KR102441549B1 - Hybrid power generation equipment - Google Patents

Abstract

The present invention includes a compressor for sucking air from the outside and compressing it, a combustor mixing the compressed air supplied from the compressor with fuel and combusting it, and a turbine through which the first combustion gas supplied from the combustor passes therein. gas turbine; a boiler for mixing and burning the first combustion gas supplied from the gas turbine with air; a first water heat exchanger through which the second combustion gas discharged from the boiler passes, and heats the feed water by heat-exchanging the supplied water with the second combustion gas; a water supply device for supplying water to the first water heat exchanger; a steam turbine through which the steam generated from the boiler passes; and a fuel heat exchanger through which the fuel supplied to the combustor passes, and a portion of the feed water that is returned to the water supply device from the first water heat exchanger and has a higher temperature than the feed water supplied to the first water heat exchanger passes inside. Hybrid power generation facilities are provided.

Description

Hybrid power generation equipment

The present invention relates to a hybrid power generation facility, and more particularly, to a hybrid power generation facility that generates electric power using power generated by driving a gas turbine and a steam turbine.

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

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

On the other hand, combined cycle power generation uses fuel such as natural gas or diesel to generate electricity by first turning a gas turbine, and passing the exhaust gas heat from the gas turbine through a heat recovery steam generator (HRSG) again. It produces steam and turns a steam turbine to generate electricity. Since combined cycle power generation generates power in two stages, the thermal efficiency is about 10% higher than that of conventional thermal power plants, and there is less pollution and the time required to restart after stopping is short.

At this time, referring to FIG. 1 , in the conventional hybrid power generation facility 10 , as the natural gas supplied to the gas turbine 11 is supplied at a rather low temperature, the gas turbine is supplied while maintaining a rather low temperature. In (11), additional fuel is consumed, the efficiency of the entire facility is lowered, and there is a problem in that the carbon dioxide emission is maintained high.

Patent Publication No. 10-2018-0002398 Hybrid power generation device (published on January 08, 2018)

The present invention was created to solve the above problems, and it is an object of the present invention to provide a hybrid power generation facility that preheats fuel supplied to the gas turbine to improve the fuel consumption rate of the gas turbine compared to the prior art and reduce carbon dioxide emissions. .

The present invention includes a compressor for sucking air from the outside and compressing it, a combustor mixing the compressed air supplied from the compressor with fuel and combusting it, and a turbine through which the first combustion gas supplied from the combustor passes therein. gas turbine; a boiler for mixing and burning the first combustion gas supplied from the gas turbine with air; a first water heat exchanger through which the second combustion gas discharged from the boiler passes, and heats the feed water by heat-exchanging the supplied water with the second combustion gas; a water supply device for supplying water to the first water heat exchanger; a steam turbine through which the steam generated from the boiler passes; and a fuel heat exchanger through which the fuel supplied to the combustor passes, and a portion of the feed water that is returned to the water supply device from the first water heat exchanger and has a higher temperature than the feed water supplied to the first water heat exchanger passes inside. Hybrid power generation facilities are provided.

A hybrid power generation facility according to the present invention includes a first water line for supplying water from the water supply device to the first water heat exchanger, and a second water line for returning water discharged from the first water heat exchanger to the water supply device. and a third water line branched from the second water line and supplying water with a higher temperature than the water supplied to the first water heat exchanger to the fuel heat exchanger.

The hybrid power generation facility according to the present invention may further include a fourth water line for supplying the water discharged from the fuel heat exchanger to the condenser.

The steam turbine includes a medium-pressure turbine and a low-pressure turbine connected to the medium-pressure turbine through which steam having a pressure smaller than that of steam passing through the medium-pressure turbine passes, and the water supply device is configured to supply steam passing through the medium-pressure turbine. It includes a medium pressure water supply unit receiving the supply and a low pressure water supply unit receiving the steam that has passed through the low pressure turbine, and the first water heat exchanger may allow water supplied from the low pressure water supply unit to pass therethrough.

The hybrid power generation facility according to the present invention may further include a second water heat exchanger through which the second combustion gas discharged from the boiler passes and the water supplied from the intermediate pressure water supply unit passes.

A hybrid power generation facility according to the present invention, a first boiler line through which the second combustion gas discharged from the boiler flows, and a second branched from the first boiler line for supplying a second combustion gas to the second water heat exchanger It may further include a boiler line and a third boiler line connecting the first water heat exchanger and the second water heat exchanger to each other.

In the hybrid power generation facility according to the present invention, air supplied to the boiler from the outside passes, and as the second combustion gas that is connected to the first boiler line and flows through the first boiler line passes, it is supplied to the boiler. An air preheater in which the used air is preheated, a fourth boiler line through which the second combustion gas discharged from the first water heat exchanger flows, and a fourth boiler line connecting the air preheater and the fourth boiler line, and discharged from the air preheater A fifth boiler line for joining the second combustion gas to the fourth boiler line may be further included.

In the hybrid power generation facility according to the present invention, the water supplied from the condenser to the low-pressure water supply unit passes inside, and the auxiliary heat exchanger for heating the water by passing carbon dioxide collected from the second combustion gas discharged from the boiler under pressure is further provided. may include

The hybrid power generation facility according to the present invention is disposed between the first water heat exchanger and the second water heat exchanger, and the second combustion gas discharged from the second water heat exchanger and supplied to the first water heat exchanger passes through and , It may further include a third water heat exchanger that is supplied to the fuel heat exchanger through a portion of the feed water having a higher temperature than the feed water supplied to the first water heat exchanger as discharged from the first water heat exchanger.

A hybrid power generation facility according to the present invention includes a sixth boiler line for supplying a second combustion gas from the second water heat exchanger to a third water heat exchanger, and a second combustion gas from the third water heat exchanger to the first water heat exchanger. A seventh boiler line supplying It may further include a sixth water line for supplying water having a higher temperature than the water supplied to the third water heat exchanger from the heat exchanger to the fuel heat exchanger.

The hybrid power generation facility according to the present invention includes an auxiliary heat exchanger through which water supplied from a condenser to the water supply device passes inside, and carbon dioxide collected from the second combustion gas discharged from the boiler is pressurized and passed to heat water; Between a seventh water line supplying water from the auxiliary heat exchanger to the water supply device, a second water heat exchanger through which the second combustion gas discharged from the boiler passes, and the first water heat exchanger and the second water heat exchanger a third water heat exchanger through which a second combustion gas discharged from the second water heat exchanger and supplied to the first water heat exchanger passes, and water is branched from the seventh water line to the third water heat exchanger It may further include an eighth water line for supplying, and a ninth water line for supplying water having a higher temperature than the water supplied from the third water heat exchanger to the fuel heat exchanger to the third water heat exchanger.

The hybrid power generation facility according to the present invention includes a fuel line connecting the fuel heat exchanger and a combustor, a temperature sensor installed in the fuel line and measuring a temperature of fuel flowing along the fuel line, and the fourth water line It may further include a water valve that is installed in, and adjusts the flow rate of water flowing along the fourth water line based on the measured value of the temperature sensor.

The hybrid power generation facility according to the present invention may further include a first shut-off valve installed in the third water line and a second shut-off valve installed in the fourth water line.

The second shut-off valve may be installed on a downstream side of the water valve based on a flow direction of water flowing in the fourth water line.

The temperature sensor is provided in plurality, and the water valve may control the flow rate of water based on an average value of each measurement value of the plurality of temperature sensors.

According to the hybrid power generation facility according to the present invention, a fuel heat exchanger is provided at the front end of the combustor of the gas turbine, and the fuel supplied to the combustor is preheated in the fuel heat exchanger and then supplied to the combustor, thereby improving the efficiency of the gas turbine and the efficiency of the entire facility. can be improved, and total carbon dioxide emissions can be reduced.

1 is a schematic diagram of a conventional hybrid power generation facility.
2 is a schematic diagram of a hybrid power generation facility according to a first embodiment of the present invention.
3 is a schematic diagram of a hybrid power generation facility according to a second embodiment of the present invention.
4 is a schematic diagram of a hybrid power generation facility according to a third embodiment of the present invention.
5 is a schematic diagram of a hybrid power generation facility according to a fourth embodiment of the present invention.
6 is a schematic diagram of a hybrid power generation facility according to a fifth embodiment of the present invention.

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art 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.

Referring to FIG. 2 , the hybrid power generation facility 100 according to the first embodiment of the present invention includes a gas turbine 110 , a boiler 120 , a water supply device 130 , a steam turbine 140 , and an auxiliary heat exchanger ( 150 ), a first water heat exchanger 160 , a second water heat exchanger 161 , an air preheater 163 , and a fuel heat exchanger 190 .

The gas turbine 110 generates power for power generation using natural gas, and includes a compressor 111 , a combustor 112 , and a turbine 113 . The compressor 111 sucks air from the outside and compresses it. The combustor 112 mixes the compressed air supplied from the compressor 111 with fuel to combust it. The turbine 113, the first combustion gas supplied from the combustor 112 passes therein.

The boiler 120 burns the first combustion gas supplied from the gas turbine 110 by mixing it with air and fuel.

In the first water heat exchanger 160, the second combustion gas discharged from the boiler 120 passes, and the supplied medium-pressure low-temperature (about 120° C.) water is exchanged with the second combustion gas to exchange heat with the medium-pressure medium temperature ( about 180 degrees Celsius). The second water heat exchanger 160 is disposed between the boiler 120 and the first water heat exchanger 160, and after the second combustion gas discharged from the boiler 120 passes, the first It is supplied to the water heat exchanger (160). The air preheater 163 preheats the air as the air supplied from the outside to the boiler 120 passes, and the second combustion gas discharged from the boiler 120 passes.

The water supply device 130 supplies water to the first water heat exchanger 160 and the second water heat exchanger 161 . In the steam turbine 140 , the steam generated by the boiler 120 passes therein. That is, the medium-pressure medium-temperature feed water supplied to the boiler 120 is heated in the boiler 120 , and then converted into superheated steam and supplied to the steam turbine 140 . In this case, the steam turbine 140 includes a high-pressure turbine 143 , a medium-pressure turbine 141 , and a low-pressure turbine 142 . The high-pressure turbine 143, high-pressure steam is passed therein. The medium pressure turbine 141 is dynamically connected to the high pressure turbine 143 , and the medium pressure steam passing through the high pressure turbine 143 passes therein. The low pressure turbine 142 is dynamically connected to the medium pressure turbine 141 , and the low pressure steam passing through the medium pressure turbine 141 passes therein. The water supply device 130 includes a high pressure water supply unit 131 , a medium pressure water supply unit 132 , and a low pressure water supply unit 133 . The high-pressure water supply unit 131 receives the steam that has passed through the high-pressure turbine 143 . The intermediate pressure water supply unit 132 receives steam that has passed through the intermediate pressure turbine 141 . The low-pressure water supply unit 133 receives the steam that has passed through the low-pressure turbine 142 .

In the first water heat exchanger 160 , the water supplied from the low pressure water supply unit 133 passes. In the second water heat exchanger 161 , the water supplied from the intermediate pressure water supply unit 132 passes.

In the auxiliary heat exchanger 150, the water supplied from the condenser 151 to the low-pressure water supply unit 133 passes inside, and the high-temperature and high-pressure carbon dioxide discharged from the boiler 120 and collected is passed through the inside. . And as the high-temperature and high-pressure carbon dioxide and water passing through the interior exchange heat, the water is supplied to the low-pressure water supply unit 133 in a heated state. As the second combustion gas discharged from the boiler 120 passes through a carbon dioxide trapping device (not shown), the carbon dioxide present in the second combustion gas is collected by the carbon dioxide trapping device and then pressurized by a compressor to the auxiliary heat exchanger ( 150) is supplied. Then, the carbon dioxide supplied to the auxiliary heat exchanger 150 is discharged after heating water in the auxiliary heat exchanger 150 and moves to the outside (eg, petroleum mines, etc.).

In the fuel heat exchanger 190 , the fuel supplied to the combustor 112 passes, and a portion of the medium-pressure medium-temperature supply water returned from the first water heat exchanger 160 to the water supply device 130 is transferred to the inside. is passed

Hybrid power generation facility 100 according to the first embodiment of the present invention, the first boiler line 121, the second boiler line 122, the third boiler line 123, the fourth boiler line 124, 5 further including a boiler line 125 , a first water line 170 , a second water line 171 , a third water line 172 , a fourth water line 173 , and a fuel line 191 .

In the first boiler line 121 , the second combustion gas discharged from the boiler 120 flows. The second boiler line 122 is branched from the first boiler line 121 to supply a second combustion gas to the second water heat exchanger 161 . The third boiler line 123 connects the first water heat exchanger 160 and the second water heat exchanger 161 to each other. In the fourth boiler line 124 , the second combustion gas discharged from the first water heat exchanger 160 flows. The fifth boiler line 125 connects the air preheater 163 and the fourth boiler line 124 , and the second combustion gas discharged from the air preheater 163 is supplied to the fourth boiler line 124 . join with

The first water line 170 supplies water from the low pressure water supply unit 133 to the first water heat exchanger 160 . The second water line 171 returns the water discharged from the first water heat exchanger 160 to the water supply device 130 . The third water line 172 is branched from the second water line 171 to supply medium pressure and medium temperature water to the fuel heat exchanger 190 . The fourth water line 173 supplies the water discharged from the fuel heat exchanger 190 to the condenser 151 .

The fuel line 191 connects the fuel heat exchanger 190 and the combustor 112 , and supplies fuel from the fuel heat exchanger 190 to the combustor 112 .

According to the hybrid power generation facility 100 according to the present invention, a fuel heat exchanger 190 is provided at the front end of the combustor 112 of the gas turbine 110, and the fuel supplied to the combustor 112 is converted into a fuel heat exchanger ( 190) and then supplied to the combustor 112, the output of the gas turbine 110 and the efficiency of the entire facility can be improved, and the total amount of carbon dioxide can be reduced.

Referring to FIG. 3 , the hybrid power generation facility 200 according to the second embodiment of the present invention has a third boiler line 123 and a third water line 172 as compared with the first embodiment of the present invention. Instead of not having, a third water heat exchanger 162, a sixth boiler line 126, a seventh boiler line 127, a fifth water line 174, and a sixth water line 175 are further included. .

The third water heat exchanger 162 is disposed between the first water heat exchanger 160 and the second water heat exchanger 161, is discharged from the second water heat exchanger 161, and the first The second combustion gas supplied to the water heat exchanger 160 passes, and a portion of the medium-pressure medium-temperature feed water discharged from the first water heat exchanger 160 passes and is supplied to the fuel heat exchanger 190 .

The sixth boiler line 126 supplies a second combustion gas from the second water heat exchanger 161 to the third water heat exchanger 162 . The seventh boiler line 127 supplies a second combustion gas from the third water heat exchanger 162 to the first water heat exchanger 160 . The fifth water line 174 is branched from the second water line 171 to supply medium pressure and medium temperature water to the third water heat exchanger 162 . The sixth water line 175 supplies medium pressure and high temperature (about 250 degrees C) water from the third water heat exchanger 162 to the fuel heat exchanger 190 .

According to the second embodiment of the present invention, the heated water supplied from the low-pressure water supply unit 133 is first heated in the first water heat exchanger 160 , and the heated water is heated in a part of the boiler 120 . The heat exchange efficiency between the fuel in the fuel heat exchanger 190 and the medium-pressure high-temperature feed water is increased by additionally raising the temperature by heat-exchanging the waste gas of the third water heat exchanger 162 and supplying it to the fuel heat exchanger 190 . can be improved

Referring to FIG. 4 , the hybrid power generation facility 300 according to the third embodiment of the present invention has a fifth water line 174 and a sixth water line 175 compared with the second embodiment of the present invention. Instead of not having, a seventh water line 176 , an eighth water line 177 , and a ninth water line 178 are further included.

The seventh water line 176 supplies water from the auxiliary heat exchanger 150 to the low pressure water supply unit 133 of the water supply device 130 . The eighth water line 177 is branched from the seventh water line 176 to supply water to the third water heat exchanger 162 . The ninth water line 178 supplies high-pressure water supply from the third water heat exchanger 162 to the fuel heat exchanger 190 .

According to the third embodiment of the present invention as described above, by using the heat energy of carbon dioxide in the auxiliary heat exchanger 150 to preheat the medium-pressure low-temperature supply water to be supplied to the fuel heat exchanger 190 primarily, medium-pressure medium-temperature supply water , and by preheating the medium pressure medium temperature feed water to be supplied to the fuel heat exchanger 190 through the third water heat exchanger 162 to generate medium pressure high temperature water supply, in the fuel heat exchanger 190 It is possible to improve the heat exchange efficiency between fuel and medium pressure and high temperature feed water.

Referring to FIG. 5 , the hybrid power generation facility 400 according to the fourth embodiment of the present invention includes a temperature sensor 192 , a water valve 180 , a first shut-off valve 181 , and a second shut-off valve ( 182).

The temperature sensor 192 is installed in the fuel line 191 and measures the temperature of the fuel flowing along the fuel line 191 . The water valve 180 is installed in the fourth water line 173 and adjusts the flow rate of water flowing along the fourth water line 173 based on the measured value of the temperature sensor 192 . The first shut-off valve 181 is installed in the third water line 172 . The second shut-off valve 182 is installed on the fourth water line 173 . In this case, the second shut-off valve 182 may be installed on the downstream side of the water valve 180 based on the flow direction of the water flowing in the fourth water line 173 .

According to the fourth embodiment of the present invention, the flow amount of feed water flowing to the fuel heat exchanger 190 is adjusted based on the temperature value of the fuel supplied to the combustor 112 through the fuel line 191 . By doing so, the temperature of the fuel supplied to the combustor 112 can be set as a target value, and in a specific situation, the third water line using the first shut-off valve 181 and the second shut-off valve 182 . By closing the 172 and the fourth water line 173 , it is possible to block the flow of feed water to the fuel heat exchanger 190 .

Referring to FIG. 6 , in the hybrid power generation facility 500 according to the fifth embodiment of the present invention, the temperature sensor 192 is provided in plurality, and the water valve 180 includes the plurality of temperature sensors ( 192), the water flow rate can be adjusted based on the average value of each measurement value.

According to the fifth embodiment of the present invention as described above, the average value obtained by discarding one of the measured values of the plurality of temperature sensors 192 and having the lowest reliability is the average value of the flow rate of water supply using the water valve 180 . can be controlled, and thus the temperature of the fuel supplied to the combustor 112 can be more precisely controlled.

Meanwhile, the above-described fourth and fifth embodiments of the present invention have been described with reference to the first embodiment of the present invention, but these are merely exemplary, and the fourth and fifth embodiments of the present invention It will be understood that it can be applied to the second and third embodiments of the present invention, respectively. Accordingly, the first shut-off valve 181 may be installed in the sixth water line 175 or the ninth water line 178 instead of the third water line 172 .

100,200,300,400,500 : Hybrid power generation facility
110: gas turbine 120: boiler
130: water supply device 140: steam turbine
150: auxiliary heat exchanger 160: first water heat exchanger
161: second water heat exchanger 162: third water heat exchanger
163: air preheater 190: fuel heat exchanger

Claims (15)

A gas turbine comprising: a compressor for sucking air from the outside and compressing it; a combustor for mixing and burning the compressed air supplied from the compressor with fuel; and a turbine through which the first combustion gas supplied from the combustor passes therein;
a boiler for mixing and burning the first combustion gas supplied from the gas turbine with air;
a first water heat exchanger through which the second combustion gas discharged from the boiler passes, and heats the feed water by heat-exchanging the supplied water with the second combustion gas;
a water supply device for supplying water to the first water heat exchanger;
a steam turbine through which the steam generated from the boiler passes; and
A hybrid comprising a fuel heat exchanger through which the fuel supplied to the combustor passes, and a portion of the feed water having a higher temperature than the feed water supplied to the first water heat exchanger as returned to the water supply device from the first water heat exchanger passes inside power generation equipment. The method according to claim 1,
a first water line for supplying water from the water supply device to the first water heat exchanger;
a second water line for returning the water discharged from the first water heat exchanger to the water supply device;
The hybrid power generation facility further comprising a third water line branched from the second water line and supplying water with a higher temperature than the water supplied to the first water heat exchanger to the fuel heat exchanger. 3. The method according to claim 2,
Hybrid power generation facility further comprising a fourth water line for supplying the water discharged from the fuel heat exchanger to the condenser. The method according to claim 1,
The steam turbine is
medium pressure turbine,
It is connected to the medium pressure turbine and includes a low pressure turbine through which steam of a pressure smaller than that of the steam passing through the medium pressure turbine passes,
The water supply device,
a medium pressure water supply unit receiving the steam passing through the medium pressure turbine;
and a low-pressure water supply unit receiving the steam that has passed through the low-pressure turbine,
The first water heat exchanger is a hybrid power generation facility through which the water supplied from the low-pressure water supply unit passes. 5. The method according to claim 4,
A hybrid power generation facility further comprising a second water heat exchanger through which the second combustion gas discharged from the boiler passes, and through which the water supplied from the intermediate pressure water supply unit passes. 6. The method of claim 5,
a first boiler line through which the second combustion gas discharged from the boiler flows;
a second boiler line branched from the first boiler line and supplying a second combustion gas to the second water heat exchanger;
A hybrid power generation facility further comprising a third boiler line connecting the first water heat exchanger and the second water heat exchanger to each other. 7. The method of claim 6,
An air preheater through which the air supplied to the boiler from the outside passes, and the air supplied to the boiler is preheated as the second combustion gas that is connected to the first boiler line and flows through the first boiler line passes;
a fourth boiler line through which the second combustion gas discharged from the first water heat exchanger flows;
The hybrid power generation facility further comprising a fifth boiler line connecting the air preheater and the fourth boiler line, and joining the second combustion gas discharged from the air preheater into the fourth boiler line. 5. The method according to claim 4,
The hybrid power generation facility further comprising an auxiliary heat exchanger through which water supplied from the condenser to the low-pressure water supply unit passes inside, and the carbon dioxide collected from the second combustion gas discharged from the boiler is pressurized and passed to heat the water. 6. The method of claim 5,
It is disposed between the first water heat exchanger and the second water heat exchanger, and the second combustion gas discharged from the second water heat exchanger and supplied to the first water heat exchanger passes, and is discharged from the first water heat exchanger. A hybrid power generation facility further comprising a third water heat exchanger through which a portion of the feedwater having a higher temperature than the feedwater supplied to the first water heat exchanger is passed through and supplied to the fuel heat exchanger. 10. The method of claim 9,
a sixth boiler line for supplying a second combustion gas from the second water heat exchanger to the third water heat exchanger;
a seventh boiler line for supplying a second combustion gas from the third water heat exchanger to the first water heat exchanger;
a second water line for returning the water discharged from the first water heat exchanger to the water supply device;
a fifth water line branched from the second water line and supplying water with a higher temperature than the water supplied to the first water heat exchanger to the third water heat exchanger;
The hybrid power generation facility further comprising a sixth water line supplying water from the third water heat exchanger to the fuel heat exchanger, but supplying water having a higher temperature than the water supplied to the third water heat exchanger. The method according to claim 1,
an auxiliary heat exchanger in which water supplied from the condenser to the water supply device passes inside, and the carbon dioxide collected from the second combustion gas discharged from the boiler is pressurized and passed to heat the water;
a seventh water line for supplying water from the auxiliary heat exchanger to the water supply device;
a second water heat exchanger through which the second combustion gas discharged from the boiler passes;
a third water heat exchanger disposed between the first water heat exchanger and the second water heat exchanger, and through which a second combustion gas discharged from the second water heat exchanger and supplied to the first water heat exchanger passes;
an eighth water line branched from the seventh water line and supplying water to the third water heat exchanger;
The hybrid power generation facility further comprising a ninth water line supplying water having a higher temperature than the water supplied to the third water heat exchanger from the third water heat exchanger to the fuel heat exchanger. 4. The method of claim 3,
a fuel line connecting the fuel heat exchanger and the combustor;
a temperature sensor installed in the fuel line and measuring the temperature of the fuel flowing along the fuel line;
The hybrid power generation facility further comprising a water valve installed in the fourth water line and controlling the flow rate of water flowing along the fourth water line based on the measured value of the temperature sensor. 13. The method of claim 12,
a first shut-off valve installed in the third water line;
A hybrid power generation facility further comprising a second shut-off valve installed on the fourth water line. 14. The method of claim 13,
The second shut-off valve is a hybrid power generation facility installed on a downstream side of the water valve based on a flow direction of water flowing in the fourth water line. 13. The method of claim 12,
The temperature sensor is provided in plurality,
The water valve is a hybrid power generation facility for controlling the flow rate of water based on an average value of each measurement value of the plurality of temperature sensors.

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