 103a through which the electrode pipe 303 of the combustion unit 300 passes is formed on the upper surface thereof, and the air inlet 101 is formed. Gas burner, characterized in that the air guide plate 103 for guiding the air supplied through the upper portion is moved through the center. The method of claim 1,
The fuel mixing unit 200 is a gas burner, characterized in that the auxiliary air inlet hole (202a) is formed on the bottom surface of the mixing unit 201 spaced apart annularly. The method of claim 1,
The fuel mixing unit 200 is a gas burner, characterized in that the gas guide pipe 205 is formed to have a radial shape from the bottom of the mixing unit 201 to the top. The method of claim 1,
The fuel mixing unit (200) is a gas burner, characterized in that the gas ejection hole (205a) of the gas guide pipe (205) for ejecting the supplied gas to the mixing unit 201 is penetrated in the annular direction. The method of claim 1,
The combustion unit 300 is spaced in the annular interval on the upper surface of the upper plate 301, the fuel gas guide plate 305 is formed at a predetermined angle to flow the fuel gas ejected from the fuel injection hole (301a) in a predetermined direction Gas burner, characterized in that is formed. The method of claim 1,
The combustion unit (300) is a gas burner, characterized in that further comprises a diffusion port (306) of the upper and lower narrow structure to disperse the spark ignited on the upper surface of the upper plate (301) to the outside.

Images