KR102574462B1 - Combined cycle power generation system - Google Patents

Abstract

The present invention relates to a compressor for compressing cooling air introduced from the outside, a combustor connected to an outlet of the compressor and discharging combustion gas by burning compressed air compressed by the compressor and fuel provided from the outside, and discharged from the combustor. A gas turbine unit including a turbine in which a plurality of turbine blades rotating by combustion gas are installed; an exhaust heat recovery boiler unit generating steam by using the exhaust gas generated in the gas turbine unit; a steam turbine unit generating rotational force by using the steam generated in the heat recovery boiler unit; a condensing unit that resupplies condensed water obtained by condensing the steam discharged from the steam turbine unit to the heat recovery boiler unit; and an absorption chiller unit for cooling external air and supplying it to the compressor, wherein the absorption chiller unit includes a pump for pressurizing the diluted absorbent liquid, an absorption reheater for raising the temperature of the diluted absorbent liquid and separating it into steam and concentrated absorbent liquid, and in the absorption reheater An absorption condenser for condensing the steam by exchanging heat between the separated steam and the condensed water supplied from the condensing unit, and heat exchange between the condensed water condensed in the absorption condenser and external air to evaporate the condensed water to generate steam and the external air an absorption evaporator that cools the absorption evaporator, an absorber that mixes the steam generated in the absorption evaporator with the concentrated absorbent liquid separated from the absorption reheater to generate a diluted absorbent liquid, and supplies the diluted absorbent liquid to the pump, and an absorber that supplies the diluted absorbent liquid to the pump, and the absorption condenser. and an expansion valve for expanding condensed water supplied to the evaporator, wherein the absorption condenser exchanges heat between the steam supplied from the absorption reheater and the condensed water supplied from the condensing unit, and supplies the condensed water condensed with steam to the absorption evaporator. The condensate that has undergone heat exchange with the absorber is supplied to the absorber, and the absorber exchanges heat with the steam supplied from the absorption evaporator and the concentrated absorbent liquid separated from the absorption reheater, and then transfers the heat exchanged condensate to the heat recovery boiler unit. The dilution absorbent liquid, which is a mixture of steam and concentrated absorbent liquid, is supplied to the pump, and the condensing part is connected to the low pressure turbine of the steam turbine part through a line through which the fluid flows, condenses the fluid discharged from the low pressure turbine, and then condenses the condensed liquid. A condenser for discharging condensed water, a low-pressure pump connected to the condenser and a line through which fluid flows and sending the condensed water discharged from the condenser to the absorption chiller unit at a low pressure, and a line through which the heat recovery boiler unit and fluid flow A deaerator connected to remove air contained in the condensed water flowing into the heat recovery boiler unit, and a medium pressure pump connected to the deaerator and a fluid flow line and sending the deaerated fluid at a medium pressure through the deaerator; A high-pressure pump is connected to the medium-pressure pump through a line through which fluid flows and includes a high-pressure pump that supplies the medium-pressure fluid at a high pressure through the medium-pressure pump, and the waste heat recovery boiler unit includes a low-pressure evaporator, a medium-pressure evaporator, and a high-pressure evaporator. The steam turbine unit includes a low-pressure turbine, an intermediate-pressure turbine, and a high-pressure turbine generating rotational force with low-pressure steam, medium-pressure steam, and high-pressure steam generated in the heat recovery boiler unit, and the low-pressure evaporator includes the deaerator. is connected to supply low-pressure steam generated by heat exchange with exhaust gas by introducing some of the fluid degassed in the deaerator to the low-pressure turbine through a low-pressure superheater, and the medium-pressure evaporator is a medium-pressure economizer connected to the medium-pressure pump connected to the medium-pressure economizer to introduce steam generated using exhaust gas and supply medium-pressure steam generated using exhaust gas to the medium-pressure turbine through a medium-pressure superheater, a first reheater, and a second reheater, wherein the high-pressure evaporator Connected by the medium-pressure pump, the first high-pressure economizer, and the second high-pressure economizer, the fluid heated through the second high-pressure economizer is introduced and the high-pressure steam generated by heat exchange with the exhaust gas is transferred to the first high-pressure reheater and the second high-pressure economizer. It provides a combined cycle power generation system characterized in that the supply to the high-pressure turbine via a high-pressure reheater.
Therefore, the absorber of the absorption chiller unit dissipates heat as a heat absorbing heat source, the absorber reheater absorbs heat from the radiating heat source, and then absorbs the heat using the cooling air extracted from the compressor as a radiating heat source, thereby pre-cooling the cooling air. Through this, the temperature and flow rate of the cooling air used for cooling the turbine blades are reduced, so the output of the gas turbine can be improved, and the outside air is cooled through the absorption evaporator to solve the problem of reducing the output of the gas turbine under high outdoor temperature conditions. The condensate discharged from the low-pressure pump of the condensation unit is used as a heat source for the absorption condenser and the absorber of the absorption chiller unit to recover the heat released from the absorption reheater, so that the additional output of the condenser unit is improved and the cooling air process is improved. Through this, it can be expected to compensate for the reduction in plant efficiency.

Description

Combined cycle power generation system

The present invention relates to a combined cycle power generation system, and more particularly, to a combined cycle power generation system capable of improving the output and performance of the entire system by improving the cycle of a gas turbine combined cycle plant.

Referring to the background art disclosed in Korean Patent Registration No. 10-1295806, combined cycle power generation has the advantage of higher thermal efficiency than conventional thermal power generation because it is generated in two cycles, less pollution, and a shorter restart time after stopping. However, even in the construction period, it is only about 1/3 of that of bituminous coal-fired power plants, so it is often built for emergency power systems.

1 is a view showing a general combined cycle power generation system.

As shown in FIG. 1, a general combined cycle power generation system includes a gas turbine 10 and a heat recovery steam (HRSG) that generates steam using exhaust heat generated from the gas turbine 10. Generator, 20) and a steam turbine 30 driven by the steam generated by the heat recovery boiler 20.

In the gas turbine 10, air is compressed and supplied through a compressor, and the high-temperature natural gas heated by the heater 11 is sent to the combustor to cause combustion to rotate the turbine, and the generator 12 is powered by the power. will drive

The heat recovery boiler 20 is supplied with heat exhausted from the gas turbine 10 and used as a heat source for steam generation, and then discharged through the main stone 22. At this time, the high pressure, medium pressure, and low pressure drum of the heat recovery boiler 20 The fluid stored in (20a) (20b) (20c) is heated by the heat discharged from the gas turbine 10 and converted into steam, and then supplied to the steam turbine 30 through the steam pipe by the feed water pump 21. .

The steam turbine 30 is rotated by the steam-state working fluid to drive the generator 31 to generate secondary power, and the steam discharged from the steam turbine 30 is condensed in the condenser 32 and then condensed by the condenser pump. By (33), it is supplied again to the high-pressure, medium-pressure, and low-pressure drums 20a, 20b, and 20c of the waste heat recovery boiler 20.

The condenser 32 condenses the steam discharged from the steam turbine by performing heat exchange while circulating seawater by a seawater lifting pump and a circulating pump. Meanwhile, the condenser 32 may be provided with a seawater desalination facility personnel water tank, a water treatment facility, and a pure water tank as a supply source for supplementing boiler feed water.

Although this conventional combined cycle power generation system has the advantage of efficiently utilizing energy, the efficiency of the gas turbine 10 is affected by the temperature, atmospheric pressure, humidity, etc. of the air inhaled, especially in summer when the air temperature is high The density of air introduced into the gas turbine is lowered, which causes the efficiency of the gas turbine to decrease, and the need for research to prevent the output of the gas turbine from being reduced even in summer when the outdoor temperature is high is emerging.

The present invention was created to meet the above needs, and by applying the absorption chiller unit to solve the problem of output reduction that occurs when driving a gas turbine in a high outdoor temperature condition, used in the absorption condenser and absorber of the absorption chiller unit The performance and output of the overall system can be improved by replacing the heat source on the heat absorbing side with condensate supplied from the condenser instead of cold water. Its purpose is to provide a combined cycle power generation system capable of improving the utilization of exhaust gas generated while improving the rotational power of the steam turbine unit by supplying it to the low-pressure turbine, the intermediate-pressure turbine, and the high-pressure turbine of the turbine unit.

In order to achieve the above object, the present invention provides a compressor for compressing cooling air introduced from the outside, connected to an outlet of the compressor, and combusting compressed air compressed by the compressor and fuel provided from the outside to produce combustion gas. A gas turbine unit including a combustor for discharging and a turbine having a plurality of turbine blades rotating by the combustion gas discharged from the combustor; an exhaust heat recovery boiler unit generating steam by using the exhaust gas generated in the gas turbine unit; a steam turbine unit generating rotational force by using the steam generated in the heat recovery boiler unit; a condensing unit that resupplies condensed water obtained by condensing the steam discharged from the steam turbine unit to the heat recovery boiler unit; and an absorption chiller unit for cooling external air and supplying it to the compressor, wherein the absorption chiller unit includes a pump for pressurizing the diluted absorbent liquid, an absorption reheater for raising the temperature of the diluted absorbent liquid and separating it into steam and concentrated absorbent liquid, and in the absorption reheater An absorption condenser for condensing the steam by exchanging heat between the separated steam and the condensed water supplied from the condensing unit, and heat exchange between the condensed water condensed in the absorption condenser and external air to evaporate the condensed water to generate steam and the external air an absorption evaporator that cools the absorption evaporator, an absorber that mixes the steam generated in the absorption evaporator with the concentrated absorbent liquid separated from the absorption reheater to generate a diluted absorbent liquid, and supplies the diluted absorbent liquid to the pump, and an absorber that supplies the diluted absorbent liquid to the pump, and the absorption condenser. and an expansion valve for expanding condensed water supplied to the evaporator, wherein the absorption condenser exchanges heat between the steam supplied from the absorption reheater and the condensed water supplied from the condensing unit, and supplies the condensed water condensed with steam to the absorption evaporator. The condensate that has undergone heat exchange with the absorber is supplied to the absorber, and the absorber exchanges heat with the steam supplied from the absorption evaporator and the concentrated absorbent liquid separated from the absorption reheater, and then transfers the heat exchanged condensate to the heat recovery boiler unit. The dilution absorbent liquid, which is a mixture of steam and concentrated absorbent liquid, is supplied to the pump, and the condensing part is connected to the low pressure turbine of the steam turbine part through a line through which the fluid flows, condenses the fluid discharged from the low pressure turbine, and then condenses the condensed liquid. A condenser for discharging condensed water, a low-pressure pump connected to the condenser and a line through which fluid flows and sending the condensed water discharged from the condenser to the absorption chiller unit at a low pressure, and a line through which the heat recovery boiler unit and fluid flow A deaerator connected to remove air contained in the condensed water flowing into the heat recovery boiler unit, and a medium pressure pump connected to the deaerator and a fluid flow line and sending the deaerated fluid at a medium pressure through the deaerator; A high-pressure pump is connected to the medium-pressure pump through a line through which fluid flows and includes a high-pressure pump that supplies the medium-pressure fluid at a high pressure through the medium-pressure pump, and the waste heat recovery boiler unit includes a low-pressure evaporator, a medium-pressure evaporator, and a high-pressure evaporator. The steam turbine unit includes a low-pressure turbine, an intermediate-pressure turbine, and a high-pressure turbine generating rotational force with low-pressure steam, medium-pressure steam, and high-pressure steam generated in the heat recovery boiler unit, and the low-pressure evaporator includes the deaerator. is connected to supply low-pressure steam generated by heat exchange with exhaust gas by introducing some of the fluid degassed in the deaerator to the low-pressure turbine through a low-pressure superheater, and the medium-pressure evaporator is a medium-pressure economizer connected to the medium-pressure pump connected to the medium-pressure economizer to introduce steam generated using exhaust gas and supply medium-pressure steam generated using exhaust gas to the medium-pressure turbine through a medium-pressure superheater, a first reheater, and a second reheater, wherein the high-pressure evaporator Connected by the medium-pressure pump, the first high-pressure economizer, and the second high-pressure economizer, the fluid heated through the second high-pressure economizer is introduced and the high-pressure steam generated by heat exchange with the exhaust gas is transferred to the first high-pressure reheater and the second high-pressure economizer. It provides a combined cycle power generation system characterized in that the supply to the high-pressure turbine via a high-pressure reheater.

In the combined cycle power generation system according to the present invention, the absorption reheater heat-exchanges the diluted absorbent liquid supplied from the pump with the compressed air supplied from the compressor, and then supplies the compressed air heat-exchanged with the diluted absorbent liquid as cooling air of the turbine. can

delete

delete

The absorption evaporator generates steam by heat-exchanging the condensed water supplied from the absorption condenser with external air provided from the outside, and then the generated steam may be supplied to the absorber, and the heat-exchanged external air may be supplied to the inlet of the compressor. .

delete

delete

delete

In the combined cycle power generation system according to the present invention, the absorber of the absorption chiller unit dissipates heat as a heat source on the heat absorbing side, the absorber reheater absorbs heat from the heat source on the radiating side, and then uses the cooling air extracted from the compressor as a heat source on the radiating side to generate heat. By absorbing the cooling air, the temperature and flow rate of the cooling air used for cooling the turbine blades are reduced through the cooling air pre-cooling process, and thus the output of the gas turbine can be expected to be improved.

In addition, since external air is cooled through the absorption evaporator, it is possible to solve the problem of reducing the output of the gas turbine under conditions of high external temperature.

In addition, the condensate discharged from the low-pressure pump of the condensation unit is used as a heat source for the absorption condenser and the absorber of the absorption chiller unit to recover the heat released from the absorption reheater, so that the additional output of the condenser unit is improved and the cooling air preprocessing is improved. It can be expected to compensate for the reduction in plant efficiency through

1 is a view showing a general combined cycle power generation system.
2 is an exemplary diagram briefly showing a combined cycle power generation system according to an embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Referring to FIG. 2 , a combined cycle power generation system 100 according to an embodiment of the present invention includes a gas turbine unit 1100, an exhaust heat recovery boiler unit 1200, a steam turbine unit 1300, and a condensation unit 1400. ) and an absorption chiller unit 1500.

The gas turbine unit 1100 performs primary power generation, and includes a compressor 1110, a combustor 1120, and a turbine 1130. The compressor 1110 serves to introduce external air with rotational force and compress it to a high pressure, as in a conventional gas turbine device, and the combustor 1120 is connected to the outlet of the compressor 1110, and the compressor 1110 ), the compressed air is introduced, mixed with fuel provided from the outside, and burned, and the high-temperature and high-pressure combustion gas generated after combustion is discharged.

The compressor 1110 is provided with a suction part through which cooling air is introduced from the outside and a discharge part through which compressed air is discharged, and is connected to a plurality of turbines 1130 through a shaft to provide rotational force of the plurality of turbines 1130. After being transmitted to the shaft, the introduced air is compressed to high pressure while rotating with the received rotational force.

The compressed air compressed by the compressor 1110 is preferably accommodated in a separate chamber (not shown) and then selectively supplied to the combustor 1120 by opening and closing a valve.

The combustor 1120 is connected to the outlet of the compressor 1110, introduces compressed air compressed by the compressor 1110, mixes it with fuel supplied from the outside, burns it, and then high-temperature and high-pressure exhaust gas generated during combustion. is discharged to the turbine 1130 side of the plurality of stages.

At this time, the plurality of turbines 1130 are preferably connected to the compressor 1110 by a shaft, and the high-temperature and high-pressure exhaust gas discharged from the combustor 1120 is discharged toward the turbine 1130, and the high-temperature and high-pressure As the exhaust gas corresponds to the turbine blades, the plurality of stages of the turbine 1130 rotates to generate rotational force.

Here, as the multiple stages of turbines 1130 are axially connected to the compressor 1110, as the multiple stages of turbines 1130 rotate, the compressor 1110 also rotates, and the interior of the compressor 1110 is powered by the rotational force. Compresses the cooling air introduced into the , and the turbine 1130 is preferably composed of multiple stages in order to maximize the efficiency of the gas turbine unit 1100 .

The gas turbine unit 1100 preferably further includes a heat exchanger (not shown). The heat exchanger (not shown) transfers the compressed air supplied to the combustor 1120 after being compressed in the compressor 1100 to a rear-stage turbine disposed spaced apart from the compressor 1110 among the plurality of turbines 1130 ( 1130) serves to exchange heat with exhaust gas supplied to the heat recovery boiler unit 1200 to be described later. The temperature of the exhaust gas supplied to the exhaust gas recovery boiler unit 1200 to be described later through the heat exchanger (not shown) can be raised by heat exchange with compressed air, thereby increasing the temperature of the exhaust gas flowing into the exhaust heat recovery boiler unit 1200. As the temperature decreases, the efficiency of the heat recovery boiler unit 1200 is prevented from being lowered, and the heat exchanger (not shown) is preferably disposed between the compressor 1110 and the combustor 1120.

Heat of the exhaust gas generated in the turbine 1130 of the gas turbine unit 1100 is supplied to the heat recovery boiler unit 1200, and the heat recovery boiler unit 1200 uses the recovered exhaust gas heat to produce steam. and the steam turbine unit 1300 to be described later is driven by the steam generated in the heat recovery boiler unit 1200.

Here, the steam turbine unit 1300 performs secondary power generation, and the low pressure turbine 1310 generates rotational force with low-pressure steam generated in the heat recovery boiler unit 1200 and generates rotational force with medium-pressure steam. and a medium-pressure turbine 1320 that generates rotational force with high-pressure steam.

The steam turbine unit 1300 is connected to the condensing unit 1400 through a fluid flow line, and the condensing unit 1400 condenses the condensed water discharged from the steam turbine unit 1300 into absorption refrigeration, which will be described later. Condensed water supplied to the base 1500 and heat-exchanged in the absorption chiller unit 1500 to be described later is re-supplied to the heat recovery boiler unit 1200.

The condenser 1400 includes a condenser 1410, a low pressure pump 1420, a deaerator 1430, a medium pressure pump 1440, and a high pressure pump 1450. The condenser 1410 is connected to the low pressure turbine 1310 of the steam turbine unit 1300 through a fluid flow line, and condenses the steam discharged from the low pressure turbine 1310 and then discharges it. The low-pressure pump 1420 is connected to the condenser 1410 through a fluid flow line, and the low-pressure pump 1420 sends the fluid discharged from the condenser 1410 to an absorption chiller unit 1500 described later, , The fluid that has passed through the absorption chiller unit 1500 is supplied to the low pressure economizer 1211 of the heat recovery boiler unit 1200.

The deaerator 1430 connected to the heat recovery boiler unit 1200 through a fluid flow line is supplied from the low pressure inoculator 1211 of the heat recovery boiler unit 1200 and the low pressure evaporator 1210 to be described later. It serves to remove air contained in the condensed water, which is a fluid that circulates to the heat recovery boiler unit 1200 after being discharged.

The medium pressure pump 1440 is connected to the deaerator 1430 through a fluid flow line to deliver and supply the fluid degassed through the deaerator 1430 at medium pressure, and the high pressure pump 1450 is the medium pressure It is connected to the pump 1440 through a line through which the fluid flows, and serves to deliver and supply the fluid supplied at medium pressure through the medium pressure pump 1440 at high pressure.

The heat recovery boiler unit 1200 is installed on an exhaust passage (not shown) through which exhaust gas discharged from the gas turbine unit 1100 flows, and one side of the exhaust passage (not shown) is the gas turbine unit ( 1100) is connected to a portion through which exhaust gas is discharged, and the other side of the exhaust passage (not shown) is preferably connected to an exhaust port through which exhaust gas is discharged to the outside.

The heat recovery boiler unit 1200 includes a low pressure evaporator 1210, a medium pressure evaporator 1220, and a high pressure evaporator 1230. The low-pressure evaporator 1210 is connected to the deaerator 1430 of the condenser 1400 through a line through which fluid flows, and introduces some of the deaerated fluid (condensate) through the deaerator 1430 to the low-pressure evaporator 1430. Inside the evaporator 1210, heat exchange between the fluid (condensate) and the exhaust gas heats the fluid (condensate) to generate low-pressure steam, and discharges the fluid as low-pressure steam.

At this time, the generated low-pressure steam is branched, and some is supplied to the deaerator 1430, and the other part is supplied to the low-pressure superheater 1212, and the low-pressure steam provided to the deaerator 1430 is supplied to the deaerator 1430. 1430 is used as a catalyst for removing air contained in condensed water as a heat source.

The low-pressure steam introduced into the low-pressure superheater 1212 is heated by heat exchange with exhaust gas, disposed on the exhaust passage (not shown) and connected to the low-pressure evaporator 1210 by a line through which fluid flows, , The low-pressure steam flowing along the inside is heated by heat exchange with the exhaust gas, and the heated low-pressure steam is provided to the low-pressure turbine 1310 of the steam turbine unit 1300.

The condensed water, which is a fluid branched from the deaerator 1430 of the condensation unit 1400 to the medium pressure pump 1440, is sent at medium pressure through the medium pressure pump 1440 to the high pressure pump 1450 and the medium pressure economizer 1221. The intermediate pressure economizer 1221 is connected to the intermediate pressure pump 1440 through a fluid flow line, and the intermediate pressure economizer 1221 heats the medium pressure condensate, which is a degassed fluid flowing along the inside, through heat exchange with the exhaust gas. Steam is generated and the generated steam is provided to the medium pressure evaporator 1220.

The intermediate pressure evaporator 1220 is connected to the intermediate pressure economizer 1221 through a fluid flow line, introduces steam generated through the intermediate pressure economizer 1221, and generates and provides medium pressure steam using exhaust gas.

The medium-pressure steam generated in the medium-pressure evaporator 1220 is supplied to the medium-pressure superheater 1222, which is disposed on an exhaust passage (not shown), and the medium-pressure evaporator 1220 and the fluid is connected to a flowing line, heats the medium-pressure steam flowing along the inside by heat exchange with the exhaust gas, and mixes the heated medium-pressure steam with the steam discharged from the high-pressure turbine 1330 to form a first reheater (1241).

The first reheater 1241 is connected to the intermediate pressure superheater 1222 through a fluid flow line on an exhaust passage (not shown), and introduces the medium pressure steam heated by the intermediate pressure superheater 1222. The medium-pressure steam is primarily reheated by heat exchange with the exhaust gas, and the reheated medium-pressure steam is provided to the second reheater 1242 .

The second reheater 1242 is connected to the first reheater 1241 through a fluid flow line on an exhaust passage (not shown), and releases medium-pressure steam reheated by the first reheater 1241. Inlet, the medium-pressure steam is secondarily reheated through heat exchange with the exhaust gas, and the reheated medium-pressure steam is provided to the steam turbine unit 1300.

At this time, the medium-pressure steam provided to the steam turbine unit 1300 is used as a power source for driving the intermediate-pressure turbine 1320 of the steam turbine unit 1300, and the medium-pressure steam used as a power source for the intermediate-pressure turbine 1320 is introduced into a line connecting the low-pressure superheater 1212 and the low-pressure turbine 1310 and is provided to the low-pressure turbine 1310.

The condensed water sent to medium pressure from the medium pressure pump 1440 is boosted to a high pressure through the high pressure pump 1450 and sent to the first high pressure economizer 1251, which is connected to the exhaust passage (not shown). ) and is connected to the high-pressure pump 1450 and a fluid flow line, and heats the high-pressure condensate, which is a fluid flowing along the inside, by heat exchange with the exhaust gas, and converts the heated condensate to the second high-pressure economizer ( 1252) is provided.

The second high-pressure economizer 1252 is also disposed on an exhaust passage (not shown) and is connected to the first high-pressure economizer 1251 through a fluid flow line, so that condensate, which is a fluid flowing along the inside, is separated from the exhaust gas. It is heated by heat exchange and provided to the high-pressure evaporator 1230.

The high-pressure evaporator 1230 is disposed on one side of an exhaust passage (not shown) into which exhaust gas flows, and is connected to the second high-pressure economizer 1252 through a line through which fluid flows, so that the second high-pressure economizer 1252 The heated fluid is introduced through and heat exchange with the exhaust gas generates high-pressure steam, which is supplied to the first high-pressure reheater 1231.

The high-pressure steam generated from the high-pressure evaporator 1230 is provided to the first high-pressure reheater 1231, which is disposed on an exhaust passage (not shown) and the high-pressure evaporator 1230 The high-pressure steam flowing along the inside is reheated by heat exchange with the exhaust gas, and the reheated high-pressure steam is provided to the second high-pressure reheater 1232.

The second high-pressure reheater 1232 is also disposed on an exhaust passage (not shown), connected to the first high-pressure reheater 1231 through a fluid flow line, and exhausts high-pressure steam flowing along the inside. It is reheated by heat exchange with gas, and the reheated high-pressure steam is provided to the steam turbine unit 1300.

The high-pressure steam provided to the steam turbine unit 1300 is used as a power source for driving the high-pressure turbine 1330 of the steam turbine unit 1300, and the high-pressure steam used as a power source for the high-pressure turbine 1330 is It is provided to the intermediate pressure turbine 1320 through the first reheater 1241.

Condensate, which is a low-pressure fluid sent from the low-pressure pump 1420, is supplied to the absorption chiller unit 1500, and the absorption chiller unit 1500 cools the external air supplied from the outside to cool the gas turbine unit 1100. supplied to the compressor 1110. The absorption chiller unit 1500 includes a pump 1510, an absorption reheater 1520, an absorption condenser 1530, an absorption evaporator 1540, an absorber 1550, and an expansion valve (not shown). ..

The pump 1510 serves to pressurize the diluted absorbent liquid in which steam and the concentrated absorbent liquid are mixed, and the diluted absorbent liquid pressurized by the pump 1510 is supplied to the absorption reheater 1520. Lithium bromide is used as the absorbent contained in the concentrated absorbent liquid, but is not limited thereto, and any material capable of absorbing and dissipating heat may be used as the absorbent.

The absorbent reheater 1520 serves to separate the diluted absorbent into steam and concentrated absorbent by raising the temperature of the diluted absorbent, and exchanges heat between the diluted absorbent supplied from the pump 1510 and the compressed air supplied from the compressor 1110 to obtain the diluted absorbent. is separated into steam and concentrated absorbent liquid, and the compressed air heat-exchanged with the dilute absorbent liquid is supplied as cooling air of the turbine 1130. Preferably, the temperature of the compressed air supplied to the absorption reheater 1520 is approximately 400°C, and the temperature of the cooling air supplied from the absorption reheater 1530 to the plurality of turbines 1130 is approximately 350°C.

The steam separated from the absorption reheater 1520 is supplied to the absorption condenser 1530, and the absorption condenser 1530 exchanges heat between the steam supplied from the absorption reheater 1520 and the condensed water supplied from the condenser 1400. Condensate from which steam is condensed is supplied to the absorption evaporator 1540, and condensate that has undergone heat exchange with steam is supplied to the absorber 1550.

The absorption evaporator 1540 serves to cool the external air while generating steam by evaporating the condensed water by exchanging heat between the condensed water supplied from the absorption condenser 1530 and external air supplied from the outside. Steam generated in the absorption evaporator 1540 is supplied to the absorber 1550, and external air heat-exchanged with condensed water is supplied to the inlet of the compressor 1100. Preferably, the temperature of cooling air supplied to the inlet of the compressor 1110 is approximately 20°C, and the temperature of external air supplied from the outside is approximately 30°C.

The absorber 1550 mixes the vapor generated in the absorption evaporator 1540 with the concentrated absorbent liquid separated in the absorption reheater 1520 to produce a diluted absorbent liquid, and the generated diluted absorbent liquid is supplied to the pump 1510. . The condensed water supplied from the absorption condenser 1530 to the absorber 1550 exchanges heat with the steam supplied from the absorption evaporator 1540 and the concentrated absorption liquid separated from the absorption reheater 1520, and then the waste heat recovery boiler unit 1200 is supplied to the low-pressure economizer 1211, and the temperature of the condensed water supplied to the low-pressure economizer 1211 is preferably about 55°C.

An expansion valve (not shown) is provided on a line for supplying condensed water from the absorption condenser 1530 to the absorption evaporator 1540, and the expansion valve (not shown) moves from the absorption condenser 1530 to the absorption evaporator 1540. ) serves to expand the condensate supplied to

After the absorber 1550 of the absorption chiller unit 1500 dissipates heat as a heat absorbing side heat source and the absorption reheater 1520 absorbs heat from the radiating side heat source, the cooling air extracted from the compressor 1110 as a radiating side heat source By absorbing heat, the temperature and flow rate of the cooling air used to cool the turbine blades are reduced through the cooling air pre-cooling process, so the output of the gas turbine can be improved. A low-pressure pump ( The condensed water discharged from 1440) is used to recover the heat emitted from the absorption reheater 1520, so that the additional output of the condensing unit 1400 is improved, so that the reduction in plant efficiency through the cooling air pre-process can be expected.

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

100: combined cycle power generation system 1100: gas turbine part
1110: compressor 1120: combustor
1130: turbine 1200: heat recovery boiler unit
1300: steam turbine unit 1310: low pressure turbine
1320: medium pressure turbine 1330: high pressure turbine
1400: condensation unit 1410: condenser
1420: low pressure pump 1430: deaerator
1440: medium pressure pump 1450: high pressure pump
1500: absorption chiller unit 1510: pump
1520: absorption reheater 1530: absorption condenser
1540: absorption evaporator 1550: absorber

Claims (8)

A compressor for compressing cooling air introduced from the outside, a combustor connected to an outlet of the compressor and emitting combustion gas by burning the compressed air compressed by the compressor and fuel supplied from the outside, and a combustion gas discharged from the combustor. A gas turbine unit including a turbine in which a plurality of turbine blades rotating by are installed;
an exhaust heat recovery boiler unit generating steam by using the exhaust gas generated in the gas turbine unit;
a steam turbine unit generating rotational force by using the steam generated in the heat recovery boiler unit;
a condensing unit that resupplies condensed water obtained by condensing the steam discharged from the steam turbine unit to the heat recovery boiler unit; and
An absorption chiller unit for cooling external air and supplying it to the compressor,
The absorption chiller unit,
A pump for pressurizing the diluted absorbent;
An absorption reheater for raising the temperature of the diluted absorbent liquid to separate it into steam and concentrated absorbent liquid;
an absorption condenser for condensing the steam by exchanging heat between the steam separated from the absorption reheater and the condensed water supplied from the condensing unit;
An absorption evaporator for generating steam by evaporating the condensed water by exchanging heat between the condensed water condensed in the absorption condenser and external air and simultaneously cooling the external air;
an absorber mixing the steam generated in the absorption evaporator with the concentrated absorbent liquid separated in the absorber reheater to generate a diluted absorbent liquid and supplying the diluted absorbent liquid to the pump;
And an expansion valve for expanding the condensate supplied from the absorption condenser to the absorption evaporator,
The absorption condenser exchanges heat between the steam supplied from the absorption reheater and the condensed water supplied from the condensing unit to supply the condensed water condensed with steam to the absorption evaporator, and supply the condensed water heat-exchanged with steam to the absorber,
The absorber exchanges heat with the condensed water supplied from the absorption condenser and the steam supplied from the absorption evaporator and the concentrated absorption liquid separated from the absorption reheater, and then supplies the heat-exchanged condensate to the waste heat recovery boiler unit, dilution in which steam and concentrated absorption liquid are mixed. The absorption liquid is supplied to the pump,
The condensation part,
A condenser connected to the low-pressure turbine of the steam turbine part by a line through which fluid flows and condensing the fluid discharged from the low-pressure turbine and then discharging condensed condensed water;
A low-pressure pump connected to the condenser through a fluid flow line and sending the condensed water discharged from the condenser to the absorption chiller unit at a low pressure;
A degasser connected to the heat recovery boiler unit through a fluid flow line and removing air included in the condensed water flowing into the heat recovery boiler unit;
An intermediate pressure pump connected to the deaerator by a line through which the fluid flows and sending the fluid deaerated through the deaerator at a medium pressure;
A high-pressure pump connected to the medium-pressure pump through a line through which the fluid flows and transmitting the medium-pressure fluid delivered at a high pressure through the medium-pressure pump;
The heat recovery boiler unit includes a low-pressure evaporator, a medium-pressure evaporator, and a high-pressure evaporator,
The steam turbine part,
It includes a low-pressure turbine, a medium-pressure turbine, and a high-pressure turbine generating rotational force with low-pressure steam, medium-pressure steam, and high-pressure steam generated in the heat recovery boiler unit,
The low-pressure evaporator is connected to the deaerator to introduce some of the fluid degassed in the deaerator and supply low-pressure steam generated by heat exchange with exhaust gas to the low-pressure turbine through a low-pressure superheater;
The medium-pressure evaporator is connected to a medium-pressure economizer connected to the medium-pressure pump, introduces steam generated through the medium-pressure economizer, and transfers medium-pressure steam generated using exhaust gas through a medium-pressure superheater, a first reheater, and a second reheater. It is supplied to the medium pressure turbine,
The high-pressure evaporator is connected to the medium-pressure pump by a first high-pressure economizer and a second high-pressure economizer, and introduces a fluid heated through the second high-pressure economizer to transfer high-pressure steam generated by heat exchange with the exhaust gas to the first high-pressure material. A combined cycle power generation system characterized in that the hot air and the second high-pressure reheater are supplied to the high-pressure turbine.
delete The method of claim 1,
The absorbent reheater heat-exchanges the diluted absorbent liquid supplied from the pump with the compressed air supplied from the compressor, and then supplies the compressed air heat-exchanged with the diluted absorbent liquid as cooling air of the turbine.
delete The method of claim 1,
The absorption evaporator generates steam by heat-exchanging the condensed water supplied from the absorption condenser with external air provided from the outside, supplies the generated steam to the absorber, and supplies the heat-exchanged external air to the inlet of the compressor. Combined cycle power generation system with
delete delete delete