KR100708445B1 - Pre-mixing structure of burner for gas - Google Patents

Abstract

The present invention relates to a premixing structure of the gas burner, and more particularly, the gas supplied through the gas ejection pipe is rotated and flows into the air flowing inside the inner body of the premixing unit. The present invention relates to an apparatus for allowing uniform mixing with each other.

According to the present invention as described above, the pre-mixing space of the gas and air can be reduced to maximize the space utilization, the thermal efficiency is improved by the uniformly mixed gas and air.

Burner for gas, premixed part, gas ejection pipe, flow

Description

Pre-mixing structure of burner for gas}             

1 is a perspective view showing the appearance of a conventional gas burner.

2 is a side cross-sectional view of FIG.

3 is a partial cutaway perspective view of the premixed portion in FIG.

Figure 4 is a side cross-sectional view showing another structure of a conventional gas burner.

5 is a partial cutaway perspective view of the premixed portion in FIG. 4.

Figure 6 is a side cross-sectional view of the burner for gas according to an embodiment of the present invention.

7 is a partial cutaway perspective view of the premixed portion in FIG. 6.

8 is a cross-sectional view of FIG.

9 is an exploded perspective view of FIG. 7;

Figure 10 is a partial cutaway perspective view showing a premixed portion according to another embodiment of the present invention.

11 is a cross-sectional view of FIG. 10.

12 is a perspective view showing a gas ejection pipe according to an embodiment of the present invention.

13 is a perspective view showing a gas ejection pipe according to another embodiment of the present invention.

14 is a perspective view showing a gas ejection pipe according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

70: gas burner 71: air supply fan

72: air supply portion 74: gas supply port

80: premixed unit 82: distribution unit

84: outer body 90: flange

92: inner body 94: transfer space

96: mixing space 98: bonding holes

100: gas ejection pipe 102: gas fuel inlet

104: body portion 106: nozzle

110: gas flow groove 120: tail

The present invention relates to a premixing structure of a gas burner device. More particularly, the gas and air supplied to the gas burner device of the premixing system are sufficiently mixed in advance so that complete combustion occurs when the mixed gas is combusted. The present invention relates to a premixed structure of a gas burner device capable of maximizing combustion efficiency, minimizing pollutants, enabling high efficiency and low pollution combustion, and reducing the installation area of the gas burner device.

In general, a burner device is a device that burns fuel safely and efficiently to obtain heat, and is a gas burner device for gas combustion, an oil burner device for burning liquid fuel such as kerosene or heavy oil, and coal combustion depending on the type of fuel. And pulverized coal burners.

In addition, it is divided into a premixed burner device and a diffusion burner device according to a method of mixing fuel and air.

The premixed burner device burns fuel and air in advance, and the diffusion burner device sends fuel and air to the combustor separately, and mixes and burns the fuel in the combustor.

In particular, the premixed burner device is characterized by combusting a mixed gas sufficiently mixed with gas and air before combustion, combustion combustion heat for the purpose of the technology of high efficiency and low pollution combustion with high combustion efficiency, less pollutants are discharged Device.

As shown in Fig. 1 and Fig. 2, a general premixed burner device 1 has an air supply unit 2 for boosting and supplying air, a premixing unit 4 for mixing gas and air, and a mixed gas Is composed of a distribution section (6) having a uniform pressure distribution, a burner section (8) for combusting the mixed gas, and a heat transfer section (9) for recovering and using the combustion heat thereof according to the purpose.

The air supply unit 2 is provided with an air supply fan 3 to supply air therein.

The air supply fan 3 is fixedly installed in a conventional structure in the air supply unit (2).

The premixing unit 4 is a device for mixing gas and air used in the premixing burner 1 before combustion, and supplying the mixed gas to the burner unit 8 according to one embodiment of the present invention. Describe the configuration.

The premixing unit 4 is coupled to the air supply unit 2 and the distribution unit 6 and the flange 12 on both sides, respectively, through the air and gas supply unit (not shown) supplied from the air supply unit 2 The gas supplied from the gas supply port 14 is supplied into the premixing unit 4, and is mixed to mix the mixed gas therein to supply the mixed gas to the distribution unit 6.

As shown in FIG. 3, the premixing part 4 has a flange 12 formed at both ends and an air supply pipe 10 through which air flows, and a part of the premixed part is inserted into one side of the air supply pipe 10. In order to mix the gas supply hole 14 and the air supply hole 16 through the outer peripheral surface of the end of the gas supply port 14 and the gas supply port 14 for supplying the gas axially bent its closed end It consists of a swirler 18 provided at a predetermined position of the air supply pipe (10).

Typically, the swirler 18 is fixedly installed in the air supply pipe (10).

The flange 12 is formed for fastening the premixing part 4 to the air supply part 2 and the distribution part 6.

The flange 12 is typically fastened by bolts and nuts (not shown).

In addition, the premixing part 4 is such that the gas supply port 14 penetrates through the air supply pipe 10 and extends to an approximately center of the air supply pipe 10, and then bends in the axial direction to eject the gas in the air flow direction. Is formed.

At this time, the end of the gas supply port 14 is sealed, a plurality of gas supply holes 16 are formed on the outer circumferential surface of the end portion at regular intervals so that gas can be ejected from the center of the air supply pipe 10 toward the inner surface It is.

On the other hand, as shown in Figure 4 and 5, in another embodiment of the gas burner device 20, the premixing portion 24 is composed of a double tubular outer body 40 and the inner body 50. .

A space 60 is formed between the outer body 40 and the inner body 50.

Then, a gas supply port 34 is inserted into one side of the outer body 40 so that the end thereof is positioned on the space 60.

In addition, a plurality of gas supply holes 36 are formed in the circumferential surface of the inner body 50 at regular intervals so that the gas introduced into the gas supply hole 34 is supplied into the inner body 50.

At this time, the inner body 50 is formed to flow the air supplied by the operation of the air supply fan 23 provided inside the air supply unit 22 as a hollow.

Air and gas introduced into the inner body 50 are uniformly mixed by the swirler 38 provided therein.

In addition, the air supply fan 23 is installed in a conventional manner in the air supply unit 22, the swirler 38 is fixed to the inside of the inner body (50).

On the other hand, the flange 32 formed by contacting both sides of the outer body 40 and the inner body 50 together to seal the space 60 to prevent the outflow of gas and air pre-mixed portion 24 It is for coupling to the supply part 22 and the distribution part 26.

The flange 32 is typically fastened by bolts and nuts (not shown).

The premix 24 is formed in a double tube shape of the outer body 40 and the inner body 50, the gas supply port 34 is connected to the outer body 40, the outer body 40 and the inner body The gas is supplied to the space 60 between the 50.

At this time, the side of the inner body 50 through the gas supply hole 36 at a predetermined interval to blow out the gas into the interior of the inner body (50).

However, the premixing part of the conventional gas burner device must form a plurality of gas supply holes at the end of the gas supply pipe for uniform gas ejection, and at least one swirler (eg By forming a swirler, the device of the premixing unit is large and complicated, and there is a problem in that pressure loss by a large number of swirlers is large.

In addition, the density of the mixed gas is relatively low in the central portion of the mixed gas due to the vortex formation by the swirler, and there is also a problem that the volume of the distribution unit connected to the premixing portion needs to be large for even distribution of the mixed gas.

An object of the present invention for solving the above-mentioned conventional problems, the gas burner that can reduce the pressure loss and reduce the installation space by making the gas and air uniformly mixed without installing a separate turning machine It is to provide a premixed structure of the group.

The present invention for achieving the above object, in the gas burner for mixing and burning gas in the pre-mixing unit, the outer body of the pre-mixing unit and a gas supply port for introducing the gas into the inside is provided on one side In communication with this, the outer body having a hollow formed inside, and formed at a predetermined interval with the outer body to form a transport space for flowing the gas flowing through the gas supply port in the circumferential direction, and inside the gas and air The inner body is provided with a mixing space for mixing with each other, and the gas fuel inlet formed at both ends in communication with the transfer space formed between the inner body and the outer body in communication with the air flowing through the mixing space of the inner body and rotational flow In the body portion passing through the central axis of the mixing space to mix the gas to the center in the axial direction The nozzle gas is ejected consists of a gas distributor pipe is formed only on one side of the both side surfaces of the body portion.

Preferably, the gas fuel inlet and the gas supply port of the gas ejection pipe is installed in an angle range of 60 degrees to 90 degrees with respect to the inner body axial cross section.

And, the nozzle formed in the gas ejection pipe is gradually reduced in diameter from both ends toward the center.

The gas ejection pipe is formed with a streamlined tail in a downstream direction of air flow when mounted inside the inner body.

The inner body is formed to be in close contact with the inner side of the outer body, and a gas flow groove is formed in the circumferential direction along the inner side of the outer body so as to be a gas transfer path inside the outer body in communication with the gas ejection pipe.

In addition, two or more gas ejection pipes may be provided at equal intervals along the mixing space of the inner body, and may be installed at regular intervals or may be connected to each other at the central axis of the mixing space.

According to the present invention as described above, the pre-mixing space of the gas and air can be reduced to maximize the space utilization, the thermal efficiency is improved by the uniformly mixed gas and air.

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

As shown in FIG. 6, the gas burner 70 includes an air supply unit 72 for boosting and supplying air by the rotation of the air supply fan 71, and oxygen supplied by the air supply unit 72. And a premixing unit 80 for mixing the gas supplied by the gas supply port 74 and a distribution unit 82 for making the mixed gas have a uniform pressure distribution.

The structure of the premixing unit 80 of the gas burner 70 will be described with reference to FIGS. 7 to 9.

The premixed structure of the gas burner 70 is fixed to the gas supply port 74 for supplying gas to one side of the outer body 84 in communication with the hollow 86, the inner space, the flange 90 at both ends ) Is provided to allow the premixing unit 80 to be fixed between the air supply unit 72 and the distribution unit 82.

An inner body 92 is inserted into and coupled to the inner body 86 of the outer body 84, and the outer body 84 and the inner body 92 are spaced at regular intervals so that gas flows in the circumferential direction. 94 will be formed.

Inside the inner body 92 is provided a mixing space 96 which is a space for mixing air and gas to each other, the coupling hole 98 which is a passage for the gas to move inward to the inner body 92 side Is formed.

In the gas ejection pipe 100 mounted to the coupling hole 98, the gas fuel inlet 102 formed at both ends is coupled to the coupling hole 98, and the gas flowing through the gas fuel inlet 102 flows. Body portion 104 that is a passage is provided.

On the side of the body portion 104, a nozzle 106 through which the gas is ejected with respect to the axial direction is formed on only one side of both sides of the body portion 104 so as to rotate and spray the gas in the lateral direction of the air flow. That is, the formation of the nozzle 106 and the upper side of one side of the body portion 104 so that the gas injected into the mixing space 96 through the gas ejection pipe 100 rotates and the mixing with the air is made smoothly. The nozzles 106 are formed below the other side of the body 104, respectively.

According to another embodiment of the present invention, as shown in Figure 10 and 11, the outer surface of the inner body 92 and the inner surface of the outer body 84 is installed to be in contact with each other, the gas supply port ( A gas flow groove 110 having a groove shape is formed along the circumferential direction inside the outer body 84 in communication with 74 so that the gas supplied from the gas supply port 74 may change the circumferential direction of the outer body 84. Therefore, to ensure a uniform supply.

As shown in FIG. 12, the gas ejection pipe 100 according to the exemplary embodiment of the present invention has a shape in which the nozzle 106 is formed in a diagonal direction symmetrically about a central axis, and the nozzle 106 is illustrated in FIG. 13. Likewise, it will be another embodiment of the present invention that the diameter size gradually decreases from the outside to the inside.

In addition, the gas ejection pipe 100 forms a streamlined tail portion 120 downstream of the air flow direction as shown in FIG. 14 to reduce pressure loss.

The transfer space 94 between the outer body 84 and the inner body 92 in the above, as long as the gas supply port 74 and the gas fuel inlet 102 of the gas ejection pipe 100 have an appropriate angle, It can be formed in various sizes and shapes for convenience.

In addition, two or more gas ejection pipes 100 may be installed. In this case, the gas ejection pipe 100 may be disposed at an isometric angle with respect to the center of the cross section of the mixing space 96 of the inner body 92, and the A gas supply port 74 is formed in the middle.

8 and 11, the angle formed by the gas supply port 74 and the gas fuel inlet 102 of the gas ejection pipe 100 has a range of 60 to 90 degrees, which is the gas The gas supplied through the supply port 74 is to be uniformly distributed along the transport space 94 or the gas flow groove 110, the gas having such a uniform density flows into the gas fuel inlet (102) This is to ensure uniform injection in the gas ejection pipe 100.

Meanwhile, a configuration of the flange 90 for coupling the outer body 84 and the inner body 92 to each other may include a first flange provided at both ends of the outer body 84, as shown in FIGS. 9 and 10. 90a and the second flange 90b and the third flange 90c provided at one end of the inner body 92.

The first flange 90a is fixed in contact with the air supply unit 72, and the third flange 90c is mounted on the stepped portion 91 of the second flange 90b to be fixed to each other.

Gas ejection pipe 100 according to an embodiment of the present invention may be installed only one in the mixing space 96, may be installed two or more.

When two or more are installed, they are installed at regular intervals along the mixing space 96, and at this time, they are installed with a certain angle depending on the number of the gas ejection pipes 100.

According to another embodiment, two or more gas ejection pipes 100 are installed on the same cross section and are interconnected at the central axis of the mixing space 96.

The operation according to the embodiment of the present invention having the above configuration will be described.

Air boosted by the operation of the air supply fan 71 flows into the inner space of the premixing unit 80, and the gas supplied by the gas supply port 74 is transferred to the transfer space 94 or the gas flow groove 110. It is uniformly distributed along the outer circumferential direction of the inner body 92 along the.

The gas ejection pipe 100 coupled to the coupling hole 98 of the inner body 92 has a gas inlet flowed from the outside of the inner body 92 along the gas fuel inlet 102 and the mixing space through the nozzle 106. Gas is ejected to 96, and the gas ejected through the nozzle 106 is rotated by the shapes of the nozzles 106 formed in a diagonally outward direction.

As described above, uniform mixing occurs more preferably between the gas and the air flowing through the mixing space 96 by the gas to be rotated, as shown in Figure 13, the shape of the nozzle 106 is the body portion ( The larger the both ends of 104, the more smooth the rotational motion of the gas.

And, as shown in Figure 14, by forming a streamlined tail portion 120 in the direction in which the air flowing in the rear side of the gas ejection pipe 100, can be generated while passing through the gas ejection pipe 100 It is possible to prevent the occurrence of pressure loss by suppressing the peeling phenomenon of air.

On the other hand, when a plurality of the gas ejection pipe 100 is installed, to provide a more smooth rotational motion of the gas, compared to the case of using a single gas ejection pipe 100 is improved air and gas mixing structure Will be provided.

At this time, the speed of the gas supplied varies according to the diameter of the gas ejection pipe 100, the rotational flow speed of the gas varies according to the speed of the supplied gas, and the mixing of the gas well with the air varies well. It is desirable to adjust.

On the other hand, the present invention can be applied not only to domestic gas boilers, but also to gas boilers for research and industry.

As described above, according to the pre-mixing structure of the gas burner according to the present invention, since the gas is mixed with the air while being rotated in the mixing space inside the body, the combustion is close to the complete combustion, and the combustion efficiency is close to the combustion efficiency. In addition, the carbon monoxide emission is significantly reduced.

In addition, since the internal mixing space does not need to include a conventional swirler, the volume of the premixing portion is reduced as compared with the conventional one, thereby reducing the installation area of the gas burner and maximizing space utilization.

Claims (6)

An outer body constituting the outer body of the premixing part and provided with a gas supply port for introducing gas into the inner side and connected to the outer body having a hollow formed therein, and installed at an inner side with a predetermined distance from the outer body to supply the gas. In the gas burner including an inner body having a mixing space for gas and air mixed with each other to form a transport space for flowing the gas flowing through the sphere in the circumferential direction;  A gas fuel inlet formed at both ends of the transfer space formed between the inner body and the outer body is in communication with each other, and the body portion passing through the central axis of the mixing space so that the gas is mixed with the air flowing through the mixing space of the inner body and rotational flow. Premixing structure of the gas burner comprising a gas ejection pipe each formed in a direction opposite to each other in the nozzle in which the gas is ejected with the center in the axial direction at the left and right boundaries. 2. The premixing of the gas burner according to claim 1, wherein the gas fuel inlet and the gas supply port of the gas ejection pipe are installed within an angle range of 60 to 90 degrees with respect to the inner body axial cross section. rescue. The premixing structure of the gas burner according to claim 1, wherein the nozzles formed in the gas ejection pipe are gradually reduced in diameter from both ends toward the center. According to claim 1, wherein the gas ejection pipe is pre-mixed structure of the burner for gas, characterized in that the streamlined tail portion is formed in the downstream direction of the air flow when mounted inside the inner body. The gas of claim 1, wherein the inner body is formed to be in close contact with an inner side of the outer body, and a groove is formed in the circumferential direction along the inner side of the outer body so that the inner side of the outer body communicating with the gas supply pipe becomes a gas transfer passage. Premixing structure of the burner for gas, characterized in that comprising a flow groove. The gas burner of claim 1, wherein two or more gas ejection pipes are provided to form an equiangular angle with each other along the mixing space of the inner body, and are connected at regular intervals or interconnected at the central axis of the mixing space. Premixed structure.

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