KR102485928B1 - Air supplying apparatus and method of hybrid power generation equipment - Google Patents

Abstract

In the air supply device of a hybrid power generation facility that supplies combustion gas generated from a gas turbine that sucks air from the outside, compresses it, and mixes the compressed air with fuel for combustion, to a boiler, the combustion gas is selectively supplied from the gas turbine receiving mixing chamber; an air preheater supplying air to the mixing chamber; a burner for burning the fluid supplied from the mixing chamber; a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater; a first line connecting the gas turbine and the mixing chamber; and a second line connecting the gas turbine and the first excess air supplier.

Description

Air supplying apparatus and method of hybrid power generation equipment

The present invention relates to an air supply device and an air supply method for a hybrid power generation facility, and more particularly, in a hybrid power generation facility that generates power using power generated by driving a gas turbine and a steam turbine, air and combustion It relates to an air supply device and air supply method of a hybrid power generation facility that supplies gas.

Generally, the types of power plants are classified according to the fuel used. As a typical example, a thermal power plant heats water in a boiler using thermal energy generated by burning fuel such as coal, heavy oil, and natural gas in a boiler, and passes the high-temperature, high-pressure, superheated steam produced through the boiler to a steam turbine to operate a steam turbine. Electricity is produced by a generator connected to the

In addition to the above-mentioned facilities, thermal power plants include main and auxiliary equipment (Balance of Plant, BOP), that is, fuel supply and treatment systems, condensate and water supply systems, cooling water systems, reprocessing systems, and other utility facilities (Air, Service Water, Water/Waste Water). Treatment System) and plays a role in electricity production.

On the other hand, combined cycle power generation is power generation by first turning a gas turbine using fuel such as natural gas or diesel, and passing the heat of the exhaust gas from the gas turbine back through a heat recovery steam generator (HRSG). It produces steam and turns the second steam turbine to generate electricity. Combined cycle power generation has the advantage of being about 10% higher in thermal efficiency than conventional thermal power generation because it generates power in two cycles, and has less pollution and a shorter restart time after stopping.

Referring to FIG. 1, the air supply device 10 of a conventional hybrid power generation facility supplies oxygen to the burner 12 and the excess air supplier 13 (OFA) regardless of whether combustion gas generated in the gas turbine 11 is input. A mixed fluid of combustion gas and air having the same concentration is supplied. According to the air supply device 10 of such a conventional hybrid power plant, since the oxygen concentration required by the burner 12 is limited for combustion stability, the amount of combustion gas input is limited, so that excess combustion gas is discharged to the stack 14 Accordingly, there is a problem in that the efficiency of the entire facility is reduced. In addition, according to the conventional air supply device 10 of the hybrid power generation facility, when the combustion gas is not input, the flow rate of the excess air supply device 13 is reduced and the penetration effect is reduced, resulting in an increase in pollutants generated from the facility. there is

Registered Patent No. 10-1685772 (2016.12.06. Registration) ‘Duct unit and coal furnace system of thermal power plant using it’

The present invention was developed to solve the above problems, and the amount of combustion gas supplied to the mixing chamber and the excess air supply is adjusted according to the purpose to improve the efficiency of the facility and reduce pollutants. Air supply of a hybrid power generation facility The purpose is to provide a device and air supply method.

The present invention is an air supply device of a hybrid power generation facility that supplies combustion gas generated in a gas turbine that sucks in air from the outside, compresses it, and mixes the compressed air with fuel to burn it, to a boiler. Mixing chamber receiving combustion gas; an air preheater supplying air to the mixing chamber; a burner for burning the fluid supplied from the mixing chamber; a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater; a first line connecting the gas turbine and the mixing chamber; and a second line connecting the gas turbine and the first excess air supplier.

The second line may be branched off from the first line and connected to the first excess air supplier.

The air supply device of the hybrid power plant according to the present invention may further include a third line connecting the air preheater and the mixing chamber, and a fourth line branched from the third line and connected to the second line.

The air supply device of a hybrid power generation facility according to the present invention includes a second excess air supplier selectively receiving combustion gas from the gas turbine, and a fifth line branched from the second line and connected to the second excess air supplier can include more.

In the first mode, the gas turbine is not operated, air is supplied from the air preheater to the mixing chamber through the third line, and air is supplied from the air preheater to the first excess air supplier through a fourth line. can be supplied.

An air supply device of a hybrid power generation facility according to the present invention includes a second excess air supplier selectively supplied with combustion gas from the gas turbine, a fifth line branched from the second line and connected to the second excess air supplier, , Further comprising a third damper installed on the fourth line to selectively open and close the fourth line, and in the second mode, through the first line, second line and fifth line from the gas turbine, respectively Combustion gas is supplied to the mixing chamber, the first excess air supplier and the second excess air supplier, the third damper closes the fourth line, and the air preheater supplies air to the mixing chamber through the third line. can supply

An air supply device of a hybrid power generation facility according to the present invention includes a second excess air supplier selectively supplied with combustion gas from the gas turbine, a fifth line branched from the second line and connected to the second excess air supplier, , It further includes a second damper installed on the first line to selectively open and close the first line, and a third damper installed on the fourth line to selectively open and close the fourth line, in the third mode , The second damper closes the first line, and combustion gas is supplied from the gas turbine to the first excess air supplier and the second excess air supplier through the second and fifth lines, respectively. The third damper closes the fourth line, and the air preheater may supply air to the mixing chamber through the third line.

The air supply device of the hybrid power plant according to the present invention includes a second damper installed in the first line to selectively open and close the first line, and a second damper installed at the outlet of the mixing chamber to control the temperature of the fluid supplied to the burner It may further include a temperature sensor for measuring, and in the second mode, the second damper may adjust an opening amount such that the measured value of the temperature sensor is equal to or less than a preset reference temperature.

The air supply device of the hybrid power plant according to the present invention further includes an oxygen sensor installed in the mixing chamber and measuring an oxygen concentration inside the mixing chamber, and in the second mode, the second damper is the temperature sensor The amount of opening may be firstly adjusted so that the measured value of the oxygen sensor is equal to or less than a preset reference temperature, and then the amount of release may be secondarily adjusted so that the measured value of the oxygen sensor is equal to or greater than the preset reference concentration.

The air supply device of the hybrid power plant according to the present invention further includes a first damper installed on the fifth line and selectively opening and closing the fifth line, and in the second mode, the first damper is open. It is possible to adjust the amount of combustion gas supplied to the first excess air supplier and the second excess air supplier by adjusting the amount.

In addition, the present invention, the mixing chamber that receives the combustion gas selectively supplied from the gas turbine for inhaling and compressing air from the outside, mixing and burning the compressed air with fuel; an air preheater supplying air to the mixing chamber; a burner for burning the fluid supplied from the mixing chamber; a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater; a first line connecting the gas turbine and the mixing chamber; And a second line connecting the gas turbine and the first excess air supply unit; The amount of combustion gas flowing through the line and the second line can be adjusted.

The air supply device of the hybrid power plant further includes a third line connecting the air preheater and the mixing chamber, and a fourth line branched from the third line and connected to the second line, in a first mode, The gas turbine is not operated, and air may be supplied from the air preheater to the mixing chamber through the third line, and air may be supplied from the air preheater to the first excess air supplier through a fourth line.

The air supply device of the hybrid power plant includes a third line connecting the air preheater and the mixing chamber, a fourth line branched from the third line and connected to the second line, and a combustion gas selectively from the gas turbine A second excess air supply unit receiving the supply, a fifth line branched off from the second line and connected to the second excess air supply unit, and a third damper installed on the fourth line to selectively open and close the fourth line. In the second mode, combustion gas is supplied from the gas turbine to the mixing chamber, the first excess air supplier, and the second excess air supplier through the first line, the second line, and the fifth line, respectively, ,

The third damper closes the fourth line, and the air preheater supplies air to the mixing chamber through the third line.

The air supply device of the hybrid power plant includes a third line connecting the air preheater and the mixing chamber, a fourth line branched from the third line and connected to the second line, and a combustion gas selectively from the gas turbine A second excess air supply unit receiving the supply, a fifth line branched off from the second line and connected to the second excess air supply unit, and a third damper installed on the fourth line to selectively open and close the fourth line. In the third mode, the second damper closes the first line, and the first excess air supply and the second excess air supply from the gas turbine through the second and fifth lines, respectively Combustion gas is supplied to the furnace, the third damper closes the fourth line, and the air preheater may supply air to the mixing chamber through the third line.

The air supply device of the hybrid power plant includes a second damper installed in the first line to selectively open and close the first line, and a temperature installed at the outlet of the mixing chamber to measure the temperature of the fluid supplied to the burner. A sensor may be further included, and in the second mode, the opening amount of the second damper may be adjusted such that a measured value of the temperature sensor is equal to or less than a preset reference temperature.

The air supply device of the hybrid power plant further includes an oxygen sensor installed in the mixing chamber and measuring an oxygen concentration inside the mixing chamber, and in the second mode, the second damper measures the temperature sensor After the opening amount is firstly adjusted to be equal to or less than the predetermined reference temperature, the opening amount may be secondarily adjusted so that the measured value of the oxygen sensor is equal to or greater than the predetermined reference concentration.

The air supply device of the hybrid power plant further includes a first damper installed on the fifth line and selectively opening and closing the fifth line, and in the second mode, the first damper adjusts an opening amount. Thus, the amount of combustion gas supplied to the first excess air supplier and the second excess air supplier can be adjusted.

According to the air supply device and air supply method of a hybrid power plant according to the present invention, by having a first line connecting a gas turbine and a mixing chamber, and a second line branched from the first line and supplied to the first excess air supplier In the combustion gas-air mixing operation mode (second mode) in which both the gas turbine and the air preheater operate, the amount of combustion gas flowing along the first and second lines is adjusted so that the oxygen concentration in the mixing chamber is combustible It can be made to indicate more than the minimum value, and through this, the overall operating efficiency of the facility can be improved. In addition, according to the present invention, in the pure air operation mode (first mode) in which the gas turbine does not operate, air flows only through the first excess air supplier to improve the penetration effect of the first excess air supplier, thereby improving Pollutants generated can be reduced.

1 is a system diagram of an air supply system of a conventional hybrid power plant.
2 is a system diagram of an air supply system of a hybrid power plant according to an embodiment of the present invention.
3 is a view showing the operation of the air supply device of the hybrid power plant shown in FIG. 2 in the first mode.
4 is a view showing the operation of the air supply device of the hybrid power plant shown in FIG. 2 in the second mode.
5 is a view showing the operation of the air supply device of the hybrid power plant shown in FIG. 2 in the third mode.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

A hybrid power generation facility is a facility that performs combined power generation using a gas turbine 110 using natural gas as fuel and a steam turbine using coal as fuel. Specifically, the gas turbine 110 takes in air from the outside, compresses it, and mixes the compressed air with natural gas for combustion. To this end, the gas turbine 110 may include a compressor (not shown), a combustor (not shown), and a turbine (not shown). The compressor sucks in air from the outside and compresses it. The combustor mixes compressed air supplied from the compressor with fuel and combusts it. The turbine generates power for power generation by passing the first combustion gas supplied from the combustor into the inside. The steam turbine generates power for power generation by passing high-temperature steam generated by evaporating water using thermal energy generated by combustion of fuel to the inside.

Referring to FIG. 2, an air supply device 100 of a hybrid power plant according to an embodiment of the present invention is a device for supplying air and combustion gas in the hybrid power plant, and includes a mixing chamber 111 and an air preheater 112 ), burner 113, first excess air supplier 114, second excess air supplier 115, first line 120, second line 121, third line 122, fourth line ( 123), the fifth line 124, the sixth line 125, the first damper 130, the second damper 131, the third damper 132, the temperature sensor 133, and the oxygen sensor 134. include

The mixing chamber 111 is selectively supplied with the first combustion gas from the gas turbine 110 . The mixing chamber 111 mixes the air supplied from the air preheater 112 with the first combustion gas.

The air preheater 112 (GAH; Gas-Air Heater) supplies air to the mixing chamber 111, and as the second combustion gas generated and discharged from the boiler (not shown) passes therein, The air passing through the air preheater 112 is heated by exchanging heat with the second combustion gas.

The burner 113 is installed in a boiler and burns a mixture of supplied first combustion gas, air and fuel (ex. coal), or a mixture of only air and fuel. In addition, water is heated with thermal energy generated by combustion of the burner 113 to generate steam, and the generated steam passes through a steam turbine (not shown) to generate power for power generation.

The first excess air supplier 114 selectively receives fluid from the gas turbine 110 or the air preheater 112, and supplies over-firing air (OFA) to the boiler. The second excess air supplier 115 selectively receives first combustion gas from the gas turbine 110 .

The first line 120 connects the gas turbine 110 and the mixing chamber 111 . The second line 121 connects the gas turbine 110 and the first excess air supplier 114, and is branched off from the first line 120 and connected to the first excess air supplier 114 do. The third line 122 connects the air preheater 112 and the mixing chamber 111 . The fourth line 123 is branched off from the third line 122 and connected to the second line 121 . The fifth line 124 is branched off from the second line 121 and connected to the second excess air supplier 115 . The sixth line 126 connects the mixing chamber 111 and the burner 113.

The first damper 130 is installed on the second line 121 and selectively opens and closes the second line 121 . The second damper 131 is installed on the first line 120 and selectively opens and closes the first line 120 . The third damper 132 is installed on the fourth line 123 and selectively opens and closes the fourth line 123 .

The temperature sensor 133 is installed in the sixth line 125 and measures the temperature of the mixture at the outlet of the mixing chamber 111 . The oxygen sensor 134 is installed in the mixing chamber 111 and measures the oxygen concentration inside the mixing chamber 111 .

Referring to FIG. 3, in the first mode (pure air operation mode) of the present invention, the gas turbine 110 and the second excess air supplier 115 are not operated, and the first damper 130 and the second 2 Damper 131 is closed. Accordingly, no first combustion gas flows through the first line 120, the second line 121, and the fifth line 124. And in the first mode, air is supplied from the air preheater 112 to the mixing chamber 111 through the third line 122, and from the air preheater 112 through the fourth line 123 All remaining air not supplied to the burner 113 is supplied to the first excess air supplier 114 . Coal fuel may be separately supplied to the mixing chamber 111 . Accordingly, the mixing chamber 111 supplies the mixture to the burner 113 through the sixth line 125 after mixing fuel and air.

The first mode is an operation mode under the minimum load condition of the facility, in which air is supplied only to the first excess air supplier 114 and air is not supplied to the second excess air supplier 115. The penetration effect in the excess air supplier 114 is improved.

4, in the second mode (combustion gas-air mixing operation mode) of the present invention, the first line 120, the second line 121 and the fifth line 124 from the gas turbine 110 ) through which the first combustion gas is supplied to the mixing chamber 111, the first excess air supplier 114, and the second excess air supplier 115, respectively, and the third damper 132 is connected to the fourth line ( 123) is closed, and the air preheater 112 supplies air to the mixing chamber 111 through the third line 122.

The second mode is an operation mode under the maximum load condition of the facility, and in the second mode, an energy storage system (ESS) or a carbon capture storage system (CCS) (CCS) and Storage system) may be used together.

In the second mode, the second damper 131 adjusts the opening amount so that the measured value of the temperature sensor 133 is equal to or less than a preset reference temperature. More specifically, in the second mode, the second damper 131 first adjusts the opening amount so that the measured value of the temperature sensor 133 is equal to or less than a preset reference temperature, and then the oxygen sensor ( 134), the opening amount is secondarily adjusted so that the measured value is equal to or greater than the preset reference concentration (eg, 13%). In addition, the first damper 130 adjusts the amount of the first combustion gas supplied to the first excess air supplier 114 and the second excess air supplier 115 by adjusting the opening amount.

According to such an embodiment of the present invention, in the second mode, by adjusting the amount of the first combustion gas flowing along the first line 120 and the second line 121, the mixing chamber 111 It is possible to make the oxygen concentration of more than the minimum combustible value, and through this, the overall operating efficiency of the facility can be improved.

Referring to FIG. 5, in the third mode, the second damper 131 closes the first line 120, and the second line 121 and the fifth line 124 from the gas turbine 110 ) through which the first combustion gas is supplied to the first excess air supplier 114 and the second excess air supplier 115, respectively. And in the third mode, the third damper 132 closes the fourth line 123, and the air preheater 112 supplies air to the mixing chamber 111 through the third line 122. supply

The third mode is an operating condition in which the gas turbine 110 performs a fast start under the maximum load condition of the boiler or steam turbine. In this third mode, since the conditions (flow rate, oxygen concentration, temperature) of the first combustion gas discharged from the gas turbine 110 change rapidly, only pure air is introduced into the burner 113, and the The first excess air supplier 114 and the second excess air supplier 115 supply all of the first combustion gas discharged from the gas turbine 110 .

However, this describes the initial operation of the third mode, and when the load of the gas turbine 110 exceeds a predetermined reference load value, the second damper 131 is opened and the first line 120 Through this, the first combustion gas may be supplied to the mixing chamber 111 and the burner 113. And, in the third mode, the third damper 132 is also opened when necessary so that a predetermined amount of air can be supplied to the first excess air supplier 114 .

100: air supply device of hybrid power generation facility 110: gas turbine
111: mixing chamber 112: air supplier
113: burner 114: first excess air supplier
115: second excess air supplier 120: first line
121: second line 122: third line
123: 4th line 124: 5th line
125: 6th line 130: 1st damper
131: second damper 132: third damper
133: temperature sensor 134: oxygen sensor

Claims (17)

In the air supply device of a hybrid power generation facility for supplying combustion gas generated in a gas turbine that sucks air from the outside, compresses it, and mixes the compressed air with fuel for combustion, to a boiler,
a mixing chamber selectively receiving combustion gas from the gas turbine;
an air preheater supplying air to the mixing chamber;
a burner for burning the fluid supplied from the mixing chamber;
a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater;
a first line connecting the gas turbine and the mixing chamber;
a second line connecting the gas turbine and the first excess air supplier;
a third line connecting the air preheater and the mixing chamber;
a fourth line branched off from the third line and connected to the second line;
a second excess air supplier selectively receiving combustion gas from the gas turbine;
a fifth line branched off from the second line and connected to the second excess air supplier;
a third damper installed on the fourth line to selectively open and close the fourth line;
A second damper installed on the first line to selectively open and close the first line;
a temperature sensor installed at the outlet of the mixing chamber to measure the temperature of the fluid supplied to the burner; and
an oxygen sensor installed in the mixing chamber and measuring an oxygen concentration inside the mixing chamber; Including more,
In the second mode,
Combustion gas is supplied from the gas turbine to the mixing chamber, the first excess air supplier, and the second excess air supplier through the first line, the second line, and the fifth line, respectively;
The third damper closes the fourth line, the air preheater supplies air to the mixing chamber through the third line,
The second damper adjusts the opening amount so that the measured value of the temperature sensor is equal to or less than a preset reference temperature,
The second damper first adjusts the opening amount so that the measured value of the temperature sensor is equal to or less than a preset reference temperature, and then secondarily adjusts the opening amount so that the measured value of the oxygen sensor is equal to or greater than a preset reference concentration. Air supply device for hybrid power plant.
The method of claim 1,
The second line is branched from the first line and connected to the first excess air supplier. delete The method of claim 1,
A second excess air supplier selectively receiving combustion gas from the gas turbine;
The air supply device of the hybrid power plant further comprising a fifth line branched off from the second line and connected to the second excess air supplier. The method of claim 1,
In the first mode,
The gas turbine is not operating,
The air supply device of the hybrid power generation facility in which air is supplied from the air preheater to the mixing chamber through the third line, and air is supplied from the air preheater to the first excess air supplier through a fourth line.
delete The method of claim 1,
A second excess air supplier selectively receiving combustion gas from the gas turbine;
A fifth line branched off from the second line and connected to the second excess air supplier;
A second damper installed on the first line to selectively open and close the first line;
Further comprising a third damper installed on the fourth line to selectively open and close the fourth line,
In the third mode,
The second damper closes the first line, and combustion gas is supplied from the gas turbine to the first excess air supplier and the second excess air supplier through the second and fifth lines, respectively;
The third damper closes the fourth line, and the air preheater supplies air to the mixing chamber through the third line.
delete delete The method of claim 1,
It is installed on the second line and further includes a first damper selectively opening and closing the second line,
In the second mode,
The first damper controls the amount of combustion gas supplied to the first excess air supplier and the second excess air supplier by adjusting the opening amount. a mixing chamber that receives combustion gas selectively from a gas turbine that takes air in from the outside, compresses it, and mixes the compressed air with fuel for combustion; an air preheater supplying air to the mixing chamber; a burner for burning the fluid supplied from the mixing chamber; a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater; a first line connecting the gas turbine and the mixing chamber; a second line connecting the gas turbine and the first excess air supplier; a third line connecting the air preheater and the mixing chamber; a fourth line branched off from the third line and connected to the second line; a second excess air supplier selectively receiving combustion gas from the gas turbine; a fifth line branched off from the second line and connected to the second excess air supplier; and a third damper installed on the fourth line to selectively open and close the fourth line. In the air supply method of the hybrid power plant using the air supply device of the hybrid power plant comprising a,
Adjusting the amount of combustion gas flowing through the first line and the second line based on the oxygen concentration inside the mixing chamber,
In the second mode,
Combustion gas is supplied from the gas turbine to the mixing chamber, the first excess air supplier, and the second excess air supplier through the first line, the second line, and the fifth line, respectively;
The third damper closes the fourth line, and the air preheater supplies air to the mixing chamber through the third line. The method of claim 11,
The air supply device of the hybrid power plant,
In the first mode,
The gas turbine is not operating,
Air is supplied from the air preheater to the mixing chamber through the third line, and air is supplied from the air preheater to the first excess air supplier through a fourth line.
delete a mixing chamber that receives combustion gas selectively from a gas turbine that takes air in from the outside, compresses it, and mixes the compressed air with fuel for combustion; an air preheater supplying air to the mixing chamber; a burner for burning the fluid supplied from the mixing chamber; a first excess air supplier selectively receiving fluid from the gas turbine or the air preheater; a first line connecting the gas turbine and the mixing chamber; a second damper installed on the first line to selectively open and close the first line; and a second line connecting the gas turbine and the first excess air supplier. A third line connecting the air preheater and the mixing chamber, a fourth line branched from the third line and connected to the second line, and a second excess air supplier selectively receiving combustion gas from the gas turbine. , Air supply device of a hybrid power generation facility including a fifth line branched off from the second line and connected to the second excess air supplier, and a third damper installed on the fourth line to selectively open and close the fourth line. In the air supply method of a hybrid power generation facility using,
Adjusting the amount of combustion gas flowing through the first line and the second line based on the oxygen concentration inside the mixing chamber,
In the third mode,
The second damper closes the first line, and combustion gas is supplied from the gas turbine to the first excess air supplier and the second excess air supplier through the second and fifth lines, respectively;
The third damper closes the fourth line, and the air preheater supplies air to the mixing chamber through the third line. The method of claim 11,
The air supply device of the hybrid power plant includes a second damper installed in the first line to selectively open and close the first line, and a temperature installed at the outlet of the mixing chamber to measure the temperature of the fluid supplied to the burner. Including more sensors,
In the second mode,
The air supply method of the hybrid power generation facility, wherein the second damper adjusts the opening amount so that the measured value of the temperature sensor is equal to or less than a preset reference temperature. The method of claim 15
The air supply device of the hybrid power plant further includes an oxygen sensor installed in the mixing chamber and measuring an oxygen concentration inside the mixing chamber,
In the second mode,
The second damper first adjusts the opening amount so that the measured value of the temperature sensor is equal to or less than a preset reference temperature, and then secondarily adjusts the opening amount so that the measured value of the oxygen sensor is equal to or greater than a preset reference concentration. Air supply method of hybrid power plant. The method of claim 11,
The air supply device of the hybrid power plant further includes a first damper installed on the second line and selectively opening and closing the second line,
In the second mode,
The air supply method of the hybrid power generation facility, wherein the first damper adjusts the amount of combustion gas supplied to the first excess air supplier and the second excess air supplier by adjusting the opening amount.

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