KR20240145696A - Stove with double jet - Google Patents

Abstract

The present invention relates to a stove having a dual burner, and more specifically, to a stove having a dual burner in which the burners are separated from each other in a concentric circle and individually controlled, so that not only the overall firepower can be controlled, but also the flame ejection area can be appropriately controlled to suit the size of the heating vessel.

Description

Stove with double jet

The present invention relates to a stove having a dual burner, and more specifically, to a stove having a dual burner in which the burners are each individually controlled and partitioned in a concentric circle, so that not only the overall firepower can be controlled, but also the flame ejection area can be appropriately controlled to suit the size of the heating vessel.

Portable stoves are mostly so-called gas stoves that use liquefied butane gas as fuel, usually filled in a disposable metal can.

For example, Republic of Korea Utility Model Registration No. 20-0268993 discloses a 'portable burner stove device, hereinafter referred to as 'prior art'.

To briefly introduce it, the above-described prior art is configured to include a burner part (10) that generates combustion heat by gas ignition in the central upper portion of the main body (5), a plurality of supports (20) installed on the outside of the burner part (10), an adapter (31) equipped with a gas control valve (4) that controls the supply amount of gas supplied from a gas container (300), a connecting hose (3) that connects the main body (5) and the adapter (31), a sparker (50) that ignites the gas supplied from the gas container (300) to the burner part (10) when a piezoelectric switch (32) is operated, a fixed cap (60) and a diffusion net (80) that diffuse the combustion heat generated in the burner part (10), and a heating net (90) that is heated by the combustion heat diffused through the diffusion net (80).

However, these conventional portable stoves have a structure in which the flame that is generated when air and gas are mixed and combusted in the burner part (10) is simply diffused through the fixed cap (60), diffusion net (80), and heating net (90) to generate heat, so there is a problem in that the flame does not rise evenly, resulting in significantly lower combustion efficiency and heating performance.

In addition, since only the intensity of the flame can be controlled, there are various restrictions on controlling the flame eruption range due to the compact structure suitable for portability. Accordingly, when heating a relatively large container, even if the flame is maximized, the heating area is narrow and the heating efficiency is low. On the other hand, when heating a small container, the flame cannot be concentrated, so there was a problem of low heating efficiency.

The present invention has been created to solve the above-mentioned problems of the prior art, and the purpose of the present invention is to provide a stove having dual burners, each of which is divided into two burners on a concentric circle and controlled individually, so that not only the overall firepower can be controlled, but also the flame ejection area can be appropriately controlled to suit the size of the heating container.

The present invention is characterized by including a means for achieving the above object, which comprises: a first crater part that spews out flames; a second crater part that spews out flames at a position offset by a predetermined distance from the first crater part with the first crater part at the center; a gasket that shields a space between the first crater part and the second crater part; a gas supply part that is respectively connected to the first crater part and the second crater part and individually supplies gas to the first crater part and the second crater part; and an ignition part that is installed around the first crater part and the second crater part and applies a spark to the gas discharged from the first crater part and the second crater part to ignite it.

In addition, the first crater section is connected to the gas supply section and has a first supply cylinder that forms a gas passage inside in a hollow shape; is installed on the upper part of the first supply cylinder and forms a concave groove around the open upper part of the first supply cylinder and has a " " A fan including a bending member bent into a shape of a letter "A" and a settling member extending a certain length in a horizontal direction from an end of the bending member; and a cap member covered with the upper part of the fan, the edge of which is supported by being settling on the settling member, and having a first gas outlet for discharging gas formed therethrough at a point where it contacts the bending member; wherein the second crater section includes a second supply cylinder connected to the gas supply section and forming a gas passage therein in a hollow shape; and a discharge section installed on the upper part of the second supply cylinder and having a hollow circular ring shape surrounding the first crater section and having a second gas outlet for discharging gas formed therethrough on the upper surface thereof.

In addition, the gas supply unit is characterized by including: a first control valve for controlling the amount of gas directed to the first supply cylinder; a first connecting pipe connecting the first supply cylinder and the first control valve; a second control valve for controlling the amount of gas directed to the second supply cylinder; a second connecting pipe connecting the second supply cylinder and the second control valve; an adapter mounted on a nozzle of a gas container; a supply pipe extending from the adapter; a three-way connector having an input port directly connected to the supply pipe so as to distribute and supply gas supplied from the supply pipe to the first control valve and the second control valve, and a first output port and a second output port directed toward the first control valve and the second control valve; a first branch pipe connecting the first output port and the first control valve; and a second branch pipe connecting the second output port and the second control valve.

In addition, the gasket is characterized by having a circular thin plate structure, a central hole formed in the center through which the first supply cylinder passes, a ventilation hole formed at a certain distance eccentrically from the central hole, and being fixedly installed directly below the fan.

In addition, the gasket is characterized in that a pipe guide hole is formed penetrating at a corresponding point of the space, one end of the first connecting pipe is connected to the first control valve, the other end is connected to the bottom of the first supply cylinder, and a portion of the section between the one end and the other end has a first bend portion that is bent multiple times so as to pass through the pipe guide hole and be positioned around the first gas outlet, so that the first bend portion is directly exposed to a flame ignited around the first gas outlet, and one end of the second connecting pipe is connected to the second control valve, the other end is connected to the bottom of the second supply cylinder, and a portion of the section between the one end and the other end has a second bend portion that is bent multiple times so as to pass through the pipe guide hole and be positioned around the second gas outlet, so that the second bend portion is directly exposed to a flame ignited around the second gas outlet, so that the gas moving through the first connecting pipe and the second connecting pipe is preheated.

The present invention provides the advantageous effect of being able to control not only the overall firepower but also the flame ejection area appropriately according to the size of the heating vessel by individually controlling each of the two fire ports divided into concentric circles.

FIG. 1 is a drawing showing the overall configuration of a stove having a dual burner according to the present invention.
Figure 2 is a drawing illustrating the planar configuration of Figure 1.
Figure 3 is a drawing illustrating an embodiment in which legs are combined.
Figures 4 to 6 are drawings showing the exploded configuration of a main part of a stove having a dual burner according to the present invention.
Figure 7 is a drawing showing the bottom surface of Figure 4.
Figure 8 is a drawing showing the disassembled configuration of the first crater section.
Figure 9 is a drawing showing the second crater section.
Figure 10 is a drawing showing the disassembled configuration of the first crater section, the second crater section, and the gasket.
Figure 11 is a drawing showing the cross-sectional configuration of the first crater section, the second crater section, and the gasket.
Figure 12 is a conceptual drawing illustrating the process in which the first connecting pipe is preheated by the first crater.
Figure 13 is a conceptual drawing illustrating the process in which the second connecting pipe is preheated by the second crater.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to more completely explain the present invention to those with average knowledge in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer explanation. It should be noted that in each drawing, the same parts are sometimes illustrated with the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention are omitted.

A stove having a dual burner according to the present invention (hereinafter referred to as a stove) can be broadly defined as including a first burner section (20), a second burner section (30), a gas supply section (60), an ignition section (50), and a main body (10).

First, the main body (10) constitutes the overall appearance of the stove and is a cylindrical housing structure with an open top surface, which is designed to support the main components of the stove in the appropriate locations.

The side of the main body (10) can be configured with a structure in which a number of holes are perforated to allow heat dissipation, and a stand (11) for supporting a container to be heated can be installed on the upper surface.

The first crater part (20), the second crater part (30), the ignition part (50), etc. can be exposed and configured in the open upper center of the main body (10), and the gas supply part (60) can be safely installed in the lower part thereof.

In some cases, the legs (12) may be extended and connected to the lower part of the main body (10) so that the main body (10) can be used while being spaced at a certain height from the ground, and a handle (13) may be connected to the outside of the main body (10) to increase portability.

Next, the first crater section (20) and the second crater section (30) are configured to emit flames and are linked to the ignition section (50) and gas supply section (60) to be described later so that the flames can be controlled independently of each other.

First, the first crater (20) is positioned at the exact center of the main body (10) and is responsible for emitting flames centered on the exact center of the container placed on the stand (11).

More specifically, the first crater section (20) can be broadly exemplified as including a first supply cylinder (21), a fan (22), and a cap member (23).

The first supply cylinder (21) may be formed as a pipe structure with a vertically long hollow shape forming a gas passage inside.

The lower part of the first supply cylinder (21) is connected to the gas supply unit (60) and receives gas through an internal gas passage. This gas is discharged to the upper part of the first supply cylinder (21), but the discharged gas can be ignited at the fan (22) and the cap member (23).

The lower part of the first supply cylinder (21) can support the fan (22) and the cap member (23) at a certain height from the inside of the main body (10) while being supported and secured inside the main body (10).

The fan (22) is a disc-shaped configuration having a predetermined area and is installed on the upper part of the first supply cylinder (21). It forms a concave groove (22a) around the open upper part of the first supply cylinder (21) and has a " " It can be formed as a structure in which a bending member (22b) bent in the shape of a letter and a settling member (22c) extending a certain length in the horizontal direction from an end of the bending member (22b) are formed in succession.

The cap (23) is covered with the upper part of the open fan (22) to close not only the fan (22) but also the upper part of the first supply cylinder (21) that is open through the center of the fan (22), while the edge part has a predetermined bending structure so as to be aligned with the bending member (22b) but have a small gap between it and the bending member (22b), and the outermost edge part can be supported by being fixedly fixed on the mounting member (22c) of the fan (22).

In addition, a structure is provided in which a first gas discharge port (23a) for discharging gas is formed through a bending portion (22b) of the edge portion of the hat (23) to contact the point.

According to this structure, when gas is supplied to the first supply cylinder (21), the supplied gas is discharged from the upper portion of the first supply cylinder (21), and since a cap member (23) is spaced apart from the upper portion of the first supply cylinder (21), the discharged gas is radially spread out in the space between the fan (22) and the cap member (23) by the cap member (23) and is charged into a concave groove (22a), and then, the gas charged into the groove (22a) is introduced into the small gap between the bending member (22b) of the fan (22) and the cap member (23) and is then discharged through the first gas discharge port (23a) of the cap member (23) and can be ignited as a flame.

Next, the second crater part (30) is arranged at a distance around the first crater part (20) which is arranged at the exact center of the main body (10) and plays a role in ejecting secondary flames around the flame of the first crater part (20).

That is, the second crater section (30) individually ejects a flame that is separate from the flame provided by the first crater section (20) at a position offset by a certain distance to the outside of the first crater section (20) with the first crater section (20) at the center, thereby expanding the flame ejection area of the stove.

For this purpose, the second crater (30) can be exemplified as including a second supply cylinder (31) and a discharge port (32).

The second supply cylinder (31) is connected to the gas supply unit (60) and has a hollow shape to form a gas passage inside.

That is, the second supply cylinder (31) is configured to perform the same function as the first supply cylinder (21) of the first crater section (20) described above, and the lower part of the second supply cylinder (31) is connected to the gas supply section (60) to receive gas through an internal gas passage, and this gas is discharged to the upper part of the second supply cylinder (31), but the discharged gas can be ignited in the discharge port (32).

The lower part of the second supply cylinder (31) can support the discharge plate (32) at a certain height from the inside of the main body (10) while being supported and secured inside the main body (10).

The discharge port (32) is formed in the shape of a hollow circular ring surrounding the first crater (20) and can be installed on the upper part of the second supply cylinder (31) so as to be in communication with the interior of the second supply cylinder (31).

The gas supplied to the second supply cylinder (31) flows into the discharge port (32) to form a sealed configuration, while the second gas discharge port (32a) for discharging the gas is formed at equal intervals along the circumference on the upper surface of the discharge port (32) so that the flame can be ignited in a shape corresponding to the discharge port (32) having a circular ring shape.

Meanwhile, there is a concern that a certain space may be created between the first crater part (20) and the second crater part (30) due to the structure in which the first crater part (20) and the second crater part (30) are arranged concentrically. If this space is not properly shielded, foreign substances such as food may easily enter the main body (10) during use of the stove.

Therefore, the gap between the first crater (20) and the second crater (30) is appropriately shielded with a gasket (40) to enable cleaner use.

More specifically, the gasket (40) is a circular thin plate structure with a central hole (41) formed in the center through which the first supply cylinder (21) passes.

That is, the gasket (40) can be fixedly installed directly below the fan (22) of the first crater (20) while being mounted outside the first supply cylinder (21), and at this time, the gasket (40) can be expanded to the inner edge of the discharge port (32) of the second crater (30) so as to partition the separation space vertically.

Accordingly, even if a foreign substance falls from the upper part of the main body (10) toward the separation space, it can be blocked by the gasket (40) and its inflow to the lower part of the main body (10) can be restricted.

In addition, in order to facilitate the air flow around the first gas outlet (23a) and the second gas outlet (32a) in consideration of combustion efficiency, the gasket (40) is formed with a ventilation hole (42) at a certain distance eccentric from the center hole (41), but the number, penetration area, and arrangement of the ventilation holes (42) are restricted so as to prevent the passage of foreign substances.

Next, the ignition unit (50) is installed around the first crater unit (20) and the second crater unit (30) and is configured to ignite the gas discharged from the first crater unit (20) and the second crater unit (30) by applying a spark, thereby enabling the ignition of the first crater unit (20) and the second crater unit (30) to be individually controlled.

For example, the ignition unit (50) may be exemplified as including a first ignition plug (51) installed spaced apart from the outside of the cap member (23), a first ignition switch (52) connected to the first ignition plug (51) but positioned outside the main body (10) to control the operation of the first ignition plug (51), a second ignition plug (53) installed spaced apart from the outside of the discharge port (32), and a second ignition switch (54) connected to the second ignition plug (53) but positioned outside the main body (10) to control the operation of the second ignition plug (53).

Accordingly, by individually operating the first ignition switch (52) and the second ignition switch (54) provided outside the main body (10), the ignition of the first ignition part (20) and the second ignition part (30) can be individually controlled, and for example, depending on the situation, at least one of the first ignition part (20) and the second ignition part (30) can be activated, or both can be activated to enable cooking with maximum heat.

Since the ignition unit (50) can utilize the structure of an ignition means used in a general gas stove, a detailed description thereof is omitted below.

Next, the gas supply unit (60) is configured to supply gas from the gas container (G) to the first crater unit (20) and the second crater unit (30). It is connected to the first crater unit (20) and the second crater unit (30), respectively, and serves to individually supply gas to the first crater unit (20) and the second crater unit (30).

As with the ignition unit (50) described above, the gas supply unit (60) is also structured to selectively supply gas to the first crater unit (20) and the second crater unit (30) so that when one of the craters is not in use, the gas supply to the unused crater unit can be cut off.

More specifically, the gas supply unit (60) can be broadly exemplified as including a first control valve (64), a first connecting pipe (68), a second control valve (65), a second connecting pipe (69), an adapter (61), a supply pipe (62), a three-way connector (63), a first branch pipe (66), and a second branch pipe (67).

First, the adapter (61) is a configuration mounted on the nozzle of the gas container (G) and performs the function of supplying compressed gas fuel stored in the gas container (G) to the supply pipe (62) at a constant pressure.

On one side of the adapter (61), an inlet port is formed to allow gas flowing out from the nozzle to pass through, and a supply pipe (62) can be connected to the other side.

In some cases, the adapter (61) may be equipped with a knob to control the amount of gas supplied.

In this case, the knob can be configured to have an opening/closing operation structure that widens or narrows the internal passage of the adapter (61) by rotating the amount of gas fuel supplied from the gas container (G) to the adapter (61).

The supply pipe (62) is configured to extend from the adapter (61) and be directly connected to the three-way connector (63), and forms a conduit that transfers gas supplied from the adapter (61) to the three-way connector (63).

The supply pipe (62) may be configured to have a predetermined length so that the gas container (G) can be placed sufficiently away from the main body (10), and may be covered with a metallic coating so as to be protected from damage from heat or external stimuli.

Next, the three-way connector (63) is configured to be connected to the supply pipe (62) and to distribute and supply gas supplied from the supply pipe (62) to the first control valve (64) and the second control valve (65), and may be structured to have an input port (63a) directly connected to the supply pipe (62), and a first output port (63b) and a second output port (63c) directed toward the first control valve (64) and the second control valve (65).

The first crater part (20) is connected to the first output port (63b), and the second crater part (30) is connected to the second output port (63c), so that gas flowing into the interior of the three-way connector (63) can be distributed and supplied to the first crater part (20) and the second crater part (30) connected to the first output port (63b) and the second output port (63c).

The three-way connector (63) can be fixedly installed at the bottom of the main body (10), but its installation location is not particularly restricted.

Next, the first control valve (64) and the second control valve (65) are configured to control the amount of gas directed to the first supply cylinder (21) and the second supply cylinder (31), respectively, and can control and maintain the supply amount or pressure of gas at a certain level.

The first control valve (64) and the second control valve (65) have the same structure, and for example, the first control valve (64) and the second control valve (65) may be provided with a first knob (64a) and a second knob (65a) that control the amount of gas fuel supplied by widening or narrowing the internal passage of the valve body through rotational operation.

The first knob (64a) and the second knob (65a) are arranged to extend long beyond the main body (10) to enable easy operation by the user.

By rotating the first knob (64a) and the second knob (65a), the opening amount of the first control valve (64) and the second control valve (65) can be adjusted, and in some cases, the first control valve (64) and the second control valve (65) can be completely blocked so that gas does not pass through.

The first branch pipe (66) and the second branch pipe (67) are pipe configurations that connect the first output port (63b) and the first control valve (64), and the second output port (63c) and the second control valve (65), respectively.

The second connecting pipe (69) and the second connecting pipe (69) are pipe configurations that connect the first supply cylinder (21) and the first control valve (64), and the second supply cylinder (31) and the second control valve (65), respectively.

According to this connection system, gas fuel provided from a gas container (G) can be injected into the first supply cylinder (21) and the second supply cylinder (31) through an adapter (61), a supply pipe (62), a three-way connector (63), first and second branch pipes (66, 67), first and second control valves (64, 68), and first and second connection pipes (68, 69).

Meanwhile, the gas commonly used as fuel for stoves is petroleum butane gas, which liquefies when pressurized to about 5 atm at room temperature, and is stored in a sealed container such as a can. In addition, the physical properties of butane gas itself are high in boiling point and low in vapor pressure, so there is a problem that the ignition power decreases at sub-zero temperatures.

That is, the liquefied gas stored in the can becomes liquid and changes into gas to generate fire power, but if the surrounding temperature is low, the leaked gas cannot change phase into gas, which reduces combustion efficiency. In addition, since the liquid butane inside the can takes away heat from the surroundings when it vaporizes, the temperature of the can continues to drop, and when it approaches the freezing point of butane gas during combustion, there is a problem that the fire power weakens because the liquid gas cannot vaporize properly.

In other words, there is no particular problem when using the stove in the summer, but when using it outdoors in the winter, combustion efficiency is significantly reduced, so it is necessary to insulate the gas by some means.

Accordingly, in this embodiment, a structure is provided in which the pipes through which gas moves, particularly the first connecting pipe (68) and the second connecting pipe (69), are directly exposed to the flames of the first crater (20) and the second crater (30), so that the gas passing through the first connecting pipe (68) and the second connecting pipe (69) is naturally preheated.

To this end, a pipe guide hole (43) is formed through the gasket (40) at a corresponding point in the space, and the first connecting pipe (68) and the second connecting pipe (69) wired to the lower part of the main body (10) are configured to extend to a certain height above the first crater section (20) and the second crater section (30) through the pipe guide hole (43).

More specifically, one end of the first connecting pipe (68) is connected to the first control valve (64) and the other end is connected to the bottom of the first supply cylinder (21), and a portion of the section between the one end and the other end is structured to have a first bent portion (68a) that is bent multiple times so as to pass through the pipe guide hole (43) and be located around the first gas discharge port (23a).

That is, while one end and the other end of the first connecting pipe (68) are positioned at the lower part of the main body (10), the first bent portion (68a) is exposed and extended above the first crater part (20) and can be positioned around the first gas outlet (23a). Accordingly, when the first crater part (20) is ignited, the first bent portion (68a) is naturally structured to be directly exposed to the flame ignited around the first gas outlet (23a) of the first crater part (20). Therefore, the gas moving through the first connecting pipe (68) can be supplied to the first crater part (20) in a state where it has been preheated to a predetermined temperature.

Likewise, one end of the second connecting pipe (69) is connected to the second control valve (65), the other end is connected to the bottom of the second supply cylinder (31), and a portion of the section between the one end and the other end has a structure in which a second bent portion (69a) is bent multiple times so as to pass through the pipe guide hole (43) and be located around the second gas discharge port (32a).

That is, while one end and the other end of the second connecting pipe (69) are positioned at the bottom of the main body (10), the second bent portion (69a) is extended to be exposed above the second crater (30) and can be positioned around the second gas outlet (32a). Accordingly, when the second crater (30) is ignited, the second bent portion (69a) is naturally structured to be directly exposed to the flame ignited around the second gas outlet (32a) of the second crater (30). Therefore, the gas moving through the second connecting pipe (69) can be supplied to the second crater (30) in a state where it has been preheated to a predetermined temperature.

Meanwhile, since the first bend portion (68a) of the first connecting pipe (68) is exposed to the flame of the first crater section (20) and the second bend portion (69a) of the second connecting pipe (69) is individually exposed to the flame of the second crater section (30), a safety structure can be provided in which gas supplied toward the unused crater section when the first crater section (20) or the second crater section (30) is not used is not unnecessarily preheated.

In addition, the first connecting pipe and the second connecting pipe may be made of a heat-resistant metal material that is not damaged by flame but has heat-conducting properties.

In summary, the stove according to the present invention not only maximizes energy efficiency by preheating gas fuel using heat energy from flames that are naturally generated when the stove is used, thereby eliminating additional energy supply for gas preheating, but also provides the advantageous effect of allowing use in harsh outdoor environments in winter by increasing gas vaporization efficiency even at low temperatures.

The embodiments of the present invention described above are merely exemplary, and those skilled in the art will readily appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, it will be readily understood that the present invention is not limited to the forms mentioned in the detailed description above. Accordingly, the true technical protection scope of the present invention should be determined by the technical idea of the appended claims. In addition, the present invention should be understood to include all modifications, equivalents, and substitutes within the spirit and scope of the present invention defined by the appended claims.

10: Body
20: Crater 1
30: Crater 2
40: Gasket
50: Ignition
60: Gas supply department

Claims (5)

The first crater spews flames;
A second crater that spews flames at a location offset a certain distance from the periphery of the first crater, with the first crater at the center;
A gasket that shields the space between the first crater and the second crater;
A gas supply unit that is connected to the first crater section and the second crater section respectively and supplies gas to the first crater section and the second crater section separately; and
A stove having a double burner, characterized by including an ignition unit installed around the first burner and the second burner to ignite gas discharged from the first burner and the second burner by applying a spark. In claim 1,
The above first crater section is,
A first supply cylinder connected to the above gas supply unit and having a hollow shape to form a gas passage inside;
It is installed on the upper part of the first supply cylinder and forms a concave groove around the open upper part of the first supply cylinder and has a " " A fan in which a bending member bent in the shape of a letter and a settling member extending a certain length in the horizontal direction from an end of the bending member are formed in succession; and
A cap member is formed by covering the upper part of the fan with a rim portion that is supported by the mounting base and a first gas discharge port for discharging gas is formed through a point that contacts the bending base;
The above second crater section is,
A second supply cylinder connected to the above gas supply unit and forming a gas passage inside in a hollow shape; and
A stove with a double burner, characterized by including a discharge plate having an empty circular ring shape inside, which is installed on the upper part of the second supply cylinder and surrounds the first burner section, and having a second gas discharge port formed through the upper surface for discharging gas. In claim 2,
The above gas supply unit,
A first control valve for controlling the amount of gas directed to the first supply cylinder;
A first connecting pipe connecting the first supply cylinder and the first control valve;
A second control valve for controlling the amount of gas directed to the second supply cylinder;
A second connecting pipe connecting the second supply cylinder and the second control valve;
An adapter that mounts to the nozzle of a gas cylinder;
A supply pipe formed as an extension from the above adapter;
A three-way connector having an input port directly connected to the supply pipe so as to distribute gas supplied from the supply pipe to the first control valve and the second control valve, and a first output port and a second output port directed toward the first control valve and the second control valve;
A first branch pipe connecting the first output port and the first control valve; and
A stove having a dual burner, characterized by including a second branch pipe connecting the second output port and the second control valve. In claim 3,
A stove with a double burner, characterized in that the gasket has a circular thin plate structure, a central hole formed in the center through which the first supply cylinder passes, a ventilation hole formed at a certain distance eccentrically from the central hole, and is fixedly installed directly below the fan. In claim 4,
In the above gasket, a pipe guide hole is formed through the corresponding point of the above space.
One end of the above first connecting pipe is connected to the first control valve, the other end is connected to the bottom of the first supply cylinder, and a portion of the section between the one end and the other end has a first bend portion that is bent multiple times so as to pass through the pipe guide hole and be located around the first gas outlet, so that the first bend portion is directly exposed to the flame ignited around the first gas outlet.
A stove with a dual burner, characterized in that one end of the second connecting pipe is connected to the second control valve, the other end is connected to the bottom of the second supply cylinder, and a portion of the pipe between the one end and the other end has a second bent portion that is bent multiple times so as to pass through the pipe guide hole and be located around the second gas outlet, so that the second bent portion is directly exposed to a flame ignited around the second gas outlet, thereby preheating the gas moving through the first connecting pipe and the second connecting pipe.