KR100832303B1 - Exhaust gas recirculation oxyfuel burner capable of controlling flame with low nox - Google Patents

Abstract

An exhaust gas recirculation oxyfuel burner is provided to suppress local high temperature and reduce NOx by decreasing an optimum mixture ratio space and expanding a lean and rich fuel area. An exhaust gas recirculation oxyfuel burner includes a combustion pipe(100), an oxygen supply pipe(120), and a fuel supply pipe(110). The combustion pipe is arranged in a burner tile(200) through a flange(104), and has one side with an exhaust gas supply port(101) and one end with a combustion nozzle. The oxygen supply pipe is arranged on a first rotating plate where a first connection flange(103) is tightened. The oxygen supply pipe is equipped with an oxygen nozzle which is arranged eccentrically from the central axial line of the combustion pipe so as to spray oxygen supplied from an oxygen supply port(121) to the combustion nozzle. The fuel supply pipe is arranged on a second rotating plate where a second connection flange(123) is tightened. The fuel supply pipe is equipped with a fuel nozzle arranged eccentrically from the central axial line of the oxygen supply pipe so as to spray fuel supplied from a fuel supply port(111).

Description

Exhaust gas recirculation oxyfuel burner capable of controlling flame with low NOx}

1 is a cross-sectional view of an oxygen burner according to an embodiment of the present invention.

2 is a right side view of FIG. 1.

<Description of the symbols for the main parts of the drawings>

100: combustion tube 101: exhaust gas supply port

102: combustion nozzle 103: first connection flange

104: fixed flange 110: fuel supply pipe

111: fuel inlet 112: fuel nozzle

120: oxygen supply pipe 121: oxygen supply port

122: oxygen nozzle 123: second connection flange

130: first rotating flange 131: first sealing member

132: first driving member 133: first rotating projection

140: second rotation flange 141: second sealing member

142: second driving member 143: second rotating projection

The present invention relates to a low nitrogen oxide oxygen burner, and more particularly, to a low nitrogen oxide oxygen burner for a flue gas recirculation type gas fuel that can freely control the shape and combustion characteristics of a flame.

In general, the low nitrogen oxide oxygen burner may reduce the local peak flame temperature by forming a fuel lean and a fuel-rich mixer region through air splitting or fuel splitting.

In addition, the low nitrogen oxide oxygen burner has a disadvantage in that the structural design and the optimization of the manufacturing, such as the optimum ratio of the split ratio and the shape of the nozzle exit is required to ensure the stability of the flame.

In addition, in the case of the low nitrogen oxide fuel direct injection combustion method applied in the high temperature combustion equipment, since the initial atmospheric temperature is low, the direct fuel injection operation is impossible in terms of ensuring flame stability, and thus a separate combustor is combined until a constant temperature is raised. There is a disadvantage to use or optimize the nozzle shape.

An object of the present invention devised to solve the above problems is to provide a low nitrogen oxide oxygen burner for exhaust gas recirculation type gas fuel that can freely control the shape and combustion characteristics of the flame.

Another object of the present invention is to provide a low nitrogen oxide oxy-combustor for exhaust gas recirculating gas fuel, which is simple in structure and fabrication, unlike a conventional oxygen-combustor.

The present invention for achieving the above object is a combustion tube is installed in the burner tile by a fixed flange, the exhaust gas supply port is installed on one side, the combustion nozzle is formed at one end; The first connection flange formed on the other end of the combustion tube is installed on the first rotating plate is fixed, is installed so as to be eccentric in the center axis of the combustion tube in the combustion tube to eject the oxygen supplied from the oxygen supply port to the combustion nozzle side An oxygen supply pipe in which an oxygen nozzle is installed; And a second connection plate formed at an end of the oxygen supply pipe is fixed to the second rotating plate, and installed in the oxygen supply pipe so as to be eccentric from the central axis of the oxygen supply pipe to supply the fuel supplied from the fuel supply port to the oxygen nozzle side. A low nitrogen oxide oxy-combustor for exhaust gas recirculating gas fuel comprising a fuel supply pipe provided with an ejecting fuel nozzle.

The oxygen supply pipe may be rotated about the central axis of the combustion pipe in the combustion pipe.

The fuel supply pipe may be rotated about the central axis of the oxygen supply pipe in the oxygen supply pipe.

In addition, the oxygen supply pipe is rotated by the first driving means, characterized in that made by rotating.

In addition, the fuel supply pipe is rotated by the second drive means, characterized in that the rotation is made.

Another invention, the combustion pipe is installed on the burner tile by a fixed flange, the exhaust gas supply port is installed on one side, the combustion nozzle is formed at one end; A first connection flange formed at the other end of the combustion tube is installed on a first rotating plate fixed thereto, and is installed in the combustion tube so as to be eccentric from the central axis of the combustion tube to eject the fuel supplied from the fuel supply port to the combustion nozzle side; A fuel supply pipe having a nozzle; And a second rotary plate formed at an end of the fuel supply pipe is fixed to the second rotating plate, and installed in the fuel supply pipe so as to be eccentric in the central axis of the fuel supply pipe, and supplying oxygen supplied from the oxygen supply port to the fuel nozzle. A low nitrogen oxide oxygen burner for exhaust gas recirculating gas fuel comprising an oxygen supply pipe provided with an ejecting oxygen nozzle.

The fuel supply pipe may be rotatable about a central axis of the combustion pipe in the combustion pipe.

The oxygen supply pipe may be rotated about the central axis of the fuel supply pipe in the fuel supply pipe.

In addition, the fuel supply pipe is rotated by the first driving means, characterized in that the rotation is made.

In addition, the oxygen supply pipe is rotated by the second driving means, characterized in that the rotation is made.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

Oxygen combustor of the present invention comprises a fuel supply tube, oxygen supply tube and combustion tube, unlike the conventional coaxial or circumferential independent injection method, the combustion tube, oxygen supply tube and fuel supply tube are integrated to be eccentric, respectively Structure.

In addition, the oxygen supply pipe and the fuel supply pipe have a structure in which one is inserted into the other, and similarly, one is eccentric with respect to the other. One is rotatable about the other central axis.

The oxygen supply pipe and the fuel supply pipe are rotatable together with respect to the central axis of the combustion pipe.

1 is a cross-sectional view of an oxygen burner according to an embodiment of the present invention, in which a fuel supply pipe is inserted into an oxygen supply pipe. 2 is a right side view of FIG. 1.

The oxygen burner is inserted into the burner tile 200 by a fixed flange 104 formed in the combustion tube 100.

One side of the combustion tube 100 is the exhaust gas supply port 101 is formed.

In addition, a combustion nozzle 102 is formed at an end of the burner tile 200 of the combustion tube 100, and a first connection flange 103 is integrated at an end of the combustion tube 100 opposite to the combustion nozzle 102. Is formed.

The first connection flange 103 is provided with a first rotating flange 130 that can rotate in contact with.

A first rotating protrusion 133 is formed on the first rotating flange 130, and the first rotating protrusion 133 is coupled to the groove of the first connecting flange 103. Accordingly, the first rotation flange 130 may be rotated with respect to the first connection flange 103.

The first rotation flange 130 may be rotated by the first driving member 132. The first driving member 132 may use a known friction difference, and a gear is formed on an outer surface of the first rotating flange 130 to use a driving gear that meshes with the teeth of the first rotating flange 130. It is also possible.

In addition, an oxygen supply pipe 120 penetrates the first rotation flange 130. At this time, the oxygen supply pipe 120 is installed eccentrically with respect to the central axis of the combustion pipe (100).

A first sealing member 131 is installed between the oxygen supply pipe 120 and the first rotation flange 130 to prevent gas leakage between the oxygen supply pipe 120 and the first rotation flange 130. do.

An oxygen nozzle 122 is formed at an end of the combustion nozzle 102 side of the oxygen supply pipe 120, and an oxygen supply hole 121 is formed at one side of the oxygen supply pipe 120 to receive oxygen. .

The second connection flange 123 is integrally formed on the opposite side of the oxygen nozzle 122 of the oxygen supply pipe 120.

The second connection flange 123 is provided with a second rotation flange 140 that can rotate in contact with.

A second rotating protrusion 143 is formed on the second rotating flange 140, and the second rotating protrusion 143 is coupled to the groove of the second connecting flange 123. Accordingly, the second rotation flange 140 may be rotated with respect to the second connection flange 123.

The second rotation flange 140 may be rotated by the second driving member 142. The second driving member 142 may use a known friction difference, and a gear is formed on an outer surface of the second rotating flange 140 to use a driving gear that meshes with the teeth of the second rotating flange 140. It is also possible.

In addition, a fuel supply pipe 110 penetrates the second rotation flange 140. At this time, the fuel supply pipe 110 is installed eccentrically with respect to the central axis of the oxygen supply pipe 120.

A second sealing member 141 is installed between the fuel supply pipe 110 and the second rotation flange 140 to prevent gas leakage between the fuel supply pipe 110 and the second rotation flange 140. do.

In addition, a fuel nozzle 112 is formed at an end of the oxygen nozzle 122 side of the fuel supply pipe 110, and a fuel supply port 111 is provided at an end opposite to the fuel nozzle 112 of the fuel supply pipe 110. Is formed.

With such a configuration, the mutual mixing ratio of exhaust gas, oxygen, and fuel is varied depending on the region on the combustion nozzle 102.

That is, the oxygen amount (or fuel amount) decreases with the circumferential movement of the fuel nozzle (or oxygen nozzle) to form a region where only fuel is completely present.

Therefore, the fuel / oxygen mixing ratio imparts a characteristic that fuel thinning, optimum mixing, and fuel-rich mixing ratio are simultaneously formed in the circumferential direction of the fuel nozzle (or oxygen nozzle) cross section.

That is, as in the conventional combustor, the flame is formed at the same time according to the spatial position of the premixing characteristic of the blue flame and the characteristic of the diffusion flame, but the fuel nozzle (or oxygen nozzle) at the cross section connecting the central axis and the oxygen nozzle central axis. Blue salt and whistle are formed in half with respect to the central axis.

In this type of flame, it is possible to effectively apply heat to the target by controlling the ignition zone having a large radiant heat transfer effect toward or toward the target, and to reduce the area of rust relatively. Therefore, high temperature heating such as steel heating It can be used as a low NOx oxygen burner in the process.

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the present invention without departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that it can be changed.

Compared with the conventional coaxial injection, the oxygen burner of the present invention reduces the space for forming the optimum mixing ratio and expands the fuel lean and fuel and concentrated areas, thereby suppressing local high temperature generation of the flame temperature, thereby greatly minimizing the amount of NOx generated and greatly improving the flame stability. Has an effect.

In particular, the structure of the oxygen combustor is simple and very practical in design and manufacturing in terms of simply using a combination of fuel and oxidant straight nozzles having different diameters.

In addition, when the third nozzle is eccentrically combined outside the oxygen nozzle (or fuel nozzle) for exhaust gas recirculation injection, the position of the oxygen nozzle (or fuel nozzle) inside the oxygen nozzle (or fuel nozzle) and the inside of the third nozzle According to the position of the oxygen nozzle (or fuel nozzle) of the very various types of flame and combustion characteristics can be implemented, there is an advantage that can flexibly respond as a low pollution (low NOx) heating control device of various industrial thermal processes.

Claims (10)

A combustion tube installed in the burner tile by a fixed flange, an exhaust gas supply port is installed at one side, and a combustion nozzle formed at one end thereof; The first connection flange formed on the other end of the combustion tube is installed on the first rotating plate is fixed, is installed so as to be eccentric in the center axis of the combustion tube in the combustion tube to eject the oxygen supplied from the oxygen supply port to the combustion nozzle side An oxygen supply pipe in which an oxygen nozzle is installed; And The second connection flange formed at the end of the oxygen supply pipe is installed on the second rotating plate is fixed, the oxygen supply pipe is installed so as to be eccentric from the central axis of the oxygen supply pipe to eject the fuel supplied from the fuel supply port to the oxygen nozzle side A low nitrogen oxide oxygen burner for exhaust gas recirculating gas fuel comprising a fuel supply pipe having a fuel nozzle installed therein. The low nitrogen oxide oxygen burner according to claim 1, wherein the oxygen supply pipe is rotatable about the central axis of the combustion pipe in the combustion pipe. The low nitrogen oxide oxygen burner according to claim 1, wherein the fuel supply pipe is rotatable about the central axis of the oxygen supply pipe in the oxygen supply pipe. The low nitrogen oxide oxygen burner according to claim 2, wherein the oxygen supply pipe is rotated by rotating the first rotation flange by a first driving means. 4. The low nitrogen oxide oxygen burner according to claim 3, wherein the fuel supply pipe is rotated by rotating the second rotation flange by a second driving means. A combustion tube installed in the burner tile by a fixed flange, an exhaust gas supply port is installed at one side, and a combustion nozzle formed at one end thereof; A first connection flange formed at the other end of the combustion tube is installed on a first rotating plate fixed thereto, and is installed in the combustion tube so as to be eccentric from the central axis of the combustion tube to eject the fuel supplied from the fuel supply port to the combustion nozzle side; A fuel supply pipe having a nozzle; And The second connecting flange formed at the end of the fuel supply pipe is fixed to the second rotation plate is fixed, is installed in the fuel supply pipe to be eccentric from the central axis of the fuel supply pipe to eject the oxygen supplied from the oxygen supply port to the fuel nozzle side A low nitrogen oxide oxygen burner for exhaust gas recirculating gas fuel comprising an oxygen supply pipe installed with an oxygen nozzle. 7. The low nitrogen oxide oxygen burner according to claim 6, wherein the fuel supply pipe is rotatable about the central axis of the combustion pipe in the combustion pipe. 7. The low nitrogen oxide oxygen burner according to claim 6, wherein the oxygen supply pipe is rotatable about the central axis of the fuel supply pipe in the fuel supply pipe. 8. The low nitrogen oxide oxygen burner according to claim 7, wherein the fuel supply pipe is rotated by rotating the first rotation flange by a first driving means. 9. The low nitrogen oxide oxygen burner according to claim 8, wherein the oxygen supply pipe is rotated by rotating the second rotation flange by a second driving means.

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