KR20240026163A - Burner and boiler equipment including the same - Google Patents

Abstract

The present invention relates to a burner that sprays and burns liquid fuel or solid fuel, combustion air, and ammonia gas while supplying them into a combustion furnace, comprising: a first fuel supply unit that supplies liquid fuel or solid fuel to a recirculation area in the combustion furnace; an ammonia supply unit disposed outside the first fuel supply unit and supplying ammonia gas to a recirculation area within the combustion furnace; and a first combustion air supply unit disposed outside the ammonia supply unit and supplying air for primary combustion to the outside of the combustion area, wherein the ammonia supply unit includes a plurality of units spaced apart from the outer periphery of the first fuel supply unit. It includes an ammonia supply pipe, and at the ends of the plurality of ammonia supply pipes, there is an ammonia nozzle that controls the injection amount and injection angle of ammonia gas to differentially spray ammonia gas toward the center and the outer direction of the ammonia supply pipe to the recirculation area. A burner characterized by being provided. and boiler equipment including the same.

Description

Burner and boiler equipment including the same}

The present invention relates to a burner and a boiler facility including the same, and more specifically, to a burner that combusts while supplying liquid or solid fuel, ammonia gas, and combustion air into the combustion furnace of a boiler facility, which is a combustion device, and a burner including the same. It is about boiler equipment.

In general, the configuration of a conventional low nitrogen oxide coal burner used in a coal-fired power plant, as shown in FIG. 1, includes a pulverized coal crusher 10 that powders coal to produce pulverized coal, and a nozzle pipe 20 through which pulverized coal is supplied. It is composed of a secondary air passage 30 through which secondary combustion air is supplied, and a tertiary air passage 40 through which tertiary combustion air is supplied.

In the configuration of this low nitrogen oxide coal burner, in particular, the inside of the nozzle pipe 20 includes a damper 21 for controlling the spraying deflection of the pulverized coal, a conical expander 60, and an ignition rod 50. ), and swirl vanes 70 for forming a swirling flow are provided in the secondary and tertiary air passages 30 and 40 surrounding the nozzle pipe 20. It is a formed structure.

The basic function performed by the nozzle of the low nitrogen oxide coal burner is to inject a mixture of air and pulverized coal into the combustion furnace through the nozzle pipe 20, like the coal nozzle of a general burner.

However, since the combustion characteristics of the burner change sensitively depending on the injection type of pulverized coal and the flow conditions at the outlet, nitrogen oxides generated during combustion of pulverized coal can be reduced by using these changing characteristics.

Meanwhile, existing burners burn solid fuel and liquid fuel alone or together in air. In this case, a problem occurs in which a large amount of CO2 is generated. There is a growing need to use ammonia, a carbon-free fuel, as an alternative fuel to reduce carbon emissions. However, there is a problem in that a large amount of nitric oxide is generated when co-firing liquid or solid fuel and ammonia.

The technology behind the present invention is disclosed in Korean Patent No. 10-0376619 (registered on March 6, 2003).

The present invention was created to solve the above problems. When ammonia gas is mixed with liquid or solid fuel and co-fired, the ammonia gas is not collided with combustion air and is directly directed to the recirculation area of the combustion furnace in the combustor. The purpose is to provide a burner that can suppress the generation of nitrogen oxides and a boiler facility including the same.

In order to achieve the above object, the present invention provides a burner that supplies liquid fuel or solid fuel, combustion air, and ammonia gas into the combustion furnace and injects and burns the liquid fuel or solid fuel into the recirculation area within the combustion furnace. A first fuel supply unit that supplies fuel; an ammonia supply unit disposed outside the first fuel supply unit and supplying ammonia gas to a recirculation area within the combustion furnace; and a first combustion air supply unit disposed outside the ammonia supply unit and supplying air for primary combustion to the outside of the combustion area, wherein the ammonia supply unit includes a plurality of units spaced apart from the outer periphery of the first fuel supply unit. It includes an ammonia supply pipe, and at the ends of the plurality of ammonia supply pipes, there is an ammonia nozzle that controls the injection amount and injection angle of ammonia gas to differentially spray ammonia gas toward the center and the outer direction of the ammonia supply pipe to the recirculation area. A burner characterized by being provided is provided.

The burner according to the present invention is disposed between the ammonia supply unit and the first combustion air supply unit, and is disposed outside the second fuel supply unit and the first combustion air supply unit for supplying solid fuel into the combustion furnace. It may further include a second combustion air supply unit that supplies secondary combustion air to the outside of the area where the primary combustion air supplied from the first combustion air supply unit is burned, and the plurality of ammonia supply pipes are connected to the first fuel supply unit. It can be placed parallel to .

In the burner according to the present invention, a first guide vane and a second guide vane may be formed to be inclined outward at one end of the first combustion air supply unit and the second combustion air supply unit, and the second guide vane may be formed at one end of the first combustion air supply unit and the second combustion air supply unit. It may be formed to protrude further into the interior of the combustion furnace than the first guide vane.

The ammonia nozzle may have a disk shape, and a bent end inclined to one side may be formed at the end of the ammonia nozzle, and a first injection spraying ammonia gas to the front of the ammonia supply pipe is provided at the center of the ammonia nozzle. A hole may be formed, and a plurality of second injection holes may be formed at the bent end to inject some of the ammonia gas toward the outer circumference of the ammonia supply pipe.

The plurality of ammonia supply pipes may be spaced apart at equal intervals and may be arranged in a donut shape, and the plurality of ammonia supply pipes may be composed of three, and lines extending from the center of the first fuel supply unit are formed at intervals of 120 degrees from each other. It can be.

In addition, the present invention includes a combustor that receives fuel and combustion air and combusts it; A first fuel supply unit that supplies and injects liquid fuel or solid fuel, combustion air, and ammonia gas into the combustion furnace of the combustor and supplies liquid fuel or solid fuel to the recirculation area in the combustion furnace, and the first fuel An ammonia supply unit disposed outside the supply unit and supplying ammonia gas to the recirculation area within the combustion furnace, and a first combustion air supply unit disposed outside the ammonia supply unit and supplying air for primary combustion to the outside of the combustion area. burner; A fuel injector that supplies liquid fuel or solid fuel to the burner; Ammonia gas supplier for supplying ammonia gas to the burner; an evaporator installed on one side of the combustor, heated, and generating steam by evaporating water supplied from the outside; And an air injector for supplying air for combustion to the burner, wherein the ammonia supply unit for supplying ammonia gas from the inside of the first combustion air supply unit to the recirculation area is arranged to be spaced apart from the outer periphery of the first fuel supply unit. It includes a plurality of ammonia supply pipes, and at the ends of the plurality of ammonia supply pipes is an ammonia gas that controls the injection amount and injection angle of the ammonia gas to be differentially sprayed into the recirculation area toward the center and the outer direction of the ammonia supply pipe. Provided is a boiler facility characterized in that it is provided with a nozzle.

According to the burner according to the present invention and the boiler equipment including the same, ammonia gas is directly injected from the inside of the primary combustion air into the recirculation area of the combustion furnace in the combustor, so that ammonia gas is directly transferred to the recirculation area without colliding with the primary combustion air. By supplying gas, the recirculation area can be maintained at a low oxygen concentration to reduce the generation of nitrogen oxides, and by spraying ammonia gas from the center of the burner to the internal recirculation area, ammonia gas does not penetrate into the area where existing solid or liquid fuel is input. Therefore, the effect on flow and flame is minimized, so the stability of the liquid fuel flame is not impaired, and the ammonia gas sprayed by the ammonia nozzle mounted on the ammonia gas supply pipe that supplies ammonia gas is directed to the center and outside of the ammonia gas supply pipe. It has the advantage of being able to further reduce nitrogen oxides by differentially supplying and burning it.

Figure 1 is a block diagram showing the structure of a conventional low nitrogen oxide coal burner.
Figure 2 is a diagram schematically showing the process of supplying liquid fuel or solid fuel, ammonia gas, and combustion air to a burner according to an embodiment of the present invention.
Figure 3 is a perspective view showing the burner shown in Figure 2.
Figure 4 is an enlarged view showing main parts of the first fuel supply part, the ammonia supply part, and the second fuel supply part shown in Figure 3.
Figure 5 is a side view of the burner shown in Figure 3.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability.

Referring to FIGS. 2 and 3, the burner 100 according to an embodiment of the present invention is provided in a boiler facility (not shown) and flows liquid fuel or solid fuel, ammonia gas, and combustion air into the combustion furnace 210. It sprays while supplying, and the boiler equipment (not shown) includes a fuel injector (not shown) that supplies liquid fuel or solid fuel to the burner 100 according to an embodiment of the present invention, and an ammonia gas supplier that supplies ammonia gas. (not shown), an evaporator (not shown) installed on one side of the combustor 200 and heated to generate steam by evaporating water supplied from the outside, and an air injector (not shown) that supplies air for combustion. It is preferable, and since the boiler equipment (not shown) is general, detailed description thereof will be omitted.

The burner 100 according to an embodiment of the present invention is installed on one inner wall of the combustion furnace 210 and includes a first fuel supply unit 110, an ammonia supply unit 120, and a first combustion air supply unit 130. And, it may further include a second fuel supply unit 140 and a second combustion air supply unit 150.

Referring to FIG. 2, the first fuel supply unit 110 serves to supply liquid fuel or solid fuel supplied from the fuel injector (not shown) to the recirculation area in the combustion furnace 210, and the first fuel supply unit 110 The liquid fuel supplied to the recirculation area through the fuel supply unit 110 may be oil, and the solid fuel supplied to the recirculation area may be a mixture of pulverized coal and air.

An ammonia supply unit 120 is disposed outside the first fuel supply unit 110, and the ammonia supply unit 120 serves to supply ammonia gas to the recirculation area within the combustion furnace 210. By supplying ammonia gas to the recirculation area within the combustion furnace 210 through the ammonia supply unit 120, oxidation of nitrogen oxides due to low oxygen concentration in the recirculation area can be suppressed.

Referring to Figures 2 to 5, the ammonia supply unit 120 includes a plurality of ammonia gas supply pipes 121 arranged to be spaced apart from the outer periphery of the first fuel supply unit 110, and the plurality of ammonia gas supply pipes ( An ammonia nozzle 122 is installed at the end of the ammonia gas supply pipe 121 to spray ammonia gas moving into the recirculation area of the combustion furnace 210.

The ammonia nozzle 122 has a disk shape, and a bent edge 123 that is inclined to one side is formed at the end of the circumferential surface of the ammonia nozzle 122, which has a disk shape.

A first injection hole 122a is formed in the center of the ammonia nozzle 122, which sprays most of the ammonia gas moved into the ammonia gas supply pipe 121 into the recirculation area in front of the ammonia gas supply pipe 121, A plurality of second injection holes 123a are formed at the bent end 123 to supply some of the ammonia gas moved to the ammonia gas supply pipe 121 to the recirculation area on the outer circumference of the ammonia gas supply pipe 121.

The ammonia nozzle 122 serves to control the injection amount and injection angle of ammonia gas injected into the recirculation area of the combustion furnace 210 through the ammonia gas supply pipe 121. The same ammonia gas is not supplied to the recirculation area through the first injection hole (122a) and the second injection hole (123a), and most of the ammonia gas is supplied to the ammonia gas through the first injection hole (122a). It is supplied to the recirculation area through the front of the supply pipe 121, and some of the ammonia gas is injected and burned toward the outside of the ammonia gas supply pipe 121 through the second injection hole 123a, and then into the recirculation area. It is moved.

When all of the ammonia gas supplied through the ammonia gas supply pipe 121 is supplied to the recirculation area through the front of the ammonia gas supply pipe 121 through the first injection hole 122a of the ammonia nozzle 122, A problem may arise in that some of the supplied ammonia gas may not be burned. As in this embodiment, some of the ammonia gas supplied through the ammonia gas supply pipe 121 is injected through the second injection hole 123a of the ammonia nozzle 122 in the outer direction of the ammonia gas supply pipe 121. When the ammonia gas is burned outside the recirculation zone and then flows to the recirculation zone, nitrogen oxides are generated as the ammonia gas burns outside the recirculation zone. However, the nitrogen oxides generated are removed in the recirculation zone, which is the reduction zone, thereby minimizing the amount of ammonia gas that is not burned. At the same time, it also reduces the generation of additional nitrogen oxides.

Referring to Figures 4 and 5, three ammonia nozzles 122 in this embodiment are formed at intervals of 120 degrees based on the first fuel supply unit 110. The ammonia nozzles 122 in this embodiment are arranged at intervals of 120 degrees, but are not limited thereto. In addition, nitrogen oxides can be further reduced by differentially controlling the flow rate and spray angle of the ammonia nozzle 122.

The plurality of ammonia gas supply pipes 121 are spaced apart at equal intervals and are preferably arranged in a donut shape, but this is not limited to this and can be modified to have various shapes that are spaced at equal intervals rather than a donut shape. .

Referring to Figures 2 and 3, a first combustion air supply part 130 is disposed outside the ammonia supply part 120, and the first combustion air supply part 130 is directed to the recirculation area of the combustion furnace 210. It serves to supply air for primary combustion.

The first combustion air supply unit 130 supplies primary combustion air supplied from the outside at an angle toward the outside of the combustion furnace 210, thereby supplying it to the outside of the recirculation area of the combustion furnace 210.

Combustion air supplied into the first combustion air supply unit 130 through the plurality of air supply holes 131 provided on the other peripheral surface of the first combustion air supply unit 130 is the first combustion air supply unit 130. It is supplied to the outside of the recirculation area of the combustion furnace 210 through one end of (130).

A second fuel supply unit 140 is disposed between the ammonia supply unit 120 and the first combustion air supply unit 130, and the second fuel supply unit 140 selectively supplies solid fuel into the combustion furnace 210. It plays a role in supplying. The solid fuel supplied from the second fuel supply unit 140 is a mixture of pulverized coal and air.

The first fuel supply unit 110 and the ammonia supply unit 120 pass through the inside of the second fuel supply unit 140, and the second fuel supply unit 140 is inside the second fuel supply unit 140. A swirler 141 is provided for mixing pulverized coal, which is a mixture moving through the air, and the swirler 141 is used to connect the first fuel supply unit 110 and the ammonia supply unit inside the second fuel supply unit 140. It is preferably provided on the outer periphery of the case pipe (CP) surrounding (120) from the outside.

A second combustion air supply unit 150 is disposed outside the first combustion air supply unit 130, and the second combustion air supply unit 150 is supplied from the outside to the outside of the recirculation area of the combustion furnace 210. It serves to supply air for combustion of cars. Combustion air supplied into the second combustion air supply unit 150 through the plurality of external air supply holes 151 provided on the other peripheral surface of the second combustion air supply unit 150 is the second combustion air. It moves inside the supply unit 150 and is supplied to the outside of the recirculation area of the combustion furnace 210 through one end of the second combustion air supply unit 150.

1 supplied to one end of the first combustion air supply unit 130 and the second combustion air supply unit 150, which supply primary combustion air and secondary combustion air to the outside of the recirculation area of the combustion furnace 210. It is preferable that the first guide vane 132 and the second guide vane 152, which guide the moving direction of primary combustion air and secondary combustion air, are provided to be inclined outward.

The first guide vane 132 and the second guide vane 152 are provided inclined outward at one end of the first combustion air supply unit 130 and the second combustion air supply unit 150, respectively, thereby performing first combustion. The air for primary combustion and the air for secondary combustion moving to the air supply unit 130 and the second combustion air supply unit 150 are supplied to the outside of the recirculation area of the combustion furnace 210, and the second guide vane It is preferable that (152) is formed to protrude further into the interior of the combustion furnace (210) than the first guide vane (132).

Ammonia gas is directly injected from the inside of the first combustion air supply unit 130, which supplies air for primary combustion in the combustor 200, into the recirculation area of the combustion furnace 210 through the ammonia supply unit 120. Ammonia gas is supplied to the recirculation area without colliding with the primary combustion air, thereby maintaining the recirculation area at a low oxygen concentration and reducing the generation of nitrogen oxides.

In addition, by spraying ammonia gas from the center of the burner to the internal recirculation area, ammonia gas does not penetrate into the area where existing solid or liquid fuel is input, so the effect on flow and flame is minimized and the stability of the liquid fuel flame is not impaired. Ammonia gas sprayed by the ammonia nozzle 122 mounted on the ammonia gas supply pipe 121 of the ammonia supply unit 120 that supplies ammonia gas is differentially supplied to the center and the outer direction of the ammonia gas supply pipe 121 for combustion. Additional reduction of nitrogen oxides is possible by doing this.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

100: burner 110: first fuel supply unit
120: Ammonia supply unit 121: Ammonia gas supply pipe
122: Ammonia nozzle 123: Bend end
130: first combustion air supply unit 140: second fuel supply unit
150: second combustion air supply unit 200: combustor
210: combustion furnace

Claims (14)

In a burner that supplies liquid fuel or solid fuel, combustion air, and ammonia gas into the combustion furnace and injects and burns,
a first fuel supply unit that supplies liquid fuel or solid fuel to a recirculation area in the combustion furnace;
an ammonia supply unit disposed outside the first fuel supply unit and supplying ammonia gas to a recirculation area within the combustion furnace; and
It is disposed outside the ammonia supply unit and includes a first combustion air supply unit that supplies air for primary combustion to the outside of the combustion area,
The ammonia supply unit,
It includes a plurality of ammonia supply pipes arranged to be spaced apart from the outer periphery of the first fuel supply unit,
At the ends of the plurality of ammonia supply pipes, an ammonia nozzle is provided to control the injection amount and injection angle of ammonia gas to differentially spray ammonia gas toward the center and the outer direction of the ammonia supply pipe to the recirculation area. burner.
In claim 1,
It is disposed between the ammonia supply unit and the first combustion air supply unit, and further includes a second fuel supply unit that supplies solid fuel into the combustion furnace,
A burner, wherein the plurality of ammonia supply pipes are arranged parallel to the first fuel supply unit.
In claim 1,
A burner disposed outside the first combustion air supply unit and further comprising a second combustion air supply unit that supplies secondary combustion air to the outside of the area where the primary combustion air supplied from the first combustion air supply unit is burned. .
In claim 3,
A first guide vane and a second guide vane are formed at one end of the first combustion air supply unit and the second combustion air supply unit to be inclined outward,
The second guide vane is formed to protrude further into the interior of the combustion furnace than the first guide vane.
In claim 1,
The ammonia nozzle has a disk shape,
At the end of the ammonia nozzle, a bent end is formed that is inclined to one side,
A first injection hole is formed in the center of the ammonia nozzle for spraying ammonia gas toward the front of the ammonia supply pipe,
A burner in which a plurality of second injection holes are formed at the bent end to inject a portion of ammonia gas toward the outer circumference of the ammonia supply pipe.
In claim 1,
A burner, characterized in that the plurality of ammonia supply pipes are spaced apart at equal intervals and arranged in a donut shape.
In claim 1,
The burner is characterized in that the plurality of ammonia supply pipes consists of three, and the lines extending from the center of the first fuel supply unit are formed at intervals of 120 degrees.
A combustor that receives fuel and combustion air and combusts it;
A first fuel supply unit that supplies and injects liquid fuel or solid fuel, combustion air, and ammonia gas into the combustion furnace of the combustor and supplies liquid fuel or solid fuel to the recirculation area in the combustion furnace, and the first fuel An ammonia supply unit disposed outside the supply unit and supplying ammonia gas to the recirculation area within the combustion furnace, and a first combustion air supply unit disposed outside the ammonia supply unit and supplying air for primary combustion to the outside of the combustion area. burner;
A fuel injector that supplies liquid fuel or solid fuel to the burner;
Ammonia gas supplier for supplying ammonia gas to the burner;
an evaporator installed on one side of the combustor, heated, and generating steam by evaporating water supplied from the outside; and
Including an air injector that supplies combustion air to the burner,
The ammonia supply unit that supplies ammonia gas from the inside of the first combustion air supply unit to the recirculation area includes a plurality of ammonia supply pipes arranged to be spaced apart from the outer periphery of the first fuel supply unit,
At the ends of the plurality of ammonia supply pipes, an ammonia nozzle is provided for controlling the injection amount and injection angle of ammonia gas to differentially spray ammonia gas toward the center and the outer direction of the ammonia supply pipe to the recirculation area. Boiler equipment.
In claim 8,
The burner is,
It is disposed between the ammonia supply unit and the first combustion air supply unit, and further includes a second fuel supply unit that supplies solid fuel into the combustion furnace,
Boiler equipment, characterized in that the plurality of ammonia supply pipes are arranged in parallel with the first fuel supply unit.
In claim 8,
The burner is,
A boiler disposed outside the first combustion air supply unit and further comprising a second combustion air supply unit that supplies secondary combustion air to the outside of the area where the primary combustion air supplied from the first combustion air supply unit is burned. facility.
In claim 10,
A first guide vane and a second guide vane are formed at one end of the first combustion air supply unit and the second combustion air supply unit to be inclined outward,
The second guide vane is a boiler equipment formed to protrude further into the interior of the combustion furnace than the first guide vane.
In claim 8,
The ammonia nozzle has a disk shape,
At the end of the ammonia nozzle, a bent end is formed that is inclined to one side,
A first injection hole is formed in the center of the ammonia nozzle for spraying ammonia gas toward the front of the ammonia supply pipe,
A boiler equipment in which a plurality of second injection holes are formed at the bent end to inject a portion of ammonia gas toward the outer circumference of the ammonia supply pipe.
In claim 8,
A boiler facility characterized in that the plurality of ammonia supply pipes are spaced apart at equal intervals and are arranged in a donut shape.
In claim 8,
The boiler equipment is characterized in that the plurality of ammonia supply pipes consists of three, and the lines extending from the center of the first fuel supply section are formed at intervals of 120 degrees.

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