JP2020023941A - Combined cycle power generation plant - Google Patents

Abstract

To provide a combined cycle power generation plant capable of purging an inside of an exhaust heat recovery boiler while avoiding deterioration of efficiency of a gas turbine.SOLUTION: A combined cycle power generation plant includes: a gas turbine having a compressor for generating compressed air and a turbine having an exhaust port, driven by combustion gas generated through combustion of fuel and the compressed air generated by the compressor and discharging exhaust gas from the exhaust port; a vertical type exhaust heat recovery boiler for recovering heat from exhaust gas to generate steam; a duct for connecting the exhaust port with the lower part of the exhaust heat recovery boiler; first purge piping that has one end connected to the duct and the other end opened to the atmosphere and to which air is caused to flow in; a first purge valve provided in the first purge piping; and a control device for controlling the first purge valve so as to open the first purge piping.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a combined cycle power plant.

  In recent years, combined cycle power plants have been used to more efficiently utilize energy. The combined cycle power plant includes a gas turbine, a steam turbine, an exhaust heat recovery boiler, and the like, and employs a power generation system combining a gas turbine and a steam turbine. In such a combined cycle power plant, exhaust gas after work in a gas turbine is guided to an exhaust heat recovery boiler, steam is generated using heat of the exhaust gas, and the steam drives the steam turbine to generate power. Things.

  In a combined cycle power plant, it is necessary to purge gas (combustible gas and the like) remaining in the exhaust heat recovery boiler at the time of startup.

  For example, in a combined cycle power plant of Patent Document 1, an extraction tube for extracting compressed air from a compressor to an exhaust heat recovery boiler is provided. The extraction pipe is provided with a valve for extracting compressed air to the exhaust heat recovery boiler in an open state and for shutting off extraction of compressed air to the exhaust heat recovery boiler in a closed state. In addition, the compressed air extracted to the exhaust heat recovery boiler via the extraction pipe is a part of the compressed air generated by the compressor.

  An exhaust port of a gas turbine is connected to an exhaust heat recovery boiler via a duct (referred to as a bypass in Patent Document 1). The duct has a first position where exhaust gas exhausted from the turbine flows into the flue pipe and shuts off the flow of exhaust gas to the exhaust heat recovery boiler, or the exhaust gas flows into the exhaust heat recovery boiler and exhaust gas into the smoke pipe. An exhaust bypass damper is provided at a second position to block the inflow.

  When purging the gas in the exhaust heat recovery boiler, the exhaust bypass damper is arranged at the first position and the valve is opened while the gas turbine is driven (combustion state). The exhaust bypass damper and the valve are controlled by the control device. Thereby, a part of the compressed air is bled into the exhaust heat recovery boiler through the extraction pipe, and the gas in the exhaust heat recovery boiler is purged.

Japanese Patent No. 5550461

  When the gas turbine is stopped and restarted, it is necessary to purge the gas remaining in the exhaust heat recovery boiler. In this case, by rotating the gas turbine rotor by a motor before starting the gas turbine, the exhaust heat recovery boiler is scavenged by air passing through the gas turbine without performing combustion in the combustor (prepurge). May be called). In this case, it is necessary to purge not only the exhaust heat recovery boiler but also the gas remaining in the gas turbine, so that the pre-purge requires time.

  In addition, when preparing to shift to combined power generation while the gas turbine is operating alone, it is necessary to purge the exhaust heat recovery boiler while operating the gas turbine alone. In this case, compressed air for bleeding from the compressor is used as purge air. However, the use of compressed air for bleeding reduces the efficiency of the gas turbine.

  Therefore, an object of the present invention is to provide a combined cycle power plant capable of purging the exhaust heat recovery boiler by natural ventilation.

  The combined cycle power plant of the present invention has a compressor that generates compressed air, an exhaust port, and is driven by a combustion gas generated by combustion of fuel and the compressed air generated by the compressor; A gas turbine having a turbine that discharges exhaust gas from an exhaust port, a vertical exhaust heat recovery boiler that recovers heat from the exhaust gas to generate steam, and connects the exhaust port and a lower portion of the exhaust heat recovery boiler. A first purge pipe, one end of which is connected to the duct and the other end of which is open to the atmosphere and into which air flows, a first purge valve provided in the first purge pipe, and a first purge pipe. A control device for controlling the first purge valve so that the pipe is opened.

  According to the present invention, when the gas turbine is restarted after the gas turbine is stopped, the first purge valve is opened and the first purge pipe is opened. In this case, since the air around the tube group that is in a high temperature state in the exhaust heat recovery boiler is heated, the specific gravity of the air at the outside air temperature is smaller. This allows the outside air to flow into the exhaust heat recovery boiler from the lower part of the exhaust heat recovery boiler through the first purge pipe, so that a purge effect is provided by natural ventilation. Therefore, purging the exhaust heat recovery boiler using the flow of air generated by rotating the gas turbine by the motor before starting the gas turbine, that is, it is not always necessary to perform pre-purge by rotating the gas turbine. . With such a configuration, the inside of the exhaust heat recovery boiler can be purged by natural ventilation while the gas turbine is stopped, so that the startup time of the gas turbine and the plant can be reduced. Also, when the gas turbine is operating (when preparing for the transition to combined power generation (gas turbine operation and waste heat recovery boiler operation) while the gas turbine is operating alone), the inside of the waste heat recovery boiler is Can be purged. As a result, the compressed air for bleeding from the compressor does not need to be used, so that the efficiency of the gas turbine is not reduced.

  In the above invention, it is preferable that a check valve is provided in the first purge pipe on an upstream side of the first purge valve.

  According to the above configuration, when the pressure in the exhaust heat recovery boiler becomes positive during the operation of the gas turbine, the check valve can prevent the backflow of air. Further, by disposing the check valve upstream of the first purge valve, if a malfunction such as a stick occurs in the check valve, if the first purge valve is closed, the exhaust heat recovery boiler can be used. The check valve can be repaired or replaced even during operation.

  In the above invention, the combined cycle power plant includes a first temperature sensor that detects a temperature in the exhaust heat recovery boiler, and a first temperature sensor disposed in the first purge pipe upstream of the check valve. A second temperature sensor that detects the temperature of the air, wherein the control device is configured to perform a control based on a difference between the temperature detected by the first temperature sensor and the temperature detected by the second temperature sensor. The first purge valve may be controlled so that the first purge pipe is closed.

  According to the above configuration, it is possible to know the timing to complete the purge based on the difference between the temperature detected by the first temperature sensor and the temperature detected by the second temperature sensor. This prevents the purging from being performed more than necessary.

  In the above invention, the turbine has a rotor that is switched between a state rotated by a motor and a state disconnected from the motor, and the control device is configured to switch the rotor after the end of combustion in the gas turbine. It is desirable that the first purge valve be controlled so that the first purge pipe is opened when rotated by a motor.

  After the gas turbine is stopped after the completion of the combustion of the compressed air, turning is performed to avoid the occurrence of distortion of the gas turbine and the driven machine rotor and to reduce the bending of the shaft center before starting. I have. According to the above configuration, since the first purge valve is controlled during the turning to purge the gas in the exhaust heat recovery boiler, the purging time can be reduced as compared with the case where the purging is performed after the turning. Can be.

  In the above invention, the combined cycle power plant is connected to the duct, and a smoke pipe that discharges the exhaust gas into the atmosphere, and is provided in the duct, and allows the exhaust gas to flow into the smoke pipe and to the exhaust heat recovery boiler. An exhaust bypass damper disposed at a first position for blocking the inflow of exhaust gas or a second position for allowing the exhaust gas to flow into the exhaust heat recovery boiler and to block the flow of the exhaust gas into the smoke tube; The apparatus is configured to control the exhaust bypass damper and the first purge valve such that the exhaust bypass damper is disposed at the first position and the first purge pipe is opened during operation of the gas turbine. It may be.

  According to the above configuration, during the operation of the gas turbine (when shifting from the single operation of the gas turbine to the combined operation), the exhaust bypass damper is arranged at the first position, the first purge valve is opened, and the first purge valve is opened. The purge pipe is opened. In this case, since the air around the tube group that is in a high temperature state in the exhaust heat recovery boiler is heated, the specific gravity of the air at the outside air temperature is smaller. As a result, outside air flows into the exhaust heat recovery boiler from the lower part of the exhaust heat recovery boiler through the first purge pipe, and a purging effect is achieved. Therefore, it is not necessary to perform the purge using the compressed air during the operation of the compressor. Thus, the efficiency of the gas turbine is not reduced.

  In the above invention, the compressor has a bleed port through which the compressed air flows out, and the combined cycle power plant is provided in a second purge pipe and a second purge pipe that connect the bleed port and the duct. And a controller configured to control the second purge valve such that the second purge pipe is opened during operation of the gas turbine.

  According to the above configuration, when purging the gas in the exhaust heat recovery boiler, the compressed air flowing through the second purge pipe can be used, so that the efficiency of the gas turbine may slightly decrease, The time required for purging can be reduced depending on the amount of compressed air used.

  ADVANTAGE OF THE INVENTION According to this invention, the purge in an exhaust-heat recovery boiler can be performed, avoiding the fall of the efficiency of a gas turbine.

It is a schematic structure figure of a combined cycle power plant concerning a 1st embodiment of the present invention. (A) is a schematic block diagram which shows the gas turbine of FIG. 1, and its peripheral structure, (b) is a schematic block diagram which shows another example of a gas turbine and its peripheral structure. 4 is a flowchart illustrating a flow of a process performed by the control device according to the first embodiment. It is a schematic structure figure of a combined cycle power plant concerning a 2nd embodiment of the present invention. It is a flowchart which shows the flow of a process of the control apparatus of 2nd Embodiment.

(1st Embodiment)
Hereinafter, a combined cycle power plant (CCPP) according to an embodiment of the present invention will be described with reference to the drawings. The combined cycle power plant described below is only one embodiment of the present invention. Therefore, the present invention is not limited to the following embodiments, and additions, deletions, and changes can be made without departing from the spirit of the present invention.

  As shown in FIG. 1, a combined cycle power plant 1 according to the first embodiment includes a gas turbine 2 connected to a generator 34 (see FIGS. 2A and 2B) and exhaust gas from the gas turbine 2. Heat recovery boiler 3 having a vertical structure for recovering heat from steam to generate steam, a duct 4, a first purge pipe 5, a first purge valve 6, a check valve 7, a first temperature sensor 10 , A second temperature sensor 11 and a control device 12. The control device 12 is, for example, a computer having a memory such as a ROM and a RAM and a CPU, and a program stored in the ROM is executed by the CPU. The steam generated by the heat recovery steam generator 3 is used for power generation by a steam turbine (not shown).

  The gas turbine 2 includes a compressor 21, a combustor 25 (see FIGS. 2A and 2B), and a turbine 22 provided with an exhaust port 23. In the gas turbine 2, the compressed air generated by compression in the compressor 21 and the fuel are mixed and burned in the combustor 25, and the generated combustion gas is supplied to the turbine 22 to rotate the blades of the turbine 22. It converts the thermal energy of the combustion gas into rotational kinetic energy. Exhaust gas (combustion gas) from the turbine 22 is discharged from an exhaust port 23. The fuel for the gas turbine 2 includes LNG (natural gas), hydrogen gas, by-product gas, and liquid fuel.

  Here, the gas turbine includes a single-shaft gas turbine 2 as shown in FIG. 2A and a two-shaft gas turbine 2a as shown in FIG. 2B. 2B, the same components as those in FIG. 2A are denoted by the same reference numerals as those in FIG. 2A.

  In the gas turbine 2 shown in FIG. 2A, an output shaft 32 of the gas turbine 2 is connected to a speed reducer 33 via a shaft coupling 35. A motor 36 serving both as a starter motor and a turning motor is connected to the speed reducer 33, and a generator 34 is connected via a shaft coupling 37. The rotor 31 of the turbine 22 is switched by the speed reducer 33 between a state of being rotated by the motor 36 and a state of being separated from the motor 36. When performing the above-described turning, the rotor 31 is rotated by the motor 36. In the gas turbine 2 of FIG. 2A, a starter motor and a turning motor may be separately provided.

  In the gas turbine 2a of FIG. 2B, a motor 39 as a starter motor and a motor 36 as a turning motor are separately provided. A motor 39 is connected to the compressor 21 via a speed reducer 38. In the gas turbine 2a, a gas generator turbine 26 and a power turbine 27 are provided. An output shaft (rotor) 32 of the power turbine 27 is connected to a speed reducer 33 via a shaft coupling 35. The reduction gear 33 is connected to a motor 36 and a generator 34 via a shaft coupling 37. The output shaft 32 of the turbine 27 is switched by the speed reducer 33 between a state where the output shaft 32 is rotated by the motor 36 and a state where the output shaft 32 is separated from the motor 36. When turning, the output shaft 32 is rotated by a motor 36. Note that, in the gas turbine 2a of FIG. 2B, a motor that serves as both a starter motor and a turning motor may be provided.

  Returning to FIG. 1, one end of the duct 4 is connected to the exhaust port 23, and the other end of the duct 4 is connected to a lower part of the exhaust heat recovery boiler 3. The exhaust gas discharged from the exhaust port 23 flows into the exhaust heat recovery boiler 3 through the duct 4.

  One end of the first purge pipe 5 is connected to the duct 4. The other end of the first purge pipe 5 is open to the atmosphere, and outside air flows in from the other end. The first purge pipe 5 is provided with a check valve 7 and a first purge valve 6 in order from the upstream side. In the present embodiment, a flow control valve (damper) for controlling the amount of air in the first purge pipe 5 can be adopted as the first purge valve 6, but the present invention is not limited to this. An on-off valve that can open and close the purge pipe 5 may be employed. The same applies to a second purge valve 9 described later.

  The first temperature sensor 10 detects a temperature near the outlet of the exhaust heat recovery boiler 3 and outputs a signal of the detection result to the control device 12. The second temperature sensor 11 is disposed upstream of the check valve 7 in the first purge pipe 5, detects the temperature of air in the first purge pipe 5, and outputs a signal of the detection result to the control device 12. .

  In the combined cycle power plant 1, the purge in the exhaust heat recovery boiler 3 is performed when the gas turbine 2 is started again after the gas turbine 2 is stopped (that is, the rotor 31 is rotated by the motor 36 after the combustion in the gas turbine 2 is completed). This is done when (turning).

  When performing the purge, the controller 12 controls the first purge valve 6 so that the first purge pipe 5 is opened. In this case, since the air around the tube group in the high temperature state in the exhaust heat recovery boiler 3 after the end of the combustion is heated, the specific gravity of the air at the outside air temperature is smaller. As a result, outside air flows into the exhaust heat recovery boiler 3 from the lower part of the exhaust heat recovery boiler 3 through the first purge pipe 5, and a purging effect is achieved.

  Further, the control device 12 determines the end of the purge as follows. The controller 12 calculates the buoyancy in the exhaust heat recovery boiler 3 from the difference between the temperature detected by the first temperature sensor 10 and the temperature detected by the second temperature sensor 11, and flows into the exhaust heat recovery boiler 3. Calculate the integrated flow rate of the air. The control device 12 is configured to determine that the purge has been completed when the integrated flow rate reaches the predetermined amount, and to control the first purge valve 6 so that the first purge pipe 5 is closed.

  Subsequently, a control method at the time of purging by the control device 12 will be described. FIG. 3 is a flowchart showing the flow of the process of the control device 12.

  As shown in FIG. 3, after the combustion in the gas turbine 2 is completed, the control device 12 drives the motor 36 to perform turning (step S1). Then, the control device 12 opens the first purge valve 6 at the time of turning (step S2). Then, outside air flows into the exhaust heat recovery boiler 3 from the lower part of the exhaust heat recovery boiler 3 through the first purge pipe 5, and a purging effect is achieved.

  Subsequently, the control device 12 determines whether or not the integrated purge flow rate has reached a predetermined amount (step S3). The determination method is as described above. If the integrated purge flow rate has reached the predetermined amount (YES in step S3), the process proceeds to step S4, and if the integrated purge flow rate has not reached the predetermined amount (NO in step S3), the process of step S3 is performed again. Do.

  In step S4, the control device 12 closes the first purge valve 6. Thereby, the outside air does not flow into the exhaust heat recovery boiler 3 through the first purge pipe 5. Then, the control device 12 stops the motor 36 to end the turning (step S5).

  As described above, in the combined cycle power plant 1 of the present embodiment, the outside air is flown into the exhaust heat recovery boiler 3 through the first purge pipe 5 after the combustion is completed and at the time of turning. Is played. Therefore, it is not always necessary to purge the exhaust heat recovery boiler 3 using the flow of air generated by rotating the gas turbine 2 by the motor 36 before starting the gas turbine 2. With such a configuration, the inside of the exhaust heat recovery boiler 3 can be purged by natural ventilation while the gas turbine 2 is stopped, so that the startup time of the gas turbine 2 and the plant 1 can be reduced. Note that a purge for scavenging the gas turbine 2 by rotating the gas turbine 2 is necessary.

(2nd Embodiment)
Next, a combined cycle power plant 1a according to a second embodiment of the present invention will be described with reference to the drawings. In the present embodiment, the same components as those in the above-described first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

  As shown in FIG. 4, a combined cycle power plant 1 a according to the second embodiment includes a smoke pipe 13 connected to a duct 4 and discharging exhaust gas from the gas turbine 2 into the atmosphere, and an exhaust bypass provided in the duct 4. It further includes a damper 41, a second purge pipe 8 connecting the bleed port 24 of the compressor 21 and the duct 4, and a second purge valve 9 provided in the second purge pipe 8. In FIG. 4, since the downstream end of the second purge pipe 8 is connected to an intermediate portion of the first purge pipe 5, the bleed port 24 and the duct 4 are indirectly connected by the second purge pipe 8. Configuration.

  The exhaust bypass damper 41 allows the exhaust gas to flow into the flue gas 13 and the first position P <b> 1 at which the exhaust gas flows into the exhaust heat recovery boiler 3 or the exhaust heat recovery boiler 3 under the control of the control device 12. It is located at the second position P2 where the flow of exhaust gas into the smoke tube 13 is blocked. The case where the exhaust bypass damper 41 is located at the first position P1 is a case where the exhaust heat recovery boiler 3 does not generate steam because the exhaust gas does not flow into the exhaust heat recovery boiler 3. That is, this is a case where power generation by a steam turbine (not shown) is not performed. On the other hand, when the exhaust bypass damper 41 is located at the second position P2, since the exhaust gas flows into the exhaust heat recovery boiler 3, the power generation by the gas turbine 2 and the power generation by the steam turbine are combined. (Combined power generation). In FIG. 4, the state where the exhaust bypass damper 41 is located at the first position P1 is shown by a solid line, and the state where the exhaust bypass damper 41 is located at the second position P2 is shown by a two-dot chain line.

  In the above configuration, when performing the purge, the control device 12 sets the exhaust bypass damper 41 to the first state during the operation of the gas turbine 2 (when preparing to shift to combined power generation while the gas turbine 2 is operating alone). The exhaust bypass damper 41 and the first purge valve 6 are arranged at the position P1 and the first purge pipe 5 is opened. In this case, as in the first embodiment, the air around the high-temperature tube group in the exhaust heat recovery boiler 3 into which the high-temperature exhaust gas has flowed immediately before is heated, so that the air at the outside air temperature is heated. Less than specific gravity. As a result, the outside air flows into the exhaust heat recovery boiler 3 from the lower portion of the exhaust heat recovery boiler 3 through the first purge pipe 5, so that a purge effect is provided by natural ventilation.

  Here, utilizing the fact that the gas turbine 2 is operating, that is, the fact that the compressor 21 is operating, the control device 12 controls the second purge valve 9 so that the second purge pipe 8 is opened. It may be controlled. In this case, the compressed air generated by the compressor 21 flows into the exhaust heat recovery boiler 3 from the extraction port 24 through the second purge pipe 8. Thus, although the efficiency of the gas turbine 2 may slightly decrease, the time required for purging can be reduced depending on the amount of compressed air used. In addition, even if the first purge valve 6 and the second purge valve 8 are opened in parallel, the flow of air from the first purge pipe 5 to the exhaust heat recovery boiler 3 is not formed. Note that the method of determining when the purging is completed by the control device 12 is the same as in the first embodiment.

  Subsequently, a control method at the time of purging by the control device 12 will be described. FIG. 5 is a flowchart showing the flow of the process of the control device 12.

  As shown in FIG. 5, the control device 12 moves the exhaust bypass damper 41 to the first position P1 during the operation of the gas turbine 2 (when preparing to shift to combined power generation while operating the gas turbine 2 alone). It is determined whether or not it has been performed (step S11). When the exhaust bypass damper 41 is located at the first position P1 (YES in step S11), the process proceeds to step S13, and when the exhaust bypass damper 41 is not located at the first position P1 (at step S11). NO), the control device 12 positions the exhaust bypass damper 41 at the first position P1 (Step S12).

  In step S13, the control device 12 opens the first purge valve 6, and then opens the second purge valve 9. Thereby, the outside air flows into the exhaust heat recovery boiler 3 through the first purge pipe 5, and then the compressed air from the compressor 21 flows into the exhaust heat recovery boiler 3 through the second purge pipe 8.

  Subsequently, the control device 12 determines whether the integrated purge flow rate has reached a predetermined amount (step S14). If the integrated purge flow rate has reached the predetermined amount (YES in step S14), the process proceeds to step S15, and if the integrated purge flow rate has not reached the predetermined amount (NO in step S14), the process of step S14 is performed again. Do.

  In step S15, the control device 12 closes the first purge valve 6 and the first purge valve 9. Thereby, the outside air and the compressed air do not flow into the exhaust heat recovery boiler 3.

  As described above, in the combined cycle power plant 1a of the second embodiment, the outside air flowing through the first purge pipe 5 and the compressed air flowing through the second purge pipe 8 can be used for purging. Therefore, although the efficiency of the gas turbine 2 may slightly decrease, the time required for purging can be reduced depending on the amount of compressed air used.

(Other embodiments)
The present invention is not limited to the above embodiments, and various modifications can be made without departing from the spirit of the present invention. For example:

  In the first and second embodiments, the buoyancy in the exhaust heat recovery boiler 3 is calculated from the difference between the temperature detected by the first temperature sensor 10 and the temperature detected by the second temperature sensor 11, and the exhaust heat recovery is performed. An integrated flow rate of the air flowing into the boiler 3 is calculated, and when the integrated flow rate reaches a predetermined amount, it is determined that the purge is completed and the first purge valve 6 is closed. However, the present invention is not limited to this. When the difference between the temperature detected by the first temperature sensor 10 and the temperature detected by the second temperature sensor 11 is within a predetermined range, it is determined that the purge is completed. The first purge valve 6 may be closed. Alternatively, the first purge valve 6 may be closed after a lapse of a predetermined time from the start of the purge.

  Further, in the first embodiment, the case where the purge is performed at the time of turning after the combustion in the gas turbine 2 is completed is described. However, the present invention is not limited to this. Purge may be performed before or after turning.

  Further, in the second embodiment, the case where the purge is performed during the operation of the gas turbine 2 has been described. However, the present invention is not limited to this. In the combined cycle power plant 1a according to the second embodiment, as in the first embodiment. It is possible to perform a purge by natural ventilation at the time of turning.

  In the second embodiment, the case where the purge is performed using the air flowing through the first purge pipe 5 and the compressed air flowing through the second purge pipe 8 has been described. Similarly, the purge may be performed using only the outside air flowing through the first purge pipe 5.

  Further, in the first and second embodiments, the first purge valve 6 and the second purge valve 9 are configured to be controlled by the control device 12, but the control device that controls the first purge valve 6 and the second purge valve A control device for controlling the valve 9 may be provided separately.

DESCRIPTION OF SYMBOLS 1 Combined cycle power plant 2 Gas turbine 3 Exhaust heat recovery boiler 4 Duct 5 First purge pipe 6 First purge valve 7 Check valve 8 Second purge pipe 9 Second purge valve 10 First temperature sensor 11 Second temperature sensor 12 Control device 13 Smoke tube 21 Compressor 22 Turbine 23 Exhaust port 24 Bleed port 31 Rotor 36 Motor 41 Exhaust bypass damper P1 First position P2 Second position

Claims (6)

A compressor that generates compressed air, and a turbine that has an exhaust port, is driven by combustion gas generated by combustion of fuel and the compressed air generated by the compressor, and discharges exhaust gas from the exhaust port. A gas turbine having
A vertical exhaust heat recovery boiler that recovers heat from the exhaust gas to generate steam,
A duct connecting the exhaust port and a lower portion of the exhaust heat recovery boiler,
A first purge pipe having one end connected to the duct and the other end open to the atmosphere and into which air flows;
A first purge valve provided in the first purge pipe;
A combined cycle power plant, comprising: a control device that controls the first purge valve so that the first purge pipe is opened.   The combined cycle power plant according to claim 1, wherein a check valve is provided in the first purge pipe upstream of the first purge valve. A first temperature sensor for detecting a temperature inside the exhaust heat recovery boiler;
A second temperature sensor that is disposed on the upstream side of the check valve in the first purge pipe and detects a temperature of the air in the first purge pipe;
The control device controls the first purge valve based on a difference between the temperature detected by the first temperature sensor and the temperature detected by the second temperature sensor so that the first purge pipe is closed. 3. The combined cycle power plant of claim 2, wherein the combined cycle power plant is configured to control. The turbine has a rotor that can be switched between a state rotated by a motor and a state separated from the motor,
The control device is configured to control the first purge valve so that the first purge pipe is opened after the end of combustion in the gas turbine and when the rotor is rotated by the motor. The combined cycle power plant according to any one of claims 1 to 3, wherein: A smoke pipe connected to the duct and discharging the exhaust gas into the atmosphere;
A first position provided in the duct, for allowing the exhaust gas to flow into the smoke tube, and blocking the flow of the exhaust gas to the exhaust heat recovery boiler; or flowing the exhaust gas to the exhaust heat recovery boiler; An exhaust bypass damper disposed at a second position for blocking inflow of exhaust gas,
The control device controls the exhaust bypass damper and the first purge valve such that the exhaust bypass damper is disposed at the first position and the first purge pipe is opened during operation of the gas turbine. The combined cycle power plant according to any one of claims 1 to 4, wherein the combined cycle power plant is configured as follows. The compressor has a bleed port through which the compressed air flows out,
A second purge pipe connecting the bleed port and the duct, and a second purge valve provided in the second purge pipe,
The combined cycle power plant according to claim 5, wherein the control device is configured to control the second purge valve such that the second purge pipe is opened when the gas turbine operates.

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