KR200465440Y1 - Burner device having ceramics head - Google Patents

Abstract

A burner device having a ceramic head is disclosed. Burner device having a ceramic head of the present invention is a burner device having a ceramic head of the indirect heating type to heat the cooking vessel or food with radiant heat generated by heating the ceramic,
A mixing tube having a gas and air mixing chamber having an upper opening; A gas injection pipe coupled to one side wall of the mixing pipe so that one end of the gas and air mixing chamber communicates with the gas and air mixing chamber; Porous ceramic head disposed on the upper side of the mixing tube; And an ignition electrode line extending from an edge of one side of the ceramic head toward a central portion of the upper surface of the ceramic head, and an ignition plug provided in proximity to the ignition electrode line to ignite a gas passing through the ceramic head. .

Description

Burner device with ceramic head {BURNER DEVICE HAVING CERAMICS HEAD}

The present invention relates to a burner device having a ceramic head, and more particularly, to a burner device having a ceramic head with improved stability and easy manufacturing.

In general, a burner device having a ceramic head is designed to burn a gas to heat the ceramic. When the ceramic is heated to about 900 ° C. by burning the gas, the ceramic is heated red and infrared radiation is generated. The infrared radiation causes the food or cooking vessel to be heated.

As described above, the burner device having the ceramic head has a different heating principle from that of the general burner device.

That is, the general combustion type burner device directly burns gas and heats food or cooking vessels by its heat, and thus does not go through an intermediate energy conversion procedure, so the larger the flame, the faster the heating.

On the other hand, the burner device having a ceramic head is indirectly heated and is not affected by wind and rain since no spark is generated. In addition, since flame is not generated, high safety and high efficiency are provided, and an energy saving effect of about 30% is obtained compared to the direct combustion type. Since no flame is generated, there is no burning of the cooking vessel and no gas refrigerant is generated. Thus, the burner apparatus of the radiant heat indirect heating type which has a ceramic head is a very practical cookware.

However, the burner apparatus of the radiant heat indirect heating method having the ceramic head according to the related art has the following problems.

That is, the burner device according to the prior art is configured to inject gas into the mixing tube and the two ignition parts by using two gas conduits, which increases the processing process of the mixing tube, makes processing difficult, and increases the cost. there was. In addition, the consumption of the gas is relatively high, there is a problem that frequently causes poor ignition problems during use.

The technical problem of the present invention is to solve the problems of the ceramic burner device according to the prior art, and can be easily ignited, the gas supply structure is simple, the mixing ratio of air is good and the concentration of carbon monoxide and carbon dioxide It is to provide a means to lower.

The technical problem to be achieved by the present invention is not limited to the technical problem mentioned above, and other technical problems not mentioned above may be clearly understood by those skilled in the art from the following description. There will be.

The technical problem is, according to the present invention, a burner device having a ceramic head of the indirect heating type to heat the cooking vessel or food with radiant heat generated by heating the ceramic,

A mixing tube having a gas and air mixing chamber having an upper opening;

A gas injection pipe coupled to one side wall of the mixing pipe so that one end of the gas and air mixing chamber communicates with the gas and air mixing chamber;

Porous ceramic head disposed on the upper side of the mixing tube; And

And an ignition electrode line extending from one edge of the ceramic head to an upper surface center portion, and an auto-ignition device including an ignition plug installed in close proximity to the ignition electrode line to ignite the gas passing through the ceramic head. Achieved by a burner device having a head.

The ceramic head,

It is characterized in that it is coupled to the mixing tube by the inner ceramic fixing ring and the outer ceramic fixing ring.

The ignition electrode line,

It is characterized by consisting of a nickel-chromium alloy.

In the connection region of the gas injection tube and the gas and air mixing chamber, a gas induction for forming an air induction passage so that the gas supplied from the gas injection tube is spirally moved inside the gas and air mixing chamber and mixed with air. It is characterized in that the bracket is provided.

The gas induction bracket,

A gas induction bracket fixing part fixed to the bottom of the gas and air mixing chamber; And

A portion of the gas and air mixing chamber is divided vertically and extended vertically from the gas induction bracket fixing portion to form an air induction passage, and then bent horizontally so as to be in close contact with the inner wall of the gas and air mixing chamber. It is characterized by consisting of a guide plate is formed.

At the center of the mixing tube is provided with a column formed through the air passage in the vertical direction,

In the center of the ceramic head is formed an air hole corresponding to the air passage,

The gas from the ceramic head is characterized in that the air in the lower portion of the mixing tube is supplied to the ceramic head when burning.

The air passage is characterized in that the lower diameter is formed larger than the upper diameter.

The gas injection tube is characterized in that the diameter is formed closer to the mixing tube.

According to the present invention, since a single gas and air mixing chamber is provided and a single gas injection passage is provided, the structure is simple, and since the ignition electrode line is disposed on the upper surface of the porous ceramic head, the ignition can be easily performed. You can do it. In addition, the mixing ratio of air and gas is improved by the air induction passage to significantly reduce the amount of carbon monoxide or carbon dioxide generated, and in particular, since the air is sufficiently supplied by the air passage formed in the center, complete combustion can be achieved.

1 is a perspective view showing a burner device having a ceramic head according to the present invention.
2 is an exploded perspective view showing the burner device shown in FIG.
3 is a cross-sectional view of the burner device shown in FIG.
4 is a schematic plan view of the gas and air flow in the mixing tube shown in FIG.
FIG. 5 is a schematic perspective view of gas and air flow in the mixing tube shown in FIG. 2; FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, a description of known functions or configurations will be omitted for the sake of clarity of the present invention.

1 is a perspective view showing a burner device having a ceramic head according to the present invention, Figure 2 is an exploded perspective view showing the burner device shown in Figure 1, Figure 3 is a cross-sectional view of the burner device shown in FIG. 4 and 5 are schematic plan views and perspective views showing gas and air flow in the mixing tube shown in FIG. 2.

1 to 5, the burner device having a ceramic head is an indirect heating type burner device for heating a cooking vessel or food with radiant heat generated by heating the ceramic.

The burner device is coupled to one side wall of the mixing tube 10 so that one end of the mixing tube 10 and the gas and air mixing chamber 11 having an upper opening are in communication with the gas and air mixing chamber 11. The gas injection pipe 12, the porous ceramic head 3 disposed on the upper side of the mixing tube 10, the ignition electrode line 6 extending from one edge of the ceramic head 3 toward the center of the upper surface and the ignition It is composed of an automatic ignition device which is provided in close proximity to the electrode wire 6 and consists of a spark plug 5 for igniting the gas passing through the ceramic head 3.

More specifically, it is as follows.

The mixing tube 10 has a cylindrical shape with an upper opening as shown in FIGS. 1, 2, and 3. A pillar 13 protrudes from the center in the vertical direction, and an air passage 14 penetrates through the pillar 13. Therefore, the gas and air mixing chamber 11 is formed between the pillar 13 and the inner wall. The mixing tube 10 is made of metal. At this time, the air passage 14 has a lower inner diameter than the upper inner diameter is formed larger. This is to allow the air on the lower side to move upwards easily and quickly by the chimney phenomenon.

On the other hand, one end of the gas injection pipe 12 is coupled through the one side wall of the mixing pipe (10). Therefore, gas and air supplied through the gas injection pipe 12 flow into the gas and air mixing chamber 11. The gas injection pipe 12 is formed to have a smaller diameter from one end to the mixing pipe 10 side. This is to increase the flow rate of the gas and air to be supplied, the suction pressure is generated by the negative pressure phenomenon that the pressure is lowered to facilitate the flow of gas and air.

In addition, the ceramic head 3 is formed in a honeycomb structure so that a gas mixed with gas and air passes therethrough, and as illustrated in FIGS. 1 to 3, air holes are formed through the center and have a constant thickness. It has a donut shape. This ceramic head 3 is installed on the upper side of the mixing tube 10. At this time, the upper portion of the air passage 14 is fitted into the air hole, and the outer circumferential surface of the ceramic head 3 is fitted to the upper portion of the gas and air mixing chamber 11. In this state, the inner ceramic fixing ring 1 and the outer ceramic fixing ring 2 are firmly coupled to the mixing tube 10 without a gap.

At this time, the ceramic head 3 is supported by the pillar 13 and fixed, so that the ceramic head 3 does not flow down.

The ignition electrode line 6 of the automatic ignition apparatus is made of nickel-chromium alloy, and is a component for igniting gas together with the ignition plug 5. One end of the ignition electrode line 6 is coupled to the mixing tube 10, and the other end is bent from one edge of the ceramic head 3 toward the center of the upper surface. That is, the other end of the ignition electrode line 6 is bent so as to extend toward the center of the upper surface of the ceramic head 3 so as to be located in the gas ejection holes of the ceramic head 3. At this time, the ignition electrode line 6 is installed in a bent shape in a "으로" shape, and is installed in close contact with the upper surface of the ceramic head (3). This is to facilitate easy spacing and spark generation with the electrode of the spark plug 5, thereby to facilitate the ignition of the gas.

In addition, one side of the spark plug 5 is provided on the switch handle side, and the electrode is provided so as to maintain a predetermined distance from the ignition electrode line 6. Since the spark plug 5 is well known, its detailed description is omitted.

On the other hand, in the connection region between the gas injection tube 12 and the gas and air mixing chamber 11, the gas supplied from the gas injection tube 12 is centered on the air passage 14 inside the gas and air mixing chamber 11. A gas induction bracket 4 having a guide plate 15 for forming an air induction passage 16 to be mixed with air while being spirally moved is provided.

This gas induction bracket 4 is a gas fixed to the bottom of the gas and air mixing chamber 11 in the gas injection pipe 12 and the gas and air mixing chamber 11 connection region as shown in FIGS. 2 and 3. The gas guide bracket high so as to form an air induction passage 16 for guiding gas and air in only one direction while dividing the induction bracket fixing part 9 and a part of the gas and air mixing chamber 11 into upper and lower parts. It is composed of an induction plate 15 which is formed to be bent and extended horizontally so as to be in close contact with the inner wall of the gas and air mixing chamber 11 after being extended vertically from the government section 9. At this time, one side of the guide plate 15 is preferably formed in a curved surface to be in close contact with the inner wall of the gas and air mixing chamber 11, the horizontal area height of the guide plate 15 and the outlet of the gas injection pipe 12 and It is preferred that they are formed equal or slightly higher. The space is formed between the horizontal region of the guide plate 15 and the bottom of the ceramic head 3 to supply the ceramic head 3 with a mixture of air and gas spirally moved by the air induction passage 16. It is to make it possible.

Hereinafter, the operation of the present invention will be described.

As shown in FIGS. 3 to 5, gas and air are supplied to the mixing tube 10 through the gas injection tube 12.

At this time, since the diameter of a portion of the gas injection pipe 12 adjacent to the mixing pipe 10 is small, suction force is generated due to a negative pressure phenomenon that the flow of gas and air passing through the gas injection pipe 12 is faster and the pressure is lowered. Gas and air flow smoothly.

In this process, the gas and air supplied to the mixing pipe 10 are guided to the guide plate 15 of the gas induction bracket 4, and spirally move around the column 13 along the air induction path 16. Are mixed. That is, the gas and air introduced into the mixing tube 10 by the gas injection tube 12 are moved in one direction only by the air induction passage 16 formed by the guide plate 15 to rotate in a helical manner, and the upper ceramic It is a structure supplied to the head (3).

This will be described in more detail as follows.

The gas supplied through the gas injection pipe 12 flows into the mixing pipe 10 along the air induction passage 16 formed by the guide plate 15.

At this time, the air induction passage 16 is connected to the gas inlet pipe 12 having a narrow area and has a structure that expands to a large area in a narrow area as a whole.

In addition, the gas and air introduced into the air induction passage 16 through the gas injection tube 12 have a narrow boundary region between the gas injection tube 12 and the air induction passage 16, so that the flow velocity is increased and the pressure is increased. The suction force is generated due to the negative pressure phenomenon, which makes the flow smooth. However, the gas and the air flowing into the air induction passage 16 at a high flow rate have a structure in which the air induction passage 16 is expanded compared to the gas inlet tube 12, so that the flow rate becomes relatively slow. Due to the high-pressure jet under the condition that the flow rate of the gas is unchanged, the gas induction effect of increasing the strength and stability of the air flow can be obtained.

In other words, since the flow path formed by the gas injection pipe 12 and the air induction passage 16 has a narrow inlet side and a wide inner side, the flow rates of the gas and air supplied from the inlet side are inward. As it moves to slower and the pressure is increased, the pressure of the air and the gas flowing into the gas and air mixing chamber 11 through the air induction passage 16 is increased to cause a high-pressure jet. That is, the pressure of the gas is increased at the point where the air induction passage 16 ends, so that a high pressure jet occurs. In addition, due to the high-pressure jet of gas and air, the strength and stability of the air flow of the gas and air spirally supplied by the air induction passage 16 in the mixing pipe 10 is increased.

In this process, the gas and the air introduced into the mixing tube 10 through the gas injection tube 12 is passed through the air induction passage 16 formed by the guide plate 15, the flow rate is stabilized, the air induction passage By rotating in one direction while moving in one direction by (16), the mixing of gas and air is quick, easy and complete.

Subsequently, when the mixed gas mixed with air while swirling inside the mixing tube 10 is supplied to the ceramic head 3, the mixed gas passes through the ceramic head 3 of the honeycomb structure.

When power is supplied to the spark plug 5 in this state, a spark is generated between the electrode of the spark plug 5 and the ignition electrode line 6, and the spark ignites the mixed gas passing through the ceramic head 3. At this time, since the ignition electrode line 6 is disposed on the upper surface of the ceramic head 3, the spark is generated in a state where the mixed gas is directly supplied between the ignition electrode line 6 and the electrode of the ignition plug 5, so that the ignition is performed quickly. Since the ignition electrode line 6 is formed in a 'U' shape, the ignition success rate is also high.

On the other hand, in the state where the mixed gas supplied to the ceramic head 3 is ignited by the ignition device, the ceramic head 3 becomes red and radiates infrared rays to indirectly heat the cooking vessel or food.

Then, when the mixed gas is burned, the air located in the lower portion of the mixing tube 10 moves upward along the air passage 14 of the column 13. At this time, since the upper portion of the air passage 14 is formed smaller than the lower portion, the air moves to the upper portion of the ceramic head 3 according to the chimney (communication) phenomenon of the air passage 14. Therefore, since the air necessary for the combustion of the gas is sufficiently supplied to the upper portion of the ceramic head 3, complete combustion is achieved, thereby minimizing the generation of carbon monoxide (CO) and carbon dioxide (CO₂) due to incomplete combustion.

In the foregoing, specific embodiments of the present invention have been described and illustrated, but the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have. Therefore, such modifications or variations should not be individually understood from the technical idea or viewpoint of the present invention, but the modified embodiments should be included in the claims of utility model registration of the present invention.

1: inner ceramic retaining ring 2: outer ceramic retaining ring
3: ceramic head 4: gas induction bracket
5: spark plug
6: ignition electrode line 9: gas induction bracket fixing part
10 mixing tube 11: gas and air mixing chamber
12 gas inlet tube 13 pillar
14 air passage 15 guide plate
16: air induction passage

Claims (8)

A burner apparatus having an indirect heating ceramic head configured to heat a cooking vessel or food with radiant heat generated by heating ceramic,
A mixing tube having a gas and air mixing chamber having an upper opening;
A gas injection pipe coupled to one side wall of the mixing pipe so that one end of the gas and air mixing chamber communicates with the gas and air mixing chamber;
Porous ceramic head disposed on the upper side of the mixing tube; And an ignition electrode line installed in the ceramic head and an ignition plug provided in proximity to the ignition electrode line to ignite a gas passing through the ceramic head.
The ignition electrode line,
Burner device having a ceramic head characterized in that it is formed to be bent in a "∩" shape extending from the one side edge of the ceramic head toward the upper surface center portion. The method of claim 1,
The ceramic head,
Burner device having a ceramic head, characterized in that coupled to the mixing tube by an inner ceramic fixing ring and an outer ceramic fixing ring. The method of claim 1,
The ignition electrode line,
Burner device having a ceramic head, characterized in that the nickel-chromium alloy. The method of claim 1,
In the connection region of the gas injection tube and the gas and air mixing chamber, the gas supplied from the gas injection tube is moved spirally in the gas and air mixing chamber to form an air induction passage in one direction so as to be mixed with air. Burner device having a ceramic head, characterized in that the gas induction bracket is provided. 5. The method of claim 4,
The gas induction bracket,
A gas induction bracket fixing part fixed to the bottom of the gas and air mixing chamber; And
A portion of the gas and air mixing chamber is divided vertically and extended vertically from the gas induction bracket fixing portion to form an air induction passage, and then bent horizontally so as to be in close contact with the inner wall of the gas and air mixing chamber. Burner device having a ceramic head, characterized in that consisting of a guide plate formed. The method according to any one of claims 1 to 5,
At the center of the mixing tube is provided with a column formed through the air passage in the vertical direction,
In the center of the ceramic head is formed an air hole corresponding to the air passage,
Burner device having a ceramic head, characterized in that the air in the lower portion of the mixing tube is supplied to the ceramic head during gas combustion in the ceramic head. The method according to claim 6,
The air passage is a burner device having a ceramic head, characterized in that the lower side diameter is formed larger than the upper side diameter. The method according to any one of claims 1 to 5,
The gas injection pipe is a burner device having a ceramic head, characterized in that the closer to the mixing tube diameter is formed.

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