KR102012468B1 - Pulverized coal burner for pressurized pure oxygen - Google Patents

Abstract

The burner is started. More specifically, the first oxygen flow path unit 100 including a plurality of first oxygen nozzles 130; Located radially outward of the first oxygen flow path part 100, the first oxygen flow path part 100 covers the first oxygen flow path part 100, and includes a plurality of first oxygen nozzle holes 230 and a plurality of cooling water nozzles 240. Cooling water flow path 200; A fuel inlet part 300 positioned radially outward of the coolant flow path part 200 and including a fuel opening 330 formed along an outer surface 210 of the coolant flow path part 200; And a second oxygen flow path part 400 positioned radially outward of the fuel inlet part 300 and including a plurality of second oxygen nozzles 430, and the position of the first oxygen nozzle hole 230. Is formed to correspond to the position of the first oxygen nozzle 130, the first oxygen nozzle 130 is coupled through the first oxygen nozzle hole 230 to protrude to the outside of the cooling water flow path (200). The burner is started.

Description

Pulverized coal burner for pressurized pure oxygen}

The present invention relates to a burner, and more particularly, to a pressurized pure oxygen pulverized coal burner capable of increasing the inflow rate of pressurized pure oxygen used as an oxidant for combustion and increasing the mixing efficiency in the furnace. It is about.

Pure oxygen combustion technology is a technology that separates nitrogen from the air and uses it as an oxidant to burn fuel, and when applied to coal-fired power plants, many research and development is carried out as an eco-friendly power generation method that can sequester carbon dioxide and emit no greenhouse gas. It is becoming.

However, oxy-fuel combustion consumes a lot of power to produce oxygen, which leads to a loss of power generation efficiency of about 10%, and uses the existing combustion system concept. Therefore, it is necessary to supplement carbon dioxide as separated nitrogen through exhaust gas recirculation. In order to minimize this, a pressurized oxy-fuel combustion technique that pre-presses the entire flow through the combustion system and the exhaust gas has received much attention in recent years.

However, in the combustion system according to the pressurized pure oxygen combustion technology, the oxygen is pressurized and supplied to the combustion furnace, and thus the mixing with the fuel may be reduced because the momentum of oxygen, specifically, the inflow rate of oxygen, is reduced due to the high pressure of oxygen. have.

That is, the combustion efficiency can be maximized only by mixing well with the fuel through active movement of oxygen, and since the momentum of oxygen is lowered, there is a problem of lowering the combustion efficiency.

In addition, since pressurized pure oxygen combustion minimizes flue gas recirculation and uses only oxygen as the oxidant, the temperature of the flame is higher than that of a conventional combustion furnace using air as an oxidant. The tip may be damaged.

Korean Patent No. 10-0400418 discloses a low nitrogen oxide oxygen enriched combustion burner. Specifically, including a central air nozzle consisting of small nozzles, outer fuel nozzles disposed around the central air nozzle, outer air nozzles disposed around the central air nozzle, to maximize the suction rate of the gas in the combustion furnace and nitrogen oxides A combustion burner for reducing the amount of generated is disclosed.

As another example, Korean Patent Publication No. 10-1078842 discloses a pure oxygen pulverized coal combustion device. Specifically, the present invention discloses a pure oxygen pulverized coal combustion apparatus capable of rapidly injecting a small amount of high pressure oxygen into a fuel enrichment region formed near a primary oxidant injection position for pulverized coal and pulverized coal transfer to recycle exhaust gas.

These types of burners are intended to be applied to conventional atmospheric pressure oxy-fuel combustion, and a method for preventing a decrease in the rate of introduction of pressurized oxy-fuel in a combustion furnace has not been disclosed, and thus it is difficult to apply them to a pressure-oxygen combustion system.

In addition, there is no countermeasure for preventing damage to the oxygen nozzle tip due to the temperature of the flame which is higher than using air as the oxidant during pressurized pure oxygen combustion, and thus includes a problem that may occur in the pressurized pure oxygen combustion system. .

Korea Patent Registration No. 10-0400418 (2003.10.01) Korea Patent Registration No. 10-1078842 (Nov. 2, 2011)

An object of the present invention, in the pressurized pure oxygen burner using the pressurized pure oxygen as the oxidant for combustion, it is possible to improve the combustion efficiency by maximizing the mixing with the fuel by improving the inflow rate of the pressurized pure oxygen flowing into the combustion furnace. In addition, to provide a burner that can prevent damage to the oxygen nozzle tip according to the high flame temperature.

In order to achieve the above object, the present invention, the first oxygen flow path unit 100 including a plurality of first oxygen nozzle 130; Located radially outward of the first oxygen flow path part 100, the first oxygen flow path part 100 covers the first oxygen flow path part 100, and includes a plurality of first oxygen nozzle holes 230 and a plurality of cooling water nozzles 240. Cooling water flow path 200; A fuel inlet part 300 positioned radially outward of the coolant flow path part 200 and including a fuel opening 330 formed along an outer surface 210 of the coolant flow path part 200; And a second oxygen flow path part 400 positioned radially outward of the fuel inlet part 300 and including a plurality of second oxygen nozzles 430, and the position of the first oxygen nozzle hole 230. Is formed to correspond to the position of the first oxygen nozzle 130, the first oxygen nozzle 130 is coupled through the first oxygen nozzle hole 230 to protrude to the outside of the cooling water flow path (200). To provide a burner.

In addition, the spray angle of the coolant nozzle 240 may be adjusted.

In addition, it may further include a temperature sensor 250 positioned adjacent to the coolant nozzle 240.

In addition, the cooling water nozzle 240 may be opened and closed in a predetermined method according to the temperature sensed by the temperature sensor 250.

In addition, the outer diameter of the first oxygen nozzle 130 and the inner diameter of the first oxygen nozzle hole 230 may be the same.

In addition, the second oxygen nozzle 430 may be continuously formed to be spaced apart from the radiation of the second oxygen flow path part 400 by a predetermined distance.

According to the present invention, since a plurality of first oxygen nozzles into which pressurized pure oxygen used as an oxidant for combustion is introduced is formed in a small diameter, the rate at which pressurized pure oxygen is discharged from each first oxygen nozzle can be quickly controlled. Oxygen can flow into the furnace at high speed.

In addition, since a plurality of second oxygen nozzles into which additional pressurized pure oxygen is introduced is also formed in a small diameter, the rate of discharge of pressurized pure oxygen from each of the second oxygen nozzles can be quickly controlled, so that the additional pressurized pure oxygen can also be rapidly maintained in the combustion furnace. Can be introduced.

Therefore, by using the pressurized pure oxygen as the oxidant for combustion, by increasing the rate of inlet of the pressurized pure oxygen, it is possible to maximize the mixing of the pressurized pure oxygen and fuel to improve combustion efficiency.

Furthermore, since the cooling angle may be directly injected to the exposed portion of the first oxygen nozzle by adjusting the injection angle of the cooling water sprayed from the cooling water nozzle according to the temperature sensed by the temperature sensor, the first high temperature flame Damage to the exposed portion of the oxygen nozzle can be prevented.

1 is a side view of the inside of a combustion furnace including a pressurized pure oxygen burner according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the pressurized pure oxygen burner of FIG. 1.
3 is an exploded perspective view illustrating a first oxygen flow path part and a cooling water flow path part of the pressurized pure oxygen burner of FIG. 2.
4 is a perspective view illustrating a first oxygen flow path part and a cooling water flow path part of the pressurized pure oxygen burner of FIG. 2.
5 is a view showing a state in which the injection angle of the cooling water nozzle of the pressurized pure oxygen burner of FIG. 2 is adjusted.

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

Both main oxygen and auxiliary oxygen described below mean pressurized pure oxygen.

1 and 2, the burner 10 according to the embodiment of the present invention is installed on one side of the inner wall (2) of the furnace, and is formed in a circular cross section. The shape of the burner 10 is not limited thereto, and may have various other shapes such as polygons.

The burner 10 supplies main oxygen, cooling water, auxiliary oxygen and pulverized coal or carrier gas into the combustion furnace 1.

Description of the burner 10

1 to 4, the burner 10 according to an exemplary embodiment of the present invention may include a first oxygen flow path part 100, a coolant flow path part 200, a fuel inflow part 300, and a second oxygen flow path part ( 400).

The first oxygen flow path part 100 forms a passage through which main oxygen flows into the combustion furnace 1. In the illustrated embodiment, the first oxygen flow path part 100 is located inside the cooling water flow path part 200 to be described later. In other words, the first oxygen flow path part 100 is covered by the cooling water flow path part 200 and is not exposed to the inside of the combustion furnace 1.

The first oxygen flow path part 100 includes a plurality of first oxygen nozzles 130.

The first oxygen nozzle 130 forms a passage through which main oxygen introduced into the first oxygen flow path part 100 flows into the combustion furnace 1. In the illustrated embodiment, the first oxygen nozzle 130 is formed in a circular shape, but the shape of the first oxygen nozzle 130 is not limited thereto.

The first oxygen nozzle 130 is coupled to the first oxygen nozzle hole 230 to be described later. This will be described later.

2 to 4, the first oxygen nozzle 130 is randomly disposed in the first oxygen flow path part 100. Alternatively, the first oxygen nozzle 130 may be regularly formed on the first oxygen flow path part 100.

The plurality of first oxygen nozzles 130 can be opened and closed, respectively. Therefore, the flow rate of the main oxygen flowing into the combustion furnace 1 from the first oxygen nozzle 130 can be controlled.

In the illustrated embodiment, the first oxygen nozzle 130 is formed to have a small diameter. This is due to the present invention using pressurized pure oxygen as the oxidant.

In other words, according to Bernoulli's law, in the absence of external force, the energy of a fluid in flow includes energy due to pressure, kinetic energy, and potential energy. Assuming that the position is the same, the sum of energy due to pressure and kinetic energy is constant.

In the case of pressurized pure oxygen, the energy due to pressure is high, so that the kinetic energy is low and the flow rate is generally reduced.

At this time, the hourly flow rate of the fluid flowing in the tube is constant, which is expressed as the product of the cross-sectional area in the tube and the flow rate. In other words, if the cross-sectional area in the tube is reduced, the flow rate is increased in inverse proportion to this.

That is, by reducing the diameter of the first oxygen nozzle 130, the flow rate of the main oxygen reduced due to the increase in pressure can be compensated, so that the main oxygen can be introduced into the combustion furnace at a higher speed even when the same flow rate is supplied.

This is the same as the principle of reducing the diameter of the second oxygen nozzle 430 which will be described later in order to introduce auxiliary oxygen into the combustion furnace at a high speed.

The cooling water flow path part 200 forms a passage through which the cooling water and the main oxygen flow into the combustion furnace 1. In the illustrated embodiment, the cooling water flow path part 200 is positioned radially outward of the first oxygen flow path part and is formed to completely surround the first oxygen flow path part 100.

The cooling water flow path part 200 includes a plurality of first oxygen nozzle holes 230, a plurality of cooling water nozzles 240, and a temperature sensor 250.

The first oxygen nozzle 130 is penetrated through the first oxygen nozzle hole 230 to provide a passage through which the main oxygen introduced into the first oxygen flow path part 100 may pass through the cooling water flow path part 200.

3 and 4, the first oxygen flow path part 100 and the cooling water flow path part 200 may be combined.

At this time, the first oxygen nozzle 130 is coupled to the first oxygen nozzle hole 230 so that the exposed portion 132 of the first oxygen nozzle 130 is exposed into the combustion furnace 1. In other words, the first oxygen nozzle hole 230 forms a passage through which the first oxygen nozzle 130 may pass through the cooling water flow path part 200.

The first oxygen nozzle hole 230 may be formed to correspond to the position of the first oxygen nozzle 130 so that the first oxygen nozzle 130 may be penetrated through the first oxygen nozzle hole 230.

In addition, the outer diameter of the first oxygen nozzle 130 and the inner diameter of the first oxygen nozzle hole 230 is the same, when the first oxygen nozzle 130 is coupled to the first oxygen nozzle hole 230, The radially outer side of the first oxygen nozzle hole 230 may be completely sealed.

Therefore, when the first oxygen nozzle 130 is coupled to the first oxygen nozzle hole 230, main oxygen introduced into the first oxygen flow path part 100 may flow into the combustion furnace 1.

The first oxygen nozzle hole 230 is randomly disposed in the cooling water flow path part 200. Alternatively, the first oxygen nozzle hole 230 may be formed in a uniform arrangement, and in any case, the first oxygen nozzle hole 230 may be formed corresponding to the position of the first oxygen nozzle 130.

The coolant nozzle 240 forms a passage through which the coolant supplied to the coolant flow path part 200 flows into the combustion furnace 1.

The cooling water nozzle 240 is randomly disposed in the cooling water flow path part 200 so as not to overlap with the first oxygen nozzle hole 230. Alternatively, the coolant nozzle 240 may be regularly formed in the coolant flow path 200.

In any case, however, the cooling water nozzle 240 and the first oxygen nozzle hole 230 may be formed in the cooling water flow path part 200 to be adjacent to each other. This is to allow the exposed portion 132 of the first oxygen nozzle 130 to be cooled by the coolant sprayed from the coolant nozzle 240, as will be described later.

The spray angle of the coolant sprayed from the coolant nozzle 240 may be adjusted. Therefore, by spraying cooling water near the first oxygen nozzle 130, the exposed portion 132 of the first oxygen nozzle 130 may be prevented from being overheated and damaged (see FIG. 5).

The plurality of cooling water nozzles 240 can be opened and closed, respectively. Therefore, the flow rate of the cooling water flowing into the combustion furnace 1 from the cooling water nozzle 240 can be controlled.

In addition, the cooling water nozzle 240 is also formed to have a small diameter, it is possible to flow the cooling water into the combustion furnace at a high speed.

The temperature sensor 250 is positioned to be adjacent to the coolant nozzle 240 on the outside of the coolant flow path part 200. The temperature sensor 250 senses the temperature in the combustion furnace 1 and the temperature near the coolant nozzle 240.

In the illustrated embodiment, the temperature sensor 250 is provided as one, and alternatively, a plurality of temperature sensors 250 may be provided.

When the temperature sensed by the temperature sensor 250 is higher than the reference value, more coolant nozzles 240 are opened to increase the flow rate of the coolant flowing into the combustion furnace 1. When the temperature sensed by the temperature sensor 250 is lower than the reference value, some cooling water nozzles 240 are closed to reduce the flow rate of the cooling water flowing into the combustion furnace 1.

That is, whether or not the coolant nozzle 240 is opened or closed may be controlled according to the temperature sensed by the temperature sensor 250, and a coolant nozzle controller (not shown) may be further included for this purpose.

At this time, the reference value for determining the opening and closing of the coolant nozzle 240 may be determined in various ways according to the combustion environment and conditions.

The fuel inlet 300 provides a passage through which pulverized coal or carrier gas is introduced into the combustion furnace 1. In the illustrated embodiment, the fuel inlet 300 is located radially outward of the coolant flow path 200.

The fuel inlet 300 includes a fuel opening 330.

The fuel opening 330 is an open portion so that pulverized coal or carrier gas can be introduced into the combustion furnace 1. In the illustrated embodiment, the fuel opening 330 is formed along the outer surface 210 of the coolant flow path 200.

The pulverized coal or carrier gas introduced into the combustion furnace 1 through the fuel opening 330 is mixed with the main oxygen and the auxiliary oxygen introduced from the first oxygen nozzle 240 and the second oxygen nozzle 430 which will be described later and burned. do.

In another embodiment, when the fuel introduced into the combustion furnace 1 through the fuel opening 330 is a gas fuel other than pulverized coal fuel, only gaseous fuel may be introduced into the combustion furnace 1 without a carrier gas.

The second oxygen flow path unit 400 provides a passage through which auxiliary oxygen flows into the combustion furnace 1. In the illustrated embodiment, the second oxygen passage 400 is located radially outward of the fuel inlet 300.

The second oxygen flow path unit 400 includes a plurality of second oxygen nozzles 430.

The second oxygen nozzle 430 provides a passage through which auxiliary oxygen introduced into the second oxygen flow path part 400 flows into the combustion furnace 1. In the illustrated embodiment, the second oxygen nozzle 430 is formed in a circular shape, but the shape of the second oxygen nozzle 430 is not limited thereto.

In the illustrated embodiment, the second oxygen nozzle 430 is continuously formed at a predetermined distance apart from the radial direction of the second oxygen flow path part 400, and may be provided at any position capable of supplying auxiliary oxygen into the combustion furnace 1. Can be formed.

The diameter of the second oxygen nozzle 430 may be changed according to the flow rate and speed of the auxiliary oxygen introduced through the second oxygen nozzle 430. However, the diameter of the second oxygen nozzle 430 is preferably formed small so that the auxiliary oxygen can be introduced at a speed sufficient to mix with the fuel in the combustion furnace (1).

As described above, since the diameter of the second oxygen nozzle 430 is made small, the rate at which the auxiliary oxygen flows into the combustion furnace 1 may be increased.

The plurality of second oxygen nozzles 430 may be opened and closed, respectively. Therefore, the flow rate of the auxiliary oxygen flowing into the combustion furnace 1 from the second oxygen nozzle 430 can be controlled.

Description of the Combustion and Cooling Process of the First Oxygen Nozzle 240

Hereinafter, a process in which oxygen is introduced from a burner according to an embodiment of the present invention and a process of preventing damage to the first oxygen nozzle 240 by cooling water will be described in detail with reference to FIGS. 1 and 5.

Description of oxygen and fuel inflow, mixing process

Referring to FIG. 1, main oxygen flows into the first oxygen flow path part 100. At this time, the first oxygen flow path unit 100 and the cooling water flow path unit 200 are coupled, and thus, the plurality of first oxygen nozzles 130 are coupled through the plurality of first oxygen nozzle holes 230 to form main oxygen. To form an inlet passage.

The main oxygen introduced into the first oxygen flow path part 100 is supplied into the combustion furnace 1 through the plurality of first oxygen nozzles 130.

At this time, since the diameter of the first oxygen nozzle 130 is made small, the main oxygen flows into the combustion furnace 1 from the first oxygen nozzle 130 at high speed.

In addition, as the inflow rate of the main oxygen increases, the momentum of the main oxygen increases, so that it can be evenly distributed in the combustion furnace 1.

In addition, pulverized coal or a carrier gas is introduced through the fuel opening 330 of the fuel inlet 300. As described above, the fuel opening 330 is formed radially outward along the outer surface 210 of the cooling water flow path part 200, and is formed as an open space instead of a nozzle, and thus combustion is slower than the inflow rate of the main oxygen. It may be introduced into the furnace (1).

The pulverized coal or carrier gas introduced into the combustion furnace 1 is mixed with main oxygen and combustion occurs.

At this time, as the momentum of the main oxygen increases, it is possible to mix with the pulverized coal or the carrier gas evenly, and the mixture of the pulverized coal or the carrier gas and the main oxygen is also distributed evenly in the combustion furnace 1, so that the combustion efficiency can be increased.

On the other hand, auxiliary oxygen also flows in the plurality of second oxygen nozzles 430 of the second oxygen flow path part 400. At this time, since the diameter of the second oxygen nozzle 430 is also small, auxiliary oxygen flows into the combustion furnace 1 from the second oxygen nozzle 430 at high speed.

Therefore, the momentum of the auxiliary oxygen is increased and distributed evenly in the combustion furnace 1, as well as the main oxygen and pulverized coal or a mixture of carrier gas and auxiliary oxygen are also distributed evenly in the combustion furnace 1, so that the combustion efficiency can be increased. .

That is, even under pressurized pure oxygen combustion conditions, since the main oxygen and the auxiliary oxygen are supplied into the combustion furnace 1 through the first oxygen nozzle 130 and the second oxygen nozzle 430, the inflow rate of the main oxygen and the auxiliary oxygen increases. Can be.

By increasing the inflow rate of the main oxygen and auxiliary oxygen, the momentum of the main oxygen and auxiliary oxygen is increased to maximize the mixing of oxygen and pulverized coal or carrier gas.

Description of the cooling process of the first oxygen nozzle 240

As described above, the plurality of first oxygen nozzles 130 are penetrated through the plurality of first oxygen nozzle holes 230 to form an inflow passage of main oxygen.

At this time, damage due to the high temperature of the exposed portion 132 of the first oxygen nozzle 130 protruding from the cooling water flow path part 200 into the combustion furnace 1 is problematic.

Referring to FIG. 5, an injection angle of the coolant injected into the combustion furnace 1 from the coolant nozzle 240 may be adjusted. In particular, the spray angle of the coolant may be adjusted so that the coolant may be directly injected into the exposed portion 132 of the first oxygen nozzle 130.

When the temperature in the combustion furnace 1 sensed by the temperature sensor 250 and the temperature near the coolant nozzle 240 are higher than the reference value, the coolant spray angle of the coolant nozzle 240 is an exposed portion of the first oxygen nozzle 130. Adjusted to spray coolant directly toward 132.

That is, the coolant spray angle of the coolant nozzle 240 may be adjusted according to the temperature detected by the temperature sensor 250, and a coolant nozzle controller (not shown) may be further included for this purpose.

At this time, the reference value for adjusting the injection angle of the coolant nozzle 240 may be determined in various ways according to the combustion environment and conditions.

Therefore, when damage due to heat due to pressurized pure oxygen combustion of the exposed portion 132 of the first oxygen nozzle 130 is expected, the cooling water is directly sprayed to the exposed portion 132 of the first oxygen nozzle 130 to cool. Thus, damage to the exposed portion 132 of the first oxygen nozzle 130 can be prevented even under high temperature combustion conditions.

In addition, as described above, since the cooling water injected from the cooling water nozzle 240 may also be injected at a high speed, the exposed portion 132 of the first oxygen nozzle 130 may be cooled rapidly.

Although it has been described above with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention described in the claims below. It will be appreciated.

1: combustion furnace
2: combustion furnace inner wall
10: burner
100: first oxygen flow path portion
130: first oxygen nozzle
132: exposed part
200: cooling water flow path
210: outer side
230: first oxygen nozzle hole
240: coolant nozzle
250: temperature sensor
300: fuel inlet
330 fuel opening
400: second oxygen flow path portion
430: second oxygen nozzle

Claims (6)

A first oxygen flow path part 100 including a plurality of first oxygen nozzles 130;
Located in the radially outer side of the first oxygen flow path unit 100, a plurality of cooling water nozzles covering the first oxygen flow path unit 100, the plurality of first oxygen nozzle hole 230 and the injection angle ( Cooling water flow path unit 200 including 240;
A fuel inlet part 300 positioned radially outward of the coolant flow path part 200 and including a fuel opening 330 formed along an outer surface 210 of the coolant flow path part 200; And
Located on the radially outer side of the fuel inlet 300, and includes a second oxygen flow path unit 400 including a plurality of second oxygen nozzle 430,
The position of the first oxygen nozzle hole 230 is formed corresponding to the position of the first oxygen nozzle 130,
The first oxygen nozzle 130 penetrates through the first oxygen nozzle hole 230 to protrude out of the cooling water flow path part 200.
burner.
delete The method of claim 1,
Further comprising a temperature sensor 250 located adjacent to the coolant nozzle 240,
burner.
The method of claim 3,
The cooling water nozzle 240 may be opened and closed in a predetermined manner according to the temperature sensed by the temperature sensor 250.
burner.
The method of claim 1,
The outer diameter of the first oxygen nozzle 130 and the inner diameter of the first oxygen nozzle hole 230 is the same,
burner.
The method of claim 1,
The second oxygen nozzle 430 is continuously formed to be spaced apart a predetermined distance on the radiation of the second oxygen flow path unit 400,
burner.

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