JP2004132357A - Combined power generation plant - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a means forming a system for dumping to a condenser steam generated, in combined power generation with a steam-power generation plant and a gas turbine plant combined without the need for an additional receiving port of the condenser in a conventional plant. <P>SOLUTION: This combined power generation plant consisting of the steam-power generation plant and the gas turbine plant comprises a system 1 having a main steam pipe 60 and the condenser 25 connected to each other for dumping the steam generated in a combustion boiler 10 to the condenser 25 bypassing a steam turbine, a HRSG high pressure turbine bypass system 2 connected with a high pressure steam pipe 70 of an exhaust heat recovery boiler, and a HRSG low pressure turbine bypass system 3 connected with a low pressure steam pipe 71 thereof. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a combined power plant that combines a steam power plant and a gas turbine plant.
[0002]
[Prior art]
A combined power plant consisting of a steam power plant consisting of a combustion boiler, a steam turbine, and a condenser, and a gas turbine plant consisting of a gas turbine and a waste heat recovery boiler. There is known a power generation plant that drives a steam turbine by combining steam and steam generated by an exhaust heat recovery boiler of a gas turbine plant.
[0003]
Japanese Patent Application Laid-Open No. 2000-220412, for example, relates to this type of power plant.
[0004]
[Patent Document 1]
JP-A-2000-220412 (FIG. 1)
[0005]
[Problems to be solved by the invention]
The power generation plant has a system for dumping steam generated in the boiler to a condenser at the time of starting and stopping, at the time of load interruption, and the like. The above prior art is a power plant that combines a steam power plant and a gas turbine plant. Since there are two steam boilers, a combustion boiler and a waste heat recovery boiler, a system that dumps the generated steam into a condenser Need to be installed in two systems, the system configuration becomes complicated, and it is necessary to install a plurality of condenser inlets.
[0006]
An object of the present invention is to provide means for constructing a system for dumping generated steam to a condenser without increasing the number of condenser inlets from that of a conventional plant.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, a combined cycle power plant of the present invention connects a steam pipe of a combustion boiler and a condenser, bypasses a steam generated by the combustion boiler and dumps the steam to a condenser, and A pipe connecting the exhaust heat recovery boiler steam pipe to the system for dumping to the condenser is provided.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0009]
<< Example 1 >>
One embodiment of a combined cycle power plant according to the present invention will be described with reference to FIG.
[0010]
This power plant mainly includes a combustion boiler 10, a main steam pipe 60, a low-temperature reheat steam pipe 61, a high-temperature reheat steam pipe 62, a high-, medium-, and low-pressure steam turbine 21, 22, 23, A steam power plant including a water heater 25 and a condensate / water supply system, a gas turbine 40 and an exhaust heat recovery boiler 50 using exhaust gas from the gas turbine 40 as a heat source, and exhaust heat recovery from a high-pressure steam pipe 70 and a low-pressure steam pipe 71. It is composed of two facilities of a gas turbine plant composed of boiler steam pipes.
[0011]
In FIG. 1, feed water supplied to a combustion boiler 10 is heated by a economizer 12 and generated in an evaporator 13. The generated steam is guided as superheated steam to the high-pressure steam turbine 21 by the main steam pipe 60 connecting the evaporator 13 and the high-pressure steam turbine 21 while being superheated by the primary superheater 14 and the secondary superheater 15. On the other hand, the steam generated by the exhaust heat recovery boiler 50 joins the main steam pipe 60 by the high pressure steam pipe 70 connecting the high pressure drum 51 and the main steam pipe 60, and flows into the high pressure steam turbine 21 as superheated steam. .
[0012]
The steam after driving the high-pressure steam turbine 21 passes through the low-temperature reheat steam pipe 61 and is guided to the reheater 11 of the combustion boiler 10. The steam superheated by the reheater 11 is supplied to the medium-pressure steam turbine 22 via the high-temperature reheat steam pipe 62. On the other hand, the steam generated in the exhaust heat recovery boiler 50 is joined to the high-temperature reheat steam pipe 62 by the low-pressure steam pipe 71 connecting the low-pressure drum 52 and the high-temperature reheat steam pipe 62, and is similarly superheated steam to medium-pressure steam. It flows into the turbine 22.
[0013]
The steam after driving the medium-pressure steam turbine 22 passes through the crossover pipe 63 and is guided to the low-pressure steam turbine 23. Further, the steam after driving the low-pressure steam turbine 23 is guided to the condenser 25 to be condensed.
[0014]
The condensed water condensed in the condenser 25 is pressurized by the condensate pump 30 and heated by the ground steam condenser 31, and then condensed in the steam power plant and supplied to the exhaust heat recovery boiler 50 in the gas turbine plant. Branched to
[0015]
The condenser system of the steam power plant is provided with a condenser pipe 65 connecting the condenser 25 and the deaerator 34. Then, the condensed water of the steam power plant is heated by the low-pressure feed water heater 32 and deaerated by the deaerator 34 to be supplied water. Further, a water supply pipe 66 connecting the deaerator 34 and the combustion boiler 10 is provided in a water supply system of the steam power plant. The feedwater of the steam power plant is pressurized by a feedwater pump 36 and heated by a high-pressure feedwater heater 37 before returning to the combustion boiler 10.
[0016]
On the other hand, the water supply from the gas turbine plant passes through the water supply pipe 72, flows into the exhaust heat recovery boiler 50 using the exhaust gas of the gas turbine 40 as a heat source, and becomes steam by heat exchange with the gas turbine exhaust gas. The high-pressure steam pipe 70 connecting the pipes 60 joins the main steam pipe 60 and drives the high-pressure steam turbine 21 as superheated steam.
[0017]
Further, the feedwater branched inside the exhaust heat recovery boiler 50 and sent to the low-pressure drum 52 becomes steam by heat exchange with the gas turbine exhaust gas, and is connected to the low-pressure drum 52 and the high-temperature reheat steam pipe 62. The pipe 71 joins the high-temperature reheat steam pipe 62 and drives the medium-pressure steam turbine 22 as superheated steam.
[0018]
The power generation during the normal operation is performed by the above-described cycle, and the electric energy of the power generation plant is supplied to the steam turbine generator 24 driven by the high, medium, and low pressure steam turbines 21, 22, and 23 having the rotating shafts directly connected thereto, and the gas turbine. It is generated from a gas turbine generator 44 driven by.
[0019]
During normal operation, the steam is operated according to the above-mentioned cycle.However, in a steam power plant, when the generated steam cannot be vented to the steam turbine, such as during start-up / stop and load shedding, the generated steam is transferred to the condenser. A system for dumping will be installed. In the present embodiment, as this system, a turbine bypass system 1 configured to be branched from the main steam pipe 60 and connected to the condenser 25 through a turbine bypass valve 8 and a pipe is installed. With this turbine bypass system 1, steam generated in the combustion boiler 10 can be dumped to the condenser 25.
[0020]
On the other hand, as the turbine bypass system for the steam generated in the exhaust heat recovery boiler 50, the HRSG high-pressure turbine bypass system 2 branched from the high-pressure steam pipe 70 and connected to the turbine bypass system 1 and the low-pressure steam pipe 71 are branched. Then, the HRSG low-pressure turbine bypass system 3 connected to the turbine bypass system 1 is installed.
[0021]
That is, in the present embodiment, the HRSG high-pressure turbine bypass system 2 (HRSG low-pressure turbine bypass system 3), which is the second turbine bypass system, is configured as a system connected in the middle of the first turbine bypass system 1. The turbine bypass system 1 from the connection point of the high-pressure turbine bypass system 2 (HRSG low-pressure turbine bypass system 3) to the condenser 25 is shared as a bypass system for the steam generated by the combustion boiler 10 and the exhaust heat recovery boiler 50. ing.
[0022]
When constructing a parallel power generation system combining a steam power plant, a gas turbine, and an exhaust heat recovery boiler, a part of the turbine bypass system 1 is also used as a turbine bypass system in the exhaust heat recovery boiler 50 as in this embodiment. Thus, the size and complexity of the condenser 25 are not caused, and the equipment cost of the condenser and the turbine bypass system can be greatly reduced. In addition, if a gas turbine plant is added to an existing steam power plant and repowered, significant remodeling of the condenser is required, and in some cases, remodeling may not be possible. By configuring a bypass system, these problems can be solved.
[0023]
The start-up of this plant is performed by starting the steam power plant and then starting the gas turbine plant. Therefore, first, the combustion boiler 10 is started, the steam generated in the combustion boiler 10 is discharged to the condenser 25 by the turbine bypass system 1, and the pressure temperature of the steam generated in the combustion boiler 10 is changed according to the ventilation conditions for the steam turbine. After satisfying the above, the air is passed to the steam turbine. Then, the entire amount of steam generated in the combustion boiler 10 is introduced into the steam turbine, and the operation state is such that the turbine bypass system 1 is not used, or the steam amount from the combustion boiler 10 to the turbine bypass system 1 becomes equal to or less than a specified value. And then start the gas turbine plant. The steam generated from the exhaust heat recovery boiler 50 is sent to the turbine bypass system 1 via the HRSG high-pressure turbine bypass system 2 and the HRSG low-pressure turbine bypass system 3, and further discharged to the condenser 25. After the pressure temperature of the high-pressure steam from the exhaust heat recovery boiler 50 satisfies the mixing condition into the main steam, and the pressure temperature of the low pressure steam from the exhaust heat recovery boiler 50 satisfies the mixing condition into the high-temperature reheat steam. After that, steam from each exhaust heat recovery boiler is mixed into the main steam pipe 60 and the high-temperature reheat steam pipe 62, and the turbine bypass system 1 is not used. As described above, the turbine bypass system 1 of the combustion boiler 10 is sequentially used by the combustion boiler 10 and the exhaust heat recovery boiler 50, so that each of the turbine bypass systems 2 and 3 from the exhaust heat recovery boiler is connected to the turbine bypass system 1 of the combustion boiler 10. It is possible to connect to the system 1.
[0024]
The operation as described above is achieved by the control device 80 monitoring the state of opening of the turbine bypass valve 8 and the like, and permitting the gas turbine 40 to start when the above operation state is satisfied.
[0025]
When the load is cut off and the steam turbine is tripped, the steam generated in the steam power plant and the gas turbine plant cannot be simultaneously passed through the steam turbine, so that the steam generated by the turbine bypass system 1 alone cannot be processed. For this reason, it is preferable to install an air release valve 64 for discharging steam generated in the steam power plant and the gas turbine plant to the atmosphere in the steam pipe of the combustion boiler or the steam pipe of the exhaust heat recovery boiler.
[0026]
According to the combined cycle power plant of the present embodiment, it is not necessary to install a system for dumping steam generated in each plant of the steam power plant and the gas turbine plant to the condenser. The generated steam can be dumped to the condenser without increasing it from the conventional plant. Also, by monitoring the operating state of the gas turbine plant and steam power plant and starting each plant, the steam generated in the gas turbine plant or steam power plant will not be dumped to the condenser at the same time, It is possible to reduce the capacity of the dump system.
[0027]
Although the representative embodiment of the present invention is as described above, the system for dumping the generated steam to the condenser has various configurations, and other embodiments will be described below.
[0028]
<< Example 2 >>
FIG. 2 shows a second embodiment of the combined cycle power plant according to the present invention. The same parts as those of FIG. 1 are denoted by the same reference numerals, and the description thereof will be omitted. The illustration of the control device 80 is omitted.
[0029]
A turbine bypass system 1 is installed as a system for dumping generated steam to a condenser. The turbine bypass system of the present embodiment is configured such that it branches off from the main steam pipe 60 at the outlet of the primary superheater 14, passes through the pipe and the flash tank 4, and is connected to the condenser 25 through the pipe. By the turbine bypass system 1, steam generated at the time of starting the combustion boiler 10 is dumped to the condenser 25.
[0030]
On the other hand, as a turbine bypass system for the steam generated in the exhaust heat recovery boiler 50, the HRSG high-pressure turbine bypass system 2 branched from the high-pressure steam pipe 70 and connected to the flash tank 4 and the low-pressure steam pipe 71 branched. The HRSG low-pressure turbine bypass system 3 connected to the flash tank 4 is installed. Here, the connection destination of each turbine bypass system from the exhaust heat recovery boiler 50 may be not only the flash tank 4 but also a pipe near the flash tank 4.
[0031]
<< Example 3 >>
FIG. 3 shows a third embodiment of the combined cycle power plant according to the present invention. The same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals, and description thereof will be omitted. Only different points will be described here. . The illustration of the control device 80 is omitted.
[0032]
As a turbine bypass system of the combustion boiler 10, a high-pressure turbine bypass system 1 a branched from the main steam pipe 60 and connected to a low-temperature reheat steam pipe 61, and connected to a condenser 25 branch from a high-temperature reheat steam pipe 62. A low-pressure turbine bypass system 1b is installed. Further, a superheater steam pipe drain system 5 for connecting the main steam pipe 60 and the condenser 25 is provided. As a system for dumping the generated steam to the condenser, there are a main steam pipe drain system 5 and a low-pressure turbine bypass system 1b.
[0033]
The turbine bypass of the HRSG generated steam is configured such that the HRSG high-pressure turbine bypass system 2 is connected to the main steam pipe drain system 5 and the HRSG low-pressure turbine bypass system 3 is connected to the low-pressure turbine bypass system 1b.
[0034]
<< Example 4 >>
Fourth Embodiment A combined power plant according to a fourth embodiment of the present invention is shown in FIG. 4. The same parts as those in FIGS. 1 to 3 are denoted by the same reference numerals, and description thereof will be omitted. Only different points will be described here. . The illustration of the control device 80 is omitted.
[0035]
In the present embodiment, a secondary superheater bypass system 6 that connects the main steam pipe 60 and the condenser 25 is provided. As a system for dumping the generated steam to the condenser, there are a secondary superheater bypass system 6 and a low-pressure turbine bypass system 1b.
[0036]
The turbine bypass system for the steam generated in the exhaust heat recovery boiler 50 branches from the HRSG high-pressure turbine bypass system 2 branched from the high-pressure steam pipe 70 and connected to the secondary superheater bypass system 6, and branches from the low-pressure steam pipe 71. Then, the HRSG low-pressure turbine bypass system 3 connected to the low-pressure turbine bypass system 1b is installed.
[0037]
<< Example 5 >>
FIG. 5 shows a fifth embodiment of the combined cycle power plant according to the present invention. The same parts as those in FIGS. 1 to 4 are denoted by the same reference numerals, and description thereof will be omitted. Only different points will be described here. . The illustration of the control device 80 is omitted.
[0038]
In this embodiment, a superheater inlet dump system 7 that connects the main steam pipe 60 and the condenser 25 is provided. As a system for dumping the generated steam to the condenser, there are a superheater inlet dump system 7 and a turbine bypass system 1.
[0039]
The turbine bypass system for the steam generated in the exhaust heat recovery boiler 50 branches from the high-pressure steam pipe 70 and is connected to the turbine bypass system 1 and is connected to the HRSG high-pressure turbine bypass system 2 and the low-pressure steam pipe 71 and superheated. An HRSG low-pressure turbine bypass system 3 connected to the vessel inlet dump system 7 is installed.
[0040]
<< Example 6 >>
FIG. 6 shows a sixth embodiment of the combined cycle power plant according to the present invention. The same parts as those in FIGS. 1 to 5 are denoted by the same reference numerals, and the description thereof is omitted. . The illustration of the control device 80 is omitted.
[0041]
In the present embodiment, a desuperheater 9 is installed in the turbine bypass system 1, and both the HRSG high-pressure turbine bypass system 2 and the HRSG low-pressure turbine bypass system 3 are connected to the turbine bypass system 1. The pipe extends from the bypass valve 8 to the temperature reducer 9.
[0042]
Considering the construction type of the combined cycle power plant, in addition to the case where the combined cycle power plant is newly constructed as described above, the case where a gas turbine plant is newly added to the existing steam power plant, It is conceivable that the gas turbine plant will be newly constructed and the existing equipment will be used for the steam turbine and the like.
[0043]
When constructing a new power plant, it is not necessary to install a system for dumping steam generated in each of the steam power plant and the gas turbine plant into the condenser. In addition, even when a gas turbine plant is added to an existing steam power plant, there is no need to install a new inlet for a system to dump the steam generated by the exhaust heat recovery boiler to the condenser, and No major remodeling of the water dispenser is required.
[0044]
【The invention's effect】
According to the present invention, it is not necessary to install a system for dumping steam generated in each of a steam power plant and a gas turbine plant into a condenser, so that the number of condenser inlets is increased from that of a conventional plant. Therefore, a system for dumping the generated steam to the condenser can be configured.
[Brief description of the drawings]
FIG. 1 is a schematic diagram of a combined cycle power plant according to a first embodiment of the present invention.
FIG. 2 is a schematic diagram of a combined cycle power plant according to a second embodiment of the present invention.
FIG. 3 is a schematic diagram of a combined cycle power plant according to a third embodiment of the present invention.
FIG. 4 is a schematic diagram of a combined cycle power plant according to a fourth embodiment of the present invention.
FIG. 5 is a schematic diagram of a combined cycle power plant according to a fifth embodiment of the present invention.
FIG. 6 is a schematic diagram of a combined cycle power plant according to Embodiment 6 of the present invention.
[Explanation of symbols]
1. Turbine bypass system 2. HRSG high-pressure turbine bypass system 3.
HRSG low pressure turbine bypass system, 4 ... flash tank, 5 ... main steam pipe drain system, 6 ... secondary superheater bypass system, 7 ... superheater inlet dump system, 8 ... turbine bypass valve, 9 ... cooler, 10 ... Combustion boiler, 11 reheater, 12 economizer, 13 evaporator, 14 primary superheater, 15 secondary superheater, 21 high-pressure steam turbine, 22 medium-pressure steam turbine, 23 low-pressure Steam turbine, 24: Steam turbine generator, 25: Condenser, 30: Condenser pump, 31: Ground steam condenser, 32: Low pressure feedwater heater, 34: Deaerator, 36: Feedwater pump, 37 ... High pressure feed water heater, 40 ... gas turbine, 41 ... compressor, 42 ... turbine, 43 ... combustor, 44 ... gas turbine generator, 50 ... exhaust heat recovery boiler (HRSG), 51 ... high pressure drum, 52 ... low pressure drum , 60 ... Lord Trachea, 61 ... cold reheat steam pipe, 62 ... hot reheat steam pipe,
63 ... crossover pipe, 64 ... atmospheric release valve, 70 ... high pressure steam pipe, 71 ... low pressure steam pipe, 72 ... water supply pipe, 80 ... control device.

Claims (13)

A combustion boiler, a steam boiler steam pipe comprising a main steam pipe, a low-temperature reheat steam pipe and a high-temperature reheat steam pipe, a steam turbine, a condenser, and a steam power plant comprising a condensate / water supply system;
A gas turbine, an exhaust heat recovery boiler that uses the exhaust gas of the gas turbine as a heat source, and a gas turbine plant that includes an exhaust heat recovery boiler steam pipe that supplies generated steam from the exhaust heat recovery boiler to the steam turbine. In a combined cycle power plant,
A system that connects the combustion boiler steam pipe and the condenser, and that dumps steam generated in the combustion boiler to the condenser by bypassing the steam turbine;
A combined cycle power plant, comprising: a pipe for connecting the exhaust heat recovery boiler steam pipe and a system for dumping to the condenser. The system for dumping to the condenser is a turbine bypass system having a flash tank, and a connection position of the exhaust heat recovery boiler steam pipe and the system for dumping to the condenser is set to the flash tank of the turbine bypass system or 2. The combined cycle power plant according to claim 1, wherein a pipe is provided near the flash tank. The system for dumping to the condenser has a turbine bypass valve, and connects a connection position between the exhaust heat recovery boiler steam pipe and the system for dumping to the condenser with a pipe from the turbine bypass valve to the condenser. The combined cycle power plant according to claim 1, wherein: The system for dumping to the condenser has a turbine bypass valve and a temperature reducer, and the connection position of the exhaust heat recovery boiler steam pipe and the system for dumping to the condenser is changed from the turbine bypass valve to the temperature reduction. The combined cycle power plant according to claim 1, wherein a pipe to the vessel is provided. The system for dumping to the condenser is a main steam pipe drain system of the steam power plant. 2. The combined cycle power plant according to claim 1, wherein said pipe is a pipe. The system for dumping to the condenser is a superheater bypass system of the steam power plant. The combined cycle power plant according to claim 1, wherein: 7. A valve provided in a system for dumping to the condenser, and a control device for controlling a start timing of the gas turbine plant by using a state value of the valve as an input, is provided. A combined cycle power plant according to item 1. A combustion boiler, a steam boiler steam pipe comprising a main steam pipe, a low-temperature reheat steam pipe and a high-temperature reheat steam pipe, a steam turbine, a condenser, and a steam power plant comprising a condensate / water supply system;
A gas turbine, a gas turbine plant including an exhaust heat recovery boiler that uses the exhaust gas of the gas turbine as a heat source, and an exhaust heat recovery boiler steam pipe that supplies generated steam from the exhaust heat recovery boiler to the steam turbine;
A system that connects the combustion boiler steam pipe and the condenser, and that dumps steam generated in the combustion boiler to the condenser by bypassing the steam turbine;
A method for starting a combined cycle power plant having a pipe for connecting a system for dumping the exhaust heat recovery boiler steam pipe and the condenser,
Activating the combustion boiler, inputting the activation state of the combustion boiler to a state value of a valve provided in a dump system to the condenser, so that the combustion boiler does not use the dump system to the condenser. Or determining that the steam amount of the system dumping from the combustion boiler to the condenser has become equal to or less than a prescribed value, and activating the gas turbine plant when the condition is satisfied. How to start a combined cycle power plant. A combustion boiler, a steam boiler steam pipe comprising a main steam pipe, a low-temperature reheat steam pipe and a high-temperature reheat steam pipe, a steam turbine, a condenser, and a steam power plant comprising a condensate / water supply system;
A gas turbine, a gas turbine plant including an exhaust heat recovery boiler that uses the exhaust gas of the gas turbine as a heat source, and an exhaust heat recovery boiler steam pipe that supplies generated steam from the exhaust heat recovery boiler to the steam turbine;
A system that connects the combustion boiler steam pipe and the condenser, and that dumps steam generated in the combustion boiler to the condenser by bypassing the steam turbine;
A control device for a combined cycle power plant used in a combined cycle power plant having a pipe connecting a system for dumping the exhaust heat recovery boiler steam pipe and the condenser,
The state value of the valve provided in the dump system to the condenser is input, and the combustion boiler is in a state not using the dump system to the condenser, or from the combustion boiler to the condenser. A control device for a combined cycle power plant, comprising: determining that a steam amount of a system to be dumped has become equal to or less than a specified value, and controlling to start the gas turbine plant when the condition is satisfied. A gas turbine plant that is added to an existing steam power plant, wherein the gas turbine is a gas turbine, an exhaust heat recovery boiler that uses exhaust gas from the gas turbine as a heat source, and an exhaust heat recovery boiler from the exhaust heat recovery boiler. It consists of an exhaust heat recovery boiler steam pipe that supplies generated steam to a steam turbine,
The exhaust heat recovery boiler steam pipe is connected to a system that connects a steam boiler steam pipe of the steam power plant and a condenser and that dumps steam generated in the combustion boiler to the condenser by bypassing the steam turbine. A gas turbine plant having piping. A valve is provided in a dump system to the condenser of the steam power plant, and a state value of the valve is input, so that the combustion boiler does not use the dump system to the condenser, or It is determined that the steam amount of the system dumping from the combustion boiler to the condenser has become equal to or less than a specified value, and when the condition is satisfied, control is performed so as to start the gas turbine plant. Item 11. The gas turbine plant according to item 10. A steam boiler, a steam turbine driven by steam generated by the combustion boiler, and a steam power plant having a condenser for condensing steam discharged from the steam turbine,
In a combined cycle power plant comprising a gas turbine and a gas turbine plant having an exhaust heat recovery boiler that generates steam for driving the steam turbine using the gas turbine as a heat source,
A combined power plant wherein a part of a turbine bypass system for generated steam of each of the combustion boiler and the exhaust heat recovery boiler is shared, and the steam turbine is supplied to the condenser by bypassing the steam turbine. . A combustion boiler, a steam turbine driven by steam generated by the combustion boiler, a combustion boiler steam pipe for supplying steam generated by the combustion boiler to the steam turbine, and condensing steam discharged from the steam turbine A steam power plant having a condenser; and
A gas turbine, a gas turbine plant having an exhaust heat recovery boiler that uses the gas turbine as a heat source, and an exhaust heat recovery boiler steam pipe that supplies steam generated by the exhaust heat recovery boiler to the combustion boiler steam pipe. In the combined power plant that is configured,
A first turbine bypass system that bypasses the steam turbine with steam generated by the combustion boiler flowing down the combustion boiler steam pipe;
A second turbine bypass system for flowing steam generated by the exhaust heat recovery boiler, which is supplied to the steam turbine via the combustion boiler steam pipe and flows down the exhaust heat recovery boiler steam pipe, to bypass the combustion boiler steam pipe; And
A configuration in which the first and second turbine bypass systems are partially shared, so that steam generated by the combustion boiler and / or the exhaust heat recovery boiler to be bypassed is dumped to the condenser through the shared system. Combined power plant characterized by the following.

Images