KR101680073B1 - Fire tower for high thermal power gas burner - Google Patents

Abstract

The present invention relates to a pagoda for a high-power gas burner. The present invention relates to a multi-stage cap forming unit (11) having a structure in which a gas nozzle (11a) is formed at an equal interval and is formed through a multi-step groove formed at a concave inner side in a conical shape with a top cut off. A main tube body 12 connected to a lower portion of the multi-stage tube forming portion 11 and mixing the fuel gas and air and supplying the mixed gas to the multi-tube tube forming portion 11; And an air adjusting pipe (13) corresponding to a tubular body in which the air passing hole is formed in the side by being cylindrically formed to overlap with an upper air adjusting end (12b) formed in a lower region of the main tube body (12); The present invention provides a pagoda for a high-power gas burner.
Thus, water is prevented from flowing into the nozzle through the spray nozzle corresponding to the upper hole, so that water is prevented from entering the nozzle, thereby eliminating the risk of explosion due to excessive water vapor generation, In order to prevent the risk of explosion due to the deterioration of the heat efficiency and the explosion when the gas is introduced into the space area connected to the nozzle at a time, the mixture gas is dispersed outwardly through the bell-shaped structure inside, Provides a possible effect.

Description

Fire tower for high thermal power gas burner

The present invention relates to a pagoda for a high-power gas burner, and more particularly, to a pagoda for a high-power gas burner, and more particularly, The present invention relates to a pylon for a high-strength gas burner for dispersing a mixed gas outwardly through an inner structure to prevent thermal degradation and explosive sound, thereby maintaining overall stability while maintaining thermal efficiency.

A gas burner is a device that obtains heat by supplying fuel gas from a gas supply source and burning it, and is widely used for cooking in a business. LNG or LPG is used as fuel gas and electrons are supplied at a relatively lower pressure than the latter. The gas burner generally comprises a fuel mixing section for mixing air and gas and a nozzle section for jetting the mixed gas.

Many efforts have been made to improve thermal efficiency and thermal power for gas burners. However, the conventional gas burners have a complicated structure and thus require a large production cost. In addition, there is a problem that the flame is dispersed to the side and the thermal power is lowered, and the air and the fuel gas are not mixed uniformly, .

Accordingly, the present applicant has proposed a method of controlling the air pressure according to the kind of the fuel gas through the gas burner for cook and increasing the thermal power and thermal efficiency.

However, in the conventional cooking gas burner, there is a risk that water enters into the ejection nozzle corresponding to the upper hole and gas fire is turned off or explosion sound is generated due to external steam. In the present invention, I would like to present a pagoda for a burner.

[Related Technical Literature]

1. BURNER OF HIGH THERMAL POWER (Patent Application No. 10-2012-0024873)

2. SUPPORTING STAND OF COOKING RECEPTACLE FOR BURNER (Patent Application No. 10-2013-0014424)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a water purifier that eliminates the risk of water being blown into the water through the jet nozzle corresponding to the upper hole, And to provide a pagoda for a high-strength gas burner to be used.

In addition, the present invention diffuses the mixed gas outwardly through the inner structure in order to prevent the thermal efficiency from deteriorating and explosion when the mixed gas is excessively introduced into the space area connected to the spray nozzle at a time, To a pylon for a high-strength gas burner for maintaining stability.

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to accomplish the above object, the pagoda for a high-power gas burner according to an embodiment of the present invention is formed in a conical shape with a top cut, and a gas nozzle 11a is formed through a multi- (11) having a structure formed by being surrounded by a multi-stage shade (11); A main tube body 12 connected to a lower portion of the multi-stage tube forming portion 11 and mixing the fuel gas and air and supplying the mixed gas to the multi-tube tube forming portion 11; And an air adjusting pipe (13) corresponding to a tubular body in which the air passing hole is formed in the side by being cylindrically formed to overlap with an upper air adjusting end (12b) formed in a lower region of the main tube body (12); And a control unit.

At this time, the multi-stage shovel forming portion 11 is formed in a first shade shape to an n-th shade shape (n is a natural number of 2 or more), a groove-like groove of an engraved angle is formed between the respective shade shapes, And a diagonal nozzle 11a is formed from the inner side to the outer side toward the region formed by the plane that intersects orthogonally at the lower portion of the groove.

The multi-stage shovel forming portion 11 is characterized by being a nozzle body that receives a mixed gas formed by mixing fuel gas and air from the main tube body 12 and ejects the mixture gas to the outside.

The multistage shim forming part 11 is formed in a donut shape in which the inside is punctured between the lower end of the mixed gas dispersion space providing part 11b and the upper end of the main tube body 12, A main tube coupling end 11c having a structure in which an outer circumferential surface is fastened to an inner circumferential surface of the multi-stage shovel-forming portion 11 at an upper portion thereof, and a space for providing a gas mixture is formed in a punch- And a control unit.

In addition, the mixed gas dispersion space providing portion 11b is formed at the upper center of the multi-stage shim forming portion 11 so as to disperse the mixed gas provided from the mixed gas providing space region of the main tube connecting portion 11c outwardly .

The pagoda for a high-power gas burner according to an embodiment of the present invention is a pagoda for a high-strength gas burner that allows water to flow through the discharge nozzle corresponding to the upper hole without flowing into the water hole, Lt; / RTI >

In addition, the pagoda for a high-power gas burner according to another embodiment of the present invention is a pagoda for a high-power gas burner, in which the thermal efficiency when the mixed gas is excessively introduced into the space region connected to the ejection nozzle at a time, Thereby providing the effect of increasing the overall thermal efficiency while maintaining stability.

1 is a perspective view showing a pagoda 10 for a high-power gas burner according to an embodiment of the present invention.
2 is an exploded perspective view showing the pagoda 10 for the high-power gas burner of FIG.
3 is a cross-sectional view of the pagoda 10 for the high-power gas burner of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of preferred embodiments of the present invention will be given with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The gas burner of the present invention can generally be used for cooking in the kitchen of the catering industry. However, the scope of the present invention should not be limited by its use.

1 is a perspective view showing a pagoda 10 for a high-power gas burner according to an embodiment of the present invention. 2 is an exploded perspective view showing the pagoda 10 for the high-power gas burner of FIG. 3 is a cross-sectional view of the pagoda 10 for the high-power gas burner of FIG.

Referring to FIGS. 1 to 3, the pagoda for a high-power gas burner 10 includes a multi-stage shovel forming portion 11, a main tube body 12, and an air conditioning pipe 13.

1 to 3, the gas nozzles 11a are arranged at regular intervals through multi-step grooves formed intaglio to the inside as shown in FIG. 1 to FIG. .

That is, the multi-stage shovel forming portion 11 is formed in a first to n-th shade shape (n is a natural number of 2 or more), and grooves of an engraved angle are formed between the respective shade shapes, And a diagonal nozzle 11a is formed from the inner side to the outer side toward the region formed by the face that intersects orthogonally at the lower portion of the groove.

With this structure, it is possible to eliminate the risk of gas explosion due to the entry of water into the inside of the nozzle 11a to turn off the gas fire or excessive water vapor.

That is, the multi-stage cap forming section 11 corresponds to a nozzle body that receives a mixed gas formed by mixing fuel gas and air from the main tube body 12 and ejects the mixture gas to the outside.

The main pipe body 12 is connected to the lower portion of the multi-stage pour forming portion 11 and mixes the fuel gas and air and supplies the mixture to the multi-stage pour forming portion 11.

The air control tube 13 corresponds to a tubular body having four air pass holes formed in the lateral direction by forming a cylinder to be superimposed on the upper air adjusting end 12b formed in a lower region of the main tube body 12. [

A lower air conditioning end 12a is formed at a lower portion of the upper air conditioning end 12b of the main tube body 12 by puncturing four holes 90 ° apart from the punctured region of the upper air conditioning end 12b .

Although not shown, a socket as a gas connecting means is connected to the lower portion of the main tube body 12, and a socket is connected to the fuel gas supply portion. The fuel gas is supplied from the fuel gas supply portion. The fuel gas can be LNG or LPG and is blown upwards in the drawing by its own pressure. Each component will be described in detail below.

The multi-stage cap forming portion 11 is composed of a nozzle 11a, a mixed gas dispersion space providing portion 11b, and a main tube connecting portion 11c. The main tubular body coupling end 11c is formed in a donut shape in which the inside is punctured between the lower end of the mixed gas dispersion space providing portion 11b and the upper end of the main tubular body 12 and the main tubular body 12 is fastened to the lower end And the outer circumferential surface of the upper portion is fastened to the inner circumferential surface of the multi-stage cap forming portion 11, thereby forming a space for providing a mixture gas in the center punch region.

The mixed gas dispersion space feeder 11b is formed in an inverted bell shape and has a multi-stage shade forming part 11 for dispersing the mixed gas provided from the mixed gas providing space region of the main tube connecting stage 11c outwardly, As shown in the upper center of FIG.

That is, in order to solve the problem that when the mixed gas is excessively introduced into the multi-stage shovel forming part 11 at a time, the explosion risk is generated and the thermal efficiency is lowered, So as to maintain the stability while raising the overall thermal efficiency.

The flame is guided diagonally upward through the nozzle 11a through this structure to smoothly burn the flame. Further, the flame is guided to flow to the outer side when food or the like falls.

Hereinafter, the main tube 12 and the air control tube 13 connected to the lower portion of the multi-stage cap forming unit 11 will be described.

The main tube body 12 is formed in a cylindrical tube shape and has a constant diameter. The upper end of the main tube body 12 is provided with an upper end coupled to a seat groove of the main tube coupling end 11c of the multi-step tube portion 11, and a lower air- An end 12a and an upper air conditioning end 12b are provided.

A plurality of air through holes of the lower air adjusting end 12a and the upper air adjusting end 12b are provided along the circumferential direction on the side wall of the main tube 12, The air passage holes of the air conditioning end 12b are disposed at intervals of 90 [deg.] Along the circumferential direction which is the vertical center axis of the main tube body 12. [

That is, the air passing holes of the lower air adjusting end 12a and the air passing holes of the upper air adjusting end 12b are spaced by 90 degrees and spaced apart by 90 degrees along the circumferential direction of the main tube 12, . Of course, this number is only an example.

According to the drawings, the air passage holes of the lower air adjusting end 12a and the air passage holes of the upper air adjusting end 12b are provided in a single line, but are disposed at mutually staggered positions. Therefore, the outside air flows into the main tube body 12 uniformly along the circumference of the main tube body 12 as a whole.

Meanwhile, the air introduced into the air passage holes of the lower air adjusting end 12a and the fuel gas supplied through the fuel gas holes (not shown) of the lower portion of the main tube 12 are mixed to produce a primary mixed gas. The primary mixed gas is directed upward along the main tube 12.

According to the embodiment of the present invention, a narrow induction tube 12c is further inserted and fixed in the main tube body 12. [ The induction pipe 12c is for passing the primary mixed gas through the air passage hole of the upper air conditioning end 12b while being perfused without being influenced from the outside.

The induction pipe 12c is installed at the center of the main tube 12. [ Particularly, the induction pipe 12c is installed between the outer wall of the induction pipe 12c and the inner wall of the main tube body 12 so as to provide an annular air inflow space.

The external air introduced into the air passage hole of the upper air adjusting end 12b is directed to the multi-stage cap forming portion 11 through the air inflow space between the outer wall of the induction pipe 12c and the inner wall of the main tube body 12 . For reference, the outside air is introduced into the main tube 12 through the upper air adjusting end 12b by a negative pressure generated by a rising air flow of the primary mixed gas.

The primary mixed gas flows into the lower end of the induction pipe 12c and passes through the upper end. Then, the primary mixed gas exits the induction pipe 12c and is mixed again with the external air introduced through the air passage hole of the upper air adjusting end 12b to become a secondary mixed gas. That is, the fuel gas is mixed with the outside air sequentially through the main tube 12 in a sequential manner.

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms have been used, they have been used only in a general sense to easily describe the technical contents of the present invention and to facilitate understanding of the invention , And are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: Pagoda for high-power gas burner
11: Multi-
11a: Nozzle
11b: Mixed gas dispersion space supply
11c: main tube coupling end
12: main tube
12a: lower air conditioning unit
12b: Upper air conditioning unit
13: air control tube

Claims (5)

(11) having a structure in which a gas nozzle (11a) is formed at an equal interval and is formed through a multistage groove formed at an engraved inner side in the shape of a truncated cone; A main tube body 12 connected to a lower portion of the multi-stage tube forming portion 11 and mixing the fuel gas and air and supplying the mixed gas to the multi-tube tube forming portion 11; And an air adjusting pipe (13) corresponding to a tubular body in which the air passing hole is formed in the side by being cylindrically formed to overlap with an upper air adjusting end (12b) formed in a lower region of the main tube body (12); Wherein the high-thermal-power gas burner pylon is a high-
The multi-stage shade forming part 11 is formed in a donut shape in which the inside is punctured between the lower end of the mixed gas dispersion space providing part 11b and the upper end of the main tube body 12 and the main tube body 12 (11c) having a structure in which an outer circumferential surface is fastened to the inner circumferential surface of the multi-stage shovel forming part (11) and an air space for providing a mixed gas is formed in a pore area at the center,
The mixed gas dispersion space feeder 11b is formed in an inverted bell shape and has a plurality of openings formed in the multistage oval forming portion 11 for dispersing the mixed gas provided from the mixed gas providing space region of the main tube connecting portion 11c outwardly. And is formed at the upper center,
An annular air inflow space is provided between the outer wall of the main tube body 12 and the inner wall of the main tube body 12 at the center of the main tube body 12 so that external air introduced into the air passage hole of the upper air conditioning end 12b flows into the main tube body 12, Further comprising an induction pipe (12c) for guiding the multi-stage oval forming part (11) through the air inflow space between the inner walls of the partition wall (12) toward the multi-stage oval forming part (11). [3] The apparatus according to claim 1, wherein the multi-
(N is a natural number of 2 or more), and grooves of an engraved edge are formed between the respective corrugations. The grooves are formed in a "C" And a diagonal nozzle (11a) is formed from the inside to the outside toward the region formed by the faces which intersect orthogonally.
[3] The apparatus according to claim 1, wherein the multi-
And a nozzle body for receiving a mixed gas formed by mixing fuel gas and air from the main tube body (12) and ejecting the mixture gas to the outside.




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