JP6390067B2 - Exhaust heat recovery system, gas turbine plant equipped with the same, and exhaust heat recovery method - Google Patents

Description

  The present invention relates to an exhaust heat recovery system that recovers exhaust heat when generating cooling air, a gas turbine plant including the exhaust heat recovery system, and an exhaust heat recovery method.

  The gas turbine includes a compressor that compresses air, a combustor that generates a combustion gas by burning fuel in the air compressed by the compressor, and a turbine that is driven by the combustion gas. In this gas turbine, the bleed air from the compressor may be supplied to high-temperature parts such as a stationary blade to cool these high-temperature parts.

  In Patent Document 1 below, bleed air from a compressor is cooled by an air cooler, and steam from an exhaust heat boiler is introduced into the air cooler as a heat medium when generating cooling air. A configuration for performing heat recovery is disclosed.

JP-A-10-169414

  However, in the technique described in Patent Document 1, the temperature difference between the bleed air from the compressor is increased due to the introduction of steam, and the exhaust heat recovery in the air cooler (cooling air cooler) is increased. There is room for improved efficiency. That is, the present situation is that cooling air having a sufficiently low temperature cannot be generated.

  Therefore, the present invention improves the recovery efficiency of exhaust heat generated when generating cooling air from the air extracted from the compressor, an exhaust heat recovery system capable of efficiently generating cooling air, a gas turbine plant, and It aims at providing the exhaust heat recovery method.

  An exhaust heat recovery system as one aspect according to the invention for achieving the above object includes a compressor that compresses air, a combustor that burns fuel in the compressed air to generate combustion gas, and a combustion gas A cooling air cooler for extracting the air from the compressor in the gas turbine having a turbine driven by the generator, generating cooling air for cooling the extracted air to cool the high-temperature components, and an exhaust from the cooling air cooler An exhaust heat recovery device that recovers heat, and the exhaust heat recovery device circulates a plurality of fluids having different temperature levels as a heat medium through the cooling air cooler, thereby recovering the exhaust heat. A plurality of recovery units to perform, wherein the plurality of recovery units sequentially recover from a heat medium having a high temperature level to a heat medium having a low temperature level from the high-temperature exhaust heat toward the low-temperature exhaust heat. The exhaust heat recovery device is configured to sequentially heat water with the low boiling point medium Rankine cycle in which the low boiling point medium circulates repeatedly by condensing and evaporating by the recovered exhaust heat and the exhaust gas from the turbine. An exhaust heat recovery boiler having a plurality of economizers, and a low-pressure economizer provided on the lowest temperature side of the plurality of economizers after supplying the water as the fluid to the cooling air cooler. The low boiling point medium Rankine cycle is driven by the heat of water from the outlet of the low pressure economizer.

  In the exhaust heat recovery system, the recovery unit may cause the cooling air cooler to circulate fluids that are the same substance and have different pressures as the plurality of fluids.

  In the above exhaust heat recovery system, the recovery unit may cause the cooling air cooler to circulate fluids that are the same substance and have different substance phases as the plurality of fluids.

  In the above exhaust heat recovery system, the recovery unit may cause fluids having different boiling points to flow through the cooling air cooler as the plurality of fluids.

  In the exhaust heat recovery system, the cooling air cooler may include an evaporator that evaporates at least one of the plurality of fluids.

  In the exhaust heat recovery system, the recovery unit in the exhaust heat recovery apparatus includes an exhaust heat recovery boiler that heats water with exhaust gas from the turbine, and the exhaust heat recovery boiler includes the plurality of exhaust heat recovery boilers. The water may be passed through the cooling air cooler as a fluid.

  In the exhaust heat recovery system, the exhaust heat recovery device may further include a steam turbine that drives the water heated by the exhaust heat recovery boiler as a working medium in addition to the exhaust heat recovery boiler. Good.

  In the above exhaust heat recovery system, the recovery unit in the exhaust heat recovery apparatus distributes steam from an outlet of the steam turbine to the cooling air cooler as at least one of the plurality of fluids. Also good.

  In the exhaust heat recovery system, the cooling air cooler may generate cooling air that cools at least one of the components of the turbine and the combustor as the high-temperature component.

  In the exhaust heat recovery system, at least three recovery units in the exhaust heat recovery apparatus may be provided.

  In the above exhaust heat recovery system, the recovery unit in the exhaust heat recovery apparatus distributes the fuel to be burned in the combustor to the cooling air cooler as at least one of the plurality of fluids. Also good.

  In the above exhaust heat recovery system, the exhaust heat recovery device may heat the fuel to be burned in the combustor with at least one of the plurality of fluids.

  A gas turbine plant as one aspect according to the invention for achieving the above object includes the above-described exhaust heat recovery system, a compressor that compresses air, and combustion gas is generated by burning fuel in the compressed air. A combustor and a gas turbine having a turbine driven by combustion gas.

An exhaust heat recovery method as one aspect according to the invention for achieving the above object includes a compressor that compresses air, a combustor that generates combustion gas by burning fuel in the compressed air, and a combustion gas An extraction step of extracting the air from the compressor in a gas turbine having a turbine driven by a cooling step, a cooling step of generating cooling air for cooling the extracted air and cooling high-temperature components, and generating the cooling air A waste heat recovery step of recovering the exhaust heat by a plurality of fluids having different temperature levels as a heat medium, and in the exhaust heat recovery step, from the high temperature exhaust heat toward the low temperature exhaust heat , Recover sequentially from heat medium with high temperature level to heat medium with low temperature level,
In the exhaust heat recovery step, the exhaust heat is recovered by driving a low boiling point medium Rankine cycle in which the low boiling point medium circulates repeatedly by condensation and evaporation, and in the exhaust heat recovery step, exhaust gas from the turbine is recovered. After recovering the exhaust heat by using water from an exhaust heat recovery boiler having a plurality of economizers that sequentially heat water with gas as the plurality of fluids, it is provided on the lowest temperature side among the plurality of economizers. The low boiling point medium Rankine cycle is driven by the heat of the water from the outlet of the low pressure economizer.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat may be recovered by fluids that are the same substance and have different pressures as the plurality of fluids.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat may be recovered by a fluid that is the same substance and has a different phase of the substance as the plurality of fluids.

  In the exhaust heat recovery method, the exhaust heat may be recovered by fluids having different boiling points as the plurality of fluids in the exhaust heat recovery step.

  In the exhaust heat recovery method, at least one of the plurality of fluids may be evaporated in the cooling step.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat may be recovered by water from an exhaust heat recovery boiler that heats water with exhaust gas from the turbine as the plurality of fluids. Good.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat is recovered by steam of water from an outlet of a steam turbine that is driven by using the water heated by the exhaust heat recovery boiler as a working medium. May be.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat generated when the cooling air is generated may be recovered as at least three fluids having different temperature levels as the heat medium.

  In the exhaust heat recovery method, in the exhaust heat recovery step, the exhaust heat may be recovered by the fuel burned in the combustor as at least one of the plurality of fluids.

  In the above exhaust heat recovery method, in the exhaust heat recovery step, the fuel to be burned in the combustor may be heated by at least one of the plurality of fluids.

  According to the above-described exhaust heat recovery system, gas turbine plant, and exhaust heat recovery method, a plurality of fluids having different temperature levels are used as a heat medium, and exhaust heat generated when generating cooling air is recovered to recover exhaust heat. Recovery efficiency can be improved and cooling air can be generated efficiently.

It is a systematic diagram of the gas turbine plant in the first reference example according to the present invention. It is a flowchart which shows the procedure of the waste heat recovery method in the gas turbine plant in the 1st reference example which concerns on this invention. It is a figure which shows the 1st collection | recovery part and the 2nd collection | recovery part in the modification of the 1st reference example which concerns on this invention, Comprising: (a) shows a 1st modification and (b) shows a 2nd modification. It is a systematic diagram of the gas turbine plant in the 2nd reference example which concerns on this invention. It is a systematic diagram of the gas turbine plant in the 3rd reference example which concerns on this invention. 1 is a system diagram of a gas turbine plant in a first embodiment according to the present invention. It is a systematic diagram of the gas turbine plant in the 4th reference example concerning the present invention. It is a systematic diagram of the gas turbine plant in the 5th reference example which concerns on this invention. It is a systematic diagram of the gas turbine plant in the modification of the 5th reference example which concerns on this invention. It is a systematic diagram of the gas turbine plant in 2nd embodiment which concerns on this invention. It is a systematic diagram of the gas turbine plant in the reference example which deform | transformed 2nd embodiment which concerns on this invention. It is a systematic diagram of the gas turbine plant in 3rd embodiment which concerns on this invention. It is a systematic diagram of the gas turbine plant in 4th embodiment which concerns on this invention. It is a systematic diagram of the gas turbine plant in the 6th reference example which concerns on this invention. It is a systematic diagram of the gas turbine plant in the 7th reference example concerning the present invention. It is a systematic diagram of the gas turbine plant in the modification of the 7th reference example which concerns on this invention.

Hereinafter, various embodiments of a gas turbine plant according to the present invention will be described with reference to the drawings.
"First Reference Example"
A first reference example of a gas turbine plant 1 according to the present invention will be described with reference to FIG.

  The gas turbine plant 1 of this reference example includes a gas turbine 10, a generator 41 that generates power by driving the gas turbine 10, a cooling air cooler 54 that generates cooling air CA that cools high-temperature components, and a cooling air cooler 54. And an exhaust heat recovery system 61 having an exhaust heat recovery device 51 that recovers the exhaust heat.

  The gas turbine 10 includes a compressor 11 that compresses air A, a combustor 21 that burns fuel F in the air A compressed by the compressor 11 to generate combustion gas G, and a high-temperature and high-pressure combustion gas G. And a turbine 31 to be driven.

  The compressor 11 has a compressor rotor 13 that rotates about an axis O, and a compressor casing 17 that covers the compressor rotor 13 rotatably.

  The turbine 31 includes a turbine rotor 33 that rotates about the axis O by the combustion gas G from the combustor 21, and a turbine casing 37 that rotatably covers the turbine rotor 33.

  The turbine rotor 33 includes a rotor shaft 34 extending in an axial direction parallel to the axis O, and moving blades 35 arranged in a plurality of stages fixed to the outer periphery of the rotor shaft 34. In addition, stationary blades 38 arranged in a plurality of stages are fixed to the inner peripheral surface of the turbine casing 37. Between the inner peripheral surface of the turbine casing 37 and the outer peripheral surface of the rotor shaft 34 is a combustion gas flow path through which the combustion gas G from the combustor 21 passes. A cooling air flow path (not shown) through which the cooling air CA flows is formed in the rotor shaft 34 and the stationary blade 38.

  The combustor 21 is fixed to the turbine casing 37. The turbine rotor 33 and the compressor rotor 13 rotate about the same axis O, and are connected to each other to form a gas turbine rotor 40. The gas turbine rotor 40 is connected to the rotor of the generator 41 described above.

  The exhaust heat recovery system 61 includes a cooling air cooler 54 that cools the air A extracted from the compressor 11 and a heat medium M that is introduced into the cooling air cooler 54 to recover the exhaust heat of the cooling air cooler 54. And a recovery device 51.

The cooling air cooler 54 extracts a part of the air A compressed by the compressor 11 (extraction process S1, see FIG. 2), cools it by heat exchange with the heat medium M such as water, and the like. It sends to the said cooling air flow path, and cools a high temperature component.
And in this reference example, the air A is extracted from the exit of the compressor 11, and the cooling air CA is produced | generated (refer cooling process S2, FIG. 2). For example, the air A may be extracted from the intermediate stage of the compressor 11, and the extraction position is not limited to the case of this reference example.

  Further, the cooling air CA generated by the cooling air cooler 54 may be used, for example, for cooling the combustor 21 or may be used for cooling the moving blade 35, and is not limited to the case of this reference example.

The exhaust heat recovery device 51 heats the first recovery unit 70 and the second recovery unit 71 that exchange heat with the air A flowing through the cooling air cooler 54, and the first recovery unit 70 and the second recovery unit 71. An exhaust heat recovery boiler 65 that supplies water W as the medium M and a water supply pump 66 that supplies the water W to the exhaust heat recovery boiler 65 are provided.
Further, the exhaust heat recovery device 51 includes a steam turbine 67 driven by the steam S generated in the exhaust heat recovery boiler 65, a generator 68 that generates electric power by driving the steam turbine 67, and the steam S that drives the steam turbine 67. And a condenser 69 for returning the water W.

  Further, the exhaust heat recovery boiler 65 has a steam generation unit 72 that generates steam S by the heat of the combustion gas G that drives the turbine 31, that is, the exhaust gas EG exhausted from the gas turbine 10. That is, the steam generation unit 72 includes a low-pressure steam generation unit 74 that generates low-pressure steam LS as the steam S, an intermediate-pressure steam generation unit 75 that generates intermediate-pressure steam MS, and a high-pressure steam generation unit 76 that generates high-pressure steam HS. It has become.

  The low-pressure steam generation unit 74 includes a low-pressure economizer 74a that heats the water W, a low-pressure evaporator 74b that converts the water W heated by the low-pressure economizer 74a to steam S, and the steam S generated by the low-pressure evaporator 74b. And a low pressure superheater 74c that generates low pressure steam LS.

  The intermediate pressure steam generator 75 includes an intermediate pressure feed water pump 75d that boosts the water W heated by the low pressure economizer 74a, and an intermediate pressure economizer 75a that heats the water W boosted by the intermediate pressure feed pump 75d. And an intermediate pressure evaporator 75b that converts the water W heated by the intermediate pressure economizer 75a into steam S, and an intermediate pressure overheat that generates the intermediate pressure steam MS by superheating the steam S generated in the intermediate pressure evaporator 75b. 75c.

  The high pressure steam generator 76 includes a high pressure feed pump 76f that boosts the water W heated by the low pressure economizer 74a, a first high pressure economizer 76a that heats the water W boosted by the high pressure feed pump 76f, A second high pressure economizer 76b that further heats the water W heated by the first high pressure economizer 76a, a high pressure evaporator 76c that converts the water W heated by the second high pressure economizer 76b into steam S, The first high-pressure superheater 76d that superheats the steam S generated in the high-pressure evaporator 76c to generate the high-pressure steam HS, and the second high-pressure superheater 76e that further superheats the high-pressure steam HS.

  Elements constituting each of the high-pressure steam generator 76, the medium-pressure steam generator 75, and the low-pressure steam generator 74 are the second high-pressure superheater 76e, the first high-pressure steam generator 76e, from the turbine 31 toward the downstream side of the exhaust gas EG. Superheater 76d, high pressure evaporator 76c, second high pressure economizer 76b, medium pressure superheater 75c and low pressure superheater 74c, medium pressure evaporator 75b, first high pressure economizer 76a and medium pressure economizer 75a, low pressure The evaporator 74b and the low-pressure economizer 74a are arranged in this order.

  The steam turbine 67 includes a low pressure steam turbine 77 driven by the low pressure steam LS from the exhaust heat recovery boiler 65, an intermediate pressure steam turbine 78 driven by the intermediate pressure steam MS, and a high pressure steam turbine 79 driven by the high pressure steam HS. Is provided.

  The high-pressure steam turbine 79 is connected to the second high-pressure superheater 76e in the exhaust heat recovery boiler 65 at the inlet.

  Here, the exhaust heat recovery boiler 65 drives the high-pressure steam turbine 79 to discharge the steam S and the first reheater 83 and the second reheater 83 that superheat the medium pressure steam MS from the outlet of the medium pressure superheater 75c. A reheater 84 is further provided. The first reheater 83 is disposed upstream of the first high pressure superheater 76 d in the exhaust heat recovery boiler 65 in the flow of the exhaust gas EG, and the second reheater 84 is more than the first reheater 83. It is on the upstream side and is disposed at substantially the same position as the second high-pressure superheater 76e.

  That is, the high pressure steam turbine 79 is connected to the inlet of the first reheater 83 at the outlet.

  The intermediate pressure steam turbine 78 is connected at its inlet to the outlet of the second reheater 84.

  The low pressure steam turbine 77 is connected at its inlet to the outlet of the low pressure superheater 74 c and the intermediate pressure steam turbine 78. Moreover, it is connected to the condenser 69 at the exit.

  The generator 68 is provided in each of the low pressure steam turbine 77, the intermediate pressure steam turbine 78, and the high pressure steam turbine 79. Note that the generator 68 is not limited to being provided in each, and only one of the steam turbines 67 may be provided in common.

  The condenser 69 collects the steam S from the outlet of the low-pressure steam turbine 77 and generates liquid water W.

  The first recovery unit 70 is a heat exchanger provided in the cooling air cooler 54, and its inlet is connected to the outlet of the low-pressure economizer 74 a in the exhaust heat recovery boiler 65, and the outlet is the inlet of the high-pressure evaporator 76 c. It is connected to the. Then, water W (fluid) from the low pressure economizer 74a as the heat medium M is circulated to the cooling air cooler 54 by the high pressure feed water pump 76f, and then flows into the high pressure evaporator 76c, and the air A extracted from the compressor 11 and The exhaust heat from the cooling air cooler 54 is recovered by exchanging heat with the water W from the low pressure economizer 74a (exhaust heat recovery step S3, see FIG. 2).

  The second recovery unit 71 is a heat exchanger provided in the cooling air cooler 54 on the downstream side of the flow of the air A extracted from the compressor 11 with respect to the first recovery unit 70, and the inlet thereof is a condenser. 69 is connected to the outlet of the low-pressure economizer 74a. Then, the water W (fluid) from the condenser 69 as the heat medium M is circulated through the cooling air cooler 54 and then flows into the low-pressure economizer 74 a and extracted from the compressor 11 and the condenser 69. Exhaust heat from the cooling air cooler 54 is recovered by exchanging heat with the water W from the exhaust air (see exhaust heat recovery step S3, FIG. 2).

In this way, the air A flowing through the cooling air cooler 54 is cooled by first exchanging heat with the first recovery unit 70 and then cooled by exchanging heat with the second recovery unit 71. As a result, the cooling air CA is obtained.
And the water W which distribute | circulates the 1st collection | recovery part 70 has a high pressure (and temperature) compared with the water W which distribute | circulates the 2nd collection | recovery part 71, and becomes a fluid from which a temperature level differs as the heat medium M. ing.
Here, “different temperature levels” mean that the temperature of at least one of the inlet and outlet of the heat medium is significantly different. In addition, “high temperature level” means that the temperature of at least one of the inlet and outlet of the heat medium is high and suitable for heat exchange with higher temperature air, and “low temperature level”. "" Means that the temperature of at least one of the inlet and outlet of the heat medium is low and suitable for heat exchange with cooler air.

  The feed water pump 66 is provided between the condenser 69 and the second recovery unit 71, and uses the second recovery unit 71 to supply the water W generated from the steam S recovered from the low pressure steam turbine 77 to the low pressure economizer. 74a.

  According to such a gas turbine plant 1, exhaust heat is recovered by circulating a plurality of fluids having different temperature levels as the heat medium M to the cooling air cooler 54 by the first recovery unit 70 and the second recovery unit 71. It is supposed to be. Therefore, the cooling temperature width of the air A can be increased as compared with the case where the exhaust heat from the cooling air cooler 54 is recovered by the heat medium M at one temperature level and the air A is cooled.

  That is, for example, first, the heat medium M having a temperature level corresponding to the temperature of the air A extracted from the compressor 11 by the first recovery unit 70 is supplied to the cooling air cooler 54 and cooled. Thereafter, the heat medium M having a temperature level corresponding to the temperature of the air A whose temperature has decreased by the first recovery unit 70 is supplied to the cooling air cooler 54 by the second recovery unit 71, and the air A is further cooled. Thereby, the cooling temperature width of the air A can be increased.

  As a result, the cooling air CA having a sufficiently low temperature can be generated and used for cooling of the high-temperature components, so that the effect of preventing damage to the high-temperature components can be improved. Further, since the temperature of the cooling air CA can be lowered, the high-temperature components can be sufficiently cooled even if the flow rate of the cooling air CA is reduced. Therefore, the flow rate of the air A extracted from the compressor 11 can be reduced, and the operation efficiency and output of the gas turbine 10 can be improved.

  Furthermore, even if the heat medium M circulated in the first recovery part 70 and the second recovery part 71 is the same substance and phase fluid, the saturation temperature differs due to different pressures. Can be easily varied. For example, in this reference example, the water W flowing through the first recovery unit 70 has a higher pressure than the water W flowing through the second recovery unit 71, so that it boils at the pressure of the water W flowing through the second recovery unit 71. Exhaust heat can be recovered in the liquid phase up to the temperature level where it does. Therefore, the cooling temperature width of the air A can be increased while using the same substance and phase fluid as the fluids having different temperature levels. That is, the fluid flowing through the first recovery unit 70 and the second recovery unit 71 can be supplied from one exhaust heat recovery boiler 65, and the structure of the first recovery unit 70 and the second recovery unit 71 can be simplified by using a common apparatus. The cooling air CA having a sufficiently low temperature can be easily generated.

  Furthermore, the waste heat from the cooling air cooler 54 can be recovered by using the water W from the exhaust heat recovery boiler 65 and the steam turbine 67 as the heat medium M. That is, the exhaust heat recovery system 61 can function as a part of the combined cycle, and the cost can be reduced by making the equipment common.

  According to the gas turbine plant 1 of the present reference example, a plurality of fluids having different temperature levels are used as the heat medium M, and the exhaust heat generated when the cooling air CA is generated is recovered, thereby improving the recovery efficiency of the exhaust heat. Therefore, the cooling air CA can be generated efficiently.

  Here, as shown in FIG. 3A, the first recovery unit 70A has a first heat exchange unit 70Aa, a second heat exchange unit 70Ab, and a third heat exchange unit 70Ac. The exhaust heat from the air cooler 54 may be recovered. And the water W which distribute | circulates the 2nd collection | recovery part 71A becomes a fluid of the same temperature level as the water W which distribute | circulates the 2nd heat exchange part 70Ab in 70 A of 1st collection | recovery, ie, temperature becomes substantially the same. As described above, the water W is introduced into the first recovery unit 70A and the second recovery unit 71A from predetermined locations of the exhaust heat recovery boiler 65, respectively.

  Moreover, as shown in FIG.3 (b), 1st collection | recovery part 70B has 2nd heat exchange part 70Bb of the downstream of the flow of the air A rather than 1st heat exchange part 70Ba and 1st heat exchange part 70Ba. The second recovery unit 71B has a third heat exchange unit 71Ba and a fourth heat exchange unit 71Bb on the downstream side of the flow of air A from the third heat exchange unit 71Ba, and the cooling air cooler sequentially at these four locations. The exhaust heat from 54 may be recovered. And the water W which distribute | circulates 2nd heat exchange part 70Bb and 3rd heat exchange part 71Ba becomes a fluid of the mutually same temperature level, ie, the temperature is substantially the same, that is, exhaust heat recovery boiler 65 Water W is introduced into the first recovery unit 70B and the second recovery unit 71B from the predetermined locations.

  Thus, in the modified example of the present reference example, the exhaust heat from the cooling air cooler 54 is recovered in parallel between the first recovery units 70A and 70B and the second recovery units 71A and 71B. In the case shown in FIG. 3 (a), a parallel recovery unit including a second heat exchange unit 70Ab and a second recovery unit 71A is provided. Moreover, in the case shown in FIG.3 (b), the parallel collection | recovery part comprised from 2nd heat exchange part 70Bb and 3rd heat exchange part 71Ba is provided.

"Second Reference Example"
Next, a second reference example of the gas turbine plant 101 according to the present invention will be described with reference to FIG.

  The gas turbine plant 101 of the present reference example is different from the first reference example in that the heat medium M flowing through the first recovery unit 120 and the second recovery unit 121 is based on the gas turbine plant 1 of the first reference example. Yes.

  The first recovery unit 120 has an inlet connected to the outlet of the high-pressure evaporator 76c in the exhaust heat recovery boiler 65, and an outlet connected to the inlet of the second high-pressure superheater 76e. Then, the steam S (fluid) from the high-pressure evaporator 76 c is circulated as the heat medium M through the cooling air cooler 54 and then flows into the second high-pressure superheater 76 e. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  The second recovery unit 121 has an inlet connected to the outlet of the first high-pressure economizer 76a in the exhaust heat recovery boiler 65, and an outlet connected to the inlet of the high-pressure evaporator 76c. Then, the water W (fluid) from the first high pressure economizer 76a is circulated through the cooling air cooler 54 as the heat medium M and then flows into the high pressure evaporator 76c. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

Thus, the air A flowing through the cooling air cooler 54 is cooled by first exchanging heat with the first recovery unit 120 and then cooled by exchanging heat with the second recovery unit 121. As a result, the cooling air CA is obtained.
And the steam S which distribute | circulates the 1st collection | recovery part 120 and the water W which distribute | circulates the 2nd collection | recovery part 121 are mutually the same substances, and the phase of a substance differs, and it is a temperature level as the heat medium M. Are different fluids.

  According to the gas turbine plant 101 of this reference example, the phases (gas phase, liquid phase) are different even if the heat medium M flowing in the first recovery unit 120 and the second recovery unit 121 is a fluid of the same substance. It is possible to vary the temperature level. That is, the gas phase is at a temperature level higher than the saturation temperature, and the liquid phase is at a temperature level lower than the saturation temperature. Therefore, it is possible to increase the cooling temperature width of the air A while using fluids of the same substance as fluids having different temperature levels. For this reason, the fluid which circulates through the 1st recovery part 120 and the 2nd recovery part 121 can be supplied from one exhaust heat recovery boiler 65, and the structure of the 1st recovery part 120 and the 2nd recovery part 121 is made common by an apparatus. It is possible to make it simple, and it is possible to easily generate the cooling air CA having a sufficiently low temperature.

“Third Reference Example”
Next, a third reference example of the gas turbine plant 141 according to the present invention will be described with reference to FIG.

  The gas turbine plant 141 of the present reference example has the gas turbine plant 1 of the first reference example as a basic configuration, and the heat medium M flowing through the first recovery unit 170 and the second recovery unit 171 is different from that of the first reference example. In addition, the exhaust heat recovery device 151 further includes a low boiling point medium Rankine cycle 165.

  The first recovery unit 170 has an inlet connected to an outlet of the low-pressure economizer 74a in the exhaust heat recovery boiler 65, and an outlet connected to an inlet of the high-pressure evaporator 76c. Then, the water W (fluid) from the low-pressure economizer 74a is circulated through the cooling air cooler 54 as the heat medium M and then flows into the high-pressure evaporator 76c. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  The low boiling point medium Rankine cycle 165 includes a low boiling point medium turbine 167 (hereinafter simply referred to as a turbine 167) by circulating a medium having a lower boiling point than the water W (hereinafter referred to as a low boiling point medium LM) by repeating condensation and evaporation. This is a cycle for driving the

Examples of the low boiling point medium LM include the following substances.
・ Organic halogen compounds such as trichloroethylene, tetrachloroethylene, monochlorobenzene, dichlorobenzene and perfluorodecalin ・ Alkanes such as butane, propane, pentane, hexane, heptane, octane and decane ・ Cyclic alkanes such as cyclopentane and cyclohexane Aromatic compounds ・ Refrigerants such as R134a and R245fa,
・ A combination of the above

  The low-boiling-point medium Rankine cycle 165 includes a second recovery unit 171 that is an evaporator that heats and evaporates a liquid low-boiling-point medium LM, a turbine 167 that is driven by the evaporated low-boiling-point medium LM, and a drive of the turbine 167. A generator 168 for generating electricity, a steam recovery line 180 connecting the outlet of the turbine 167 and the inlet of the second recovery unit 171, a pump 166 provided in the steam recovery line 180, and an outlet of the turbine 167 through the steam recovery line 180 And a condenser 169 that cools and condenses the low boiling point medium LM that drives the turbine 167. That is, the low boiling point medium Rankine cycle 165 of this reference example is a so-called simple low boiling point medium Rankine cycle.

  In this reference example, the second recovery unit 171 also functions as an evaporator of the low boiling point medium Rankine cycle 165, and the low boiling point medium LM is removed by exhaust heat when the cooling air CA generates the cooling air CA. Evaporate. That is, the second recovery unit 171 has an inlet connected to the condenser 169 and an outlet connected to the inlet of the turbine 167.

In this way, the air A flowing through the cooling air cooler 54 is cooled by first exchanging heat with the first recovery unit 170 and then cooled by exchanging heat with the second recovery unit 171. As a result, the cooling air CA is obtained.
And the water W which distribute | circulates the 1st collection | recovery part 170 and the low boiling-point medium LM which distribute | circulates the 2nd collection | recovery part 171 are the fluids from which a boiling point differs mutually and a temperature level differs as the heat medium M.

  According to the gas turbine plant 141 of the present reference example, the fluid as the heat medium M that circulates in the first recovery unit 170 is water W, and the fluid as the heat medium M that circulates in the second recovery unit 171 is the low boiling point medium LM. It is. Then, by using fluids having different boiling points, that is, fluids having different temperature levels, for cooling the air A in the cooling air cooler 54, it is possible to generate the cooling air CA having a sufficiently low temperature.

  Furthermore, since the low boiling point medium Rankine cycle 165 is provided, the low boiling point medium Rankine cycle 165 is driven by the exhaust heat from the cooling air cooler 54, so that the exhaust heat can be effectively used.

  In this reference example, a plurality of low boiling point medium Rankine cycles (two in the case of this reference example) driven by the low boiling point medium LM having different boiling points are provided. You may introduce into the 2 collection | recovery part 171, respectively.

"First embodiment"
Next, with reference to FIG. 6, 1st embodiment of the gas turbine plant 191 which concerns on this invention is described.

  The gas turbine plant 191 of the present embodiment is based on the gas turbine plant 1 in the first reference example, and the exhaust heat recovery device 192 is added to the first recovery unit 70 and the second recovery unit 71, It further has a third recovery part 196 provided on the upstream side of the flow of air A with respect to the second recovery part 71, and has a low-boiling-point medium Rankine cycle 165 similar to that of the third reference example.

  The third recovery unit 196 has an inlet connected to the outlet of the high-pressure evaporator 76c in the exhaust heat recovery boiler 65, and an outlet connected to the inlet of the second high-pressure superheater 76e. Then, the steam S (fluid) from the high-pressure evaporator 76 c is circulated as the heat medium M through the cooling air cooler 54 and then flows into the second high-pressure superheater 76 e. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

As described above, the air A flowing through the cooling air cooler 54 is first cooled by exchanging heat with the third recovery unit 196, then, the first recovery unit 70, and then the second recovery unit 71. The cooling air CA is obtained by performing heat exchange between the two and being cooled.
And the steam S which distribute | circulates the 3rd collection | recovery part 196 differs from the water W which distribute | circulates the 1st collection | recovery part 70, and the water W which distribute | circulates the 2nd collection | recovery part 71, These are fluids from which a temperature level differs mutually as the heat medium M It has become.

  The low boiling point medium Rankine cycle 165 further includes an evaporator 198 that is separate from the second recovery unit 71. And the water W from the exit of the low pressure economizer 74a in the exhaust heat recovery boiler 65 is introduced into the evaporator 198, and after flowing through the evaporator 198, it flows into the inlet of the low pressure economizer 74a. Thereby, the low boiling point medium LM is indirectly evaporated by the water W from the outlet of the low pressure economizer 74a which is the heat medium M different from the low boiling point medium LM.

  According to the gas turbine plant 191 of this embodiment, water W from the exhaust heat recovery boiler 65, which is a fluid different from the low boiling point medium LM, is used as the heat medium M supplied to the cooling air cooler 54, and this fluid and the low boiling point are used. The low boiling point medium Rankine cycle 165 is driven by exchanging heat with the medium LM. For this reason, by adjusting the flow rate of the heat medium M, it becomes easy to control the amount of exhaust heat recovered to the low boiling point medium Rankine cycle 165.

  Further, while the exhaust heat recovery from the cooling air cooler 54 is performed by the exhaust heat recovery boiler 65, the low boiling point medium Rankine cycle 165 is utilized using the heat of the water W heated by the low pressure economizer 74a in the exhaust heat recovery boiler 65. Since it can be driven, low-temperature exhaust heat can be effectively used.

  In addition, since the three recovery units of the first recovery unit 70, the second recovery unit 71, and the third recovery unit 196 are provided, the cooling air cooler 54 can be used as the heat medium M by the fluid at three different temperature levels. The air A can be cooled. Therefore, the cooling air CA having a lower temperature can be generated.

"Fourth Reference Example"
Next, a fourth reference example of the gas turbine plant 201 according to the present invention will be described with reference to FIG.

  The gas turbine plant 201 of this reference example is based on the gas turbine plant 1 of the first reference example, and the exhaust heat recovery device 251 is added to the first recovery unit 270 and the second recovery unit 271, and the first recovery unit 270. Furthermore, the evaporator 272 provided in the upstream of the flow of the air A extracted from the compressor 11 and the superheater 273 provided further upstream than the evaporator 272 are further provided.

  The inlet of the first recovery unit 270 is connected to the outlet of the low-pressure economizer 74 a in the exhaust heat recovery boiler 65. Then, the water W (fluid) from the low-pressure economizer 74 a as the heat medium M is circulated through the cooling air cooler 54 by the medium-pressure feed water pump 75 d and then flows into the evaporator 272 provided in the cooling air cooler 54.

  The second recovery unit 271 has an inlet connected to the outlet of the condenser 69 and an outlet connected to an inlet of the low-pressure evaporator 74b (an outlet of the low-pressure economizer 74a). Then, water W (fluid) from the condenser 69 is circulated through the cooling air cooler 54 as the heat medium M and then flows into the low pressure evaporator 74b, the first recovery unit 270, and the first high pressure economizer 76a. In this way, heat exchange is performed between the air A extracted from the compressor 11 and the water W from the condenser 69, and the exhaust heat from the cooling air cooler 54 is recovered.

  The evaporator 272 has an inlet connected to the outlet of the first recovery unit 270, evaporates the water W flowing through the first recovery unit 270 as the heat medium M by a heat source (not shown), and generates steam S in the cooling air cooler 54. Is generated.

  The superheater 273 has an inlet connected to an outlet of the evaporator 272, and an outlet connected to an inlet of the second reheater 84 in the exhaust heat recovery boiler 65. And after making the vapor | steam S from the evaporator 272 flow in and heating, it is made to flow in into the 2nd reheater 84. FIG.

  Thus, the air A flowing through the cooling air cooler 54 is cooled by first exchanging heat with the first recovery unit 270 and then cooled by exchanging heat with the second recovery unit 271. As a result, the cooling air CA is obtained. Further, when the water W as the heat medium M is evaporated and superheated by the evaporator 272 and the superheater 273 in the cooling air cooler 54, heat exchange is performed with the air A to cool the air A. The That is, in the present reference example, the first recovery unit 270 functions as a economizer, and the steam S is generated by the evaporator 272 and the superheater 273. Therefore, the exhaust heat recovery device 251 is disposed in the cooling air cooler 54. The configuration corresponding to the exhaust heat recovery boiler is provided.

  As in the first reference example, the water W flowing through the first recovery unit 270 has a higher pressure (and temperature) than the water W flowing through the second recovery unit 271, and the heat medium M As a result, the fluid has different temperature levels.

  According to the gas turbine plant 201 of this reference example, the phase of the fluid can be changed by the cooling air cooler 54 by the evaporator 272, so that the exhaust heat for the latent heat due to the phase change is recovered from the air A from the compressor 11. Can do. Therefore, the amount of exhaust heat recovered by the cooling air cooler 54 can be increased, the cooling air CA having a lower temperature can be generated, and the high-temperature components can be sufficiently cooled.

"Fifth Reference Example"
Next, a fifth reference example of the gas turbine plant 301 according to the present invention will be described with reference to FIG.

  The gas turbine plant 301 of this reference example is based on the gas turbine plant 1 of the first reference example, and the exhaust heat recovery device 351 is added to the first recovery unit 370 and the second recovery unit 371 in addition to the first recovery unit 370. A first evaporator 373 provided between the second recovery unit 371, a second evaporator 374 provided on the upstream side of the flow of air A extracted from the compressor 11 with respect to the first recovery unit 370, and It has a superheater 375 provided further upstream than the second evaporator 374.

  The inlet of the first recovery unit 370 is connected to the outlet of the low-pressure economizer 74 a in the exhaust heat recovery boiler 65. Then, after the water W (fluid) from the low pressure economizer 74a is circulated to the cooling air cooler 54 by the medium pressure feed water pump 75d as the heat medium M, it flows into the second evaporator 374 provided in the cooling air cooler 54. Let

  The inlet of the second recovery unit 371 is connected to the outlet of the condenser 69. Then, the water W (fluid) from the condenser 69 is circulated as the heat medium M through the cooling air cooler 54 and then flows into the first evaporator 373 provided in the cooling air cooler 54.

  The first evaporator 373 has an inlet connected to the outlet of the second recovery unit 371 and an outlet connected to the low-pressure superheater 74 c in the exhaust heat recovery boiler 65. And the water W from the 2nd collection | recovery part 371 is evaporated, the vapor | steam S is produced | generated, and this vapor | steam S is made to flow in into the low voltage | pressure superheater 74c. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  The inlet of the second evaporator 374 is connected to the outlet of the first recovery unit 370. And the water W from the 1st collection | recovery part 370 is evaporated and the vapor | steam S is produced | generated.

  The superheater 375 has an inlet connected to the outlet of the second evaporator 374 and an outlet connected to the inlet of the second reheater 84 in the exhaust heat recovery boiler 65. Then, the steam S from the second evaporator 374 is superheated and flows into the second reheater 84. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  Thus, the air A flowing through the cooling air cooler 54 is first cooled by exchanging heat with the first recovery unit 370 and then cooled by exchanging heat with the second recovery unit 371. As a result, the cooling air CA is obtained. Further, when the water WW as the heat medium M is evaporated and superheated in the cooling air cooler 54 by the first evaporator 373, the second evaporator 374, and the superheater 375, the air A and the water W (steam S ), And the air A is cooled. That is, in this reference example, the first recovery unit 370 and the second recovery unit 371 function as a economizer, and steam S is generated by the first evaporator 373, the second evaporator 374, and the superheater 375. Therefore, the exhaust heat recovery device 351 has a configuration corresponding to an exhaust heat recovery boiler in the cooling air cooler 54.

  As in the first reference example, the water W flowing through the first recovery unit 370 has a higher pressure (and temperature) than the water W flowing through the second recovery unit 371, and the heat medium M As a result, the fluid has different temperature levels.

  According to the gas turbine plant 301 of the present reference example, the fluid can be phase-changed by the cooling air cooler 54 by the first evaporator 373 and the second evaporator 374, so that the latent heat due to the phase change from the air A from the compressor 11. The exhaust heat of the minute can be recovered. Accordingly, the amount of exhaust heat recovered from the cooling air cooler 54 can be increased, and the cooling air cooler 54 can generate the cooling air CA having a lower temperature, thereby sufficiently cooling the high-temperature components.

Here, as shown in FIG. 9, the exhaust heat recovery device 351 of the present reference example includes a third recovery unit as a superheater between the second evaporator 374 and the superheater 375 in the cooling air cooler 54. 376 may be further included.
The third recovery unit 376 has, for example, an inlet connected to the outlet of the first evaporator 373 and an outlet connected to the outlet of the low-pressure superheater 74 c in the exhaust heat recovery boiler 65, that is, the inlet of the low-pressure steam turbine 77. . Then, by introducing the steam S from the first evaporator 373 into the low-pressure steam turbine 77, the exhaust heat is recovered by the cooling air cooler 54.

  As described above, in this reference example, the number and arrangement of the recovery unit, the evaporator, and the superheater can be appropriately selected according to the balance of the temperature and flow rate of the heat medium M supplied to the cooling air cooler 54.

"Second embodiment"
Next, a second embodiment of the gas turbine plant 401 according to the present invention will be described with reference to FIG.

  The gas turbine plant 401 of this embodiment is based on the gas turbine plant 191 of the first embodiment, and the third recovery unit 476 is different from that of the first embodiment.

  The third recovery unit 476 has an inlet connected to the outlet of the high-pressure steam turbine 79 and the outlet of the intermediate pressure superheater 75 c in the exhaust heat recovery boiler 65, and the outlet connected to the inlet of the second reheater 84. Yes. Then, the medium pressure steam MS (fluid) from the medium pressure superheater 75 c is circulated through the cooling air cooler 54 as the heat medium M and then flows into the second reheater 84. Thereby, the exhaust heat from the cooling air cooler 54 is recovered.

As described above, the air A flowing through the cooling air cooler 54 is first cooled by exchanging heat with the third recovery unit 476, and then the first recovery unit 70 and then the second recovery unit 71. The cooling air CA is obtained by performing heat exchange between the two and being cooled.
The temperature levels of the medium pressure steam MS flowing through the third recovery unit 476, the water W flowing through the first recovery unit 70, and the water W flowing through the second recovery unit 71 are different from each other, and the temperature level is high. In order, the medium pressure steam MS flowing through the third recovery unit 476, the water W flowing through the first recovery unit 70, and the water W flowing through the second recovery unit 71 are in this order.

  According to the gas turbine plant 401 of the present embodiment, the exhaust heat from the cooling air cooler 54 is recovered by supplying the steam S from the steam turbine 67 to the cooling air cooler 54, and therefore, compared with the high-pressure steam HS (S). Then, the steam S having a low pressure and temperature is supplied to the cooling air cooler 54. Therefore, the heat resistance strength in the cooling air cooler 54 can be suppressed, and the cost of the cooling air cooler 54 can be reduced. Further, the steam S from the steam turbine 67 can be reheated by exhaust heat from the cooling air cooler 54. Furthermore, since the steam S from the steam turbine 67 is used as the heat medium M, the temperature of the heat medium M can be brought close to the temperature of the air A even when the air A extracted by the compressor 11 is at a high temperature. Thus, exhaust heat recovery can be performed.

  In the present embodiment, the water W from the condenser 69 is used as the heat medium M to flow into the second recovery unit 71, and after heat recovery, the temperature is further increased by the low-pressure economizer 74a. The exhaust heat is recovered in the cycle 165, but as shown in FIG. 11 as a reference example in which this embodiment is modified, the low boiling point medium Rankine cycle 165 is not used and a part of the condensate from the condenser 69 is used. Some water W may be flowed into the second recovery part 71 as the heat medium M, and after heat recovery, it may be joined to the outlet of the low pressure economizer 74a.

  That is, the second recovery unit 71 has an inlet connected to the outlet of the condenser 69 and an outlet connected to the outlet of the low-pressure economizer 74a. Then, the water W whose temperature has risen in the second recovery unit 71 is further pressurized and heated and used in the steam turbine 67. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  Here, in a large gas turbine, the temperature of the air extracted from the compressor may become as high as 400 ° C. or more as the pressure ratio increases. In order to efficiently recover exhaust heat when cooling such high-temperature air, it is necessary to bring the temperature of water as a heat medium close to the air temperature. However, since the critical temperature of water is 374 ° C., it is difficult to cool such high-temperature air with liquid water. In this regard, in the present embodiment, since the steam S that is gaseous water W is used as the heat medium M in the third recovery unit 476, the temperature difference between the air A and the heat medium M can be reduced. The exhaust heat recovery efficiency of A can be improved.

  On the other hand, in order to effectively cool a high-temperature component with a small amount of cooling air, it is preferable to cool the air used for cooling from several tens of degrees Celsius to several hundreds of degrees Celsius. However, in order to cool the air to such a low temperature, a heat medium having a lower temperature is required, and such a heat medium is limited to low-pressure water or the like in the gas turbine combined plant. Since the saturation temperature of the low-pressure water is several hundreds of degrees Celsius, the low-temperature water supply cannot recover exhaust heat to a temperature higher than that without using phase change. Therefore, in order to reduce the temperature difference between the air and the heat medium, a heat medium having a temperature level between the steam and the low-pressure water is further required. Therefore, by using the high-pressure water W (liquid water W) as the heat medium M in the first recovery unit 70 and using the low-pressure water W (liquid water W) as the heat medium M in the second recovery unit 71, The temperature difference between the air A extracted from the compressor 11 and the heat medium M can be reduced, and the heat recovery efficiency of the air A can be improved.

"Third embodiment"
Next, a third embodiment of the gas turbine plant 501 according to the present invention will be described with reference to FIG.

  The gas turbine plant 501 of the present embodiment further includes an auxiliary compressor 555 in which the exhaust heat recovery device 551 boosts the air A extracted from the compressor 11 based on the gas turbine plant 191 in the first embodiment. ing.

  The auxiliary compressor 555 is provided between the cooling air cooler 54 and the compressor 11, and raises the pressure after introducing the air A extracted from the compressor 11 into the cooling air cooler 54. That is, in the cooling air cooler 54, the air A is cooled by the first recovery unit 70, the second recovery unit 71, and the third recovery unit 196, and then pressurized to be the cooling air CA and introduced into the combustor 21. .

  According to the gas turbine plant 501 of the present embodiment, the pressure and temperature of the air A extracted from the compressor 11 by the auxiliary compressor 555 can be adjusted and introduced into the combustor 21 as the cooling air CA. For this reason, the amount of heat exchange between the cooling air A and the combustor 21 can be adjusted, and the cooling effect of the high-temperature components in the combustor 21 can be improved.

"Fourth embodiment"
Next, with reference to FIG. 13, 4th embodiment of the gas turbine plant 601 which concerns on this invention is described.

  The gas turbine plant 601 of the present embodiment is based on the gas turbine plant 191 of the first embodiment, the exhaust heat recovery boiler 65 is different from the first embodiment, and the steam turbine 67 and generator of the first embodiment. 68 and the condenser 69 are not provided. Further, the third collection unit 676 is different.

  The inlet of the third recovery unit 676 is connected to the outlet of the high-pressure evaporator 76c in the exhaust heat recovery boiler 65, and the outlet is connected to the inlet of the second high-pressure superheater 76e. Then, the steam S (fluid) from the high-pressure evaporator 76 c is circulated as the heat medium M through the cooling air cooler 54 and then flows into the second high-pressure superheater 76 e. Thereby, the exhaust heat from the cooling air cooler 54 is recovered.

As described above, the air A flowing through the cooling air cooler 54 is first cooled by exchanging heat with the third recovery unit 676, and then the first recovery unit 70 and then the second recovery unit 71. The cooling air CA is obtained by performing heat exchange between the two and being cooled.
And the steam S which distribute | circulates the 3rd collection | recovery part 676 differs from the water W which distribute | circulates the 1st collection | recovery part 70, and the water W which distribute | circulates the 2nd collection | recovery part 71, These are fluids from which a temperature level differs as a heat medium M mutually. It has become.

  According to the gas turbine plant 601 of the present embodiment, by recovering the exhaust heat from the cooling air cooler 54 using the water W of the exhaust heat recovery boiler 65 as the heat medium M, the cost can be reduced due to the common use of equipment. That is, the exhaust heat recovery system 661 can function as a part of the cogeneration system.

"Sixth Reference Example"
Next, a sixth reference example of the gas turbine plant 701 according to the present invention will be described with reference to FIG.

  The gas turbine plant 701 of the present reference example has a gas turbine plant 401 in a reference example (see FIG. 11) modified from the second embodiment as a basic configuration, and a heat medium M flowing through the first recovery unit 770 is different.

  The first recovery unit 770 has an inlet connected to a fuel supply unit 773 that supplies fuel F used in the combustor 21, and an outlet connected to the combustor 21. Then, the fuel F (fluid) from the fuel supply unit 773 is circulated through the cooling air cooler 54 as the heat medium M and then flows into the combustor 21. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  According to the gas turbine plant 701 of the present reference example, the fuel F can be heated by recovering the exhaust heat from the cooling air cooler 54 by the fuel F of the combustor 21 as the heat medium M in the first recovery unit 770. .

  Here, in a large gas turbine, the temperature of the air extracted from the compressor may become as high as 400 ° C. or more as the pressure ratio increases. In order to efficiently cool such high-temperature air when the combustor fuel is used as a heat medium, the temperature of the fuel needs to be close to the air temperature. However, flashback can occur when the temperature of the fuel becomes high. In this respect, in this reference example, after the air A is first cooled by the third recovery unit 476 using the steam S as the heat medium M, the air A reaches a temperature suitable for heating the fuel F. Heat is exchanged between the air A and the fuel F in the recovery unit 770. Therefore, the fuel F can be heated while preventing the fuel F from being backfired.

  Furthermore, by using the low-pressure water W (liquid water W) as the heat medium M in the second recovery unit 71, the temperature difference between the air A extracted from the compressor 11 and the heat medium M can be suppressed small. The cooling efficiency of the air A can be improved.

"Seventh Reference Example"
Next, a sixth reference example of the gas turbine plant 801 according to the present invention will be described with reference to FIG.

  The gas turbine plant 801 of the present reference example is based on the gas turbine plant 401 in the reference example (see FIG. 11) obtained by modifying the second embodiment, except that the first recovery unit 870 is different, and the exhaust heat recovery device 851. Further includes a preheating unit 880 for preheating the fuel F.

  The first recovery unit 870 has an inlet connected to the outlet of the low pressure economizer 74a in the exhaust heat recovery boiler 65, and an outlet connected to the inlet of the second high pressure economizer 76b. Then, the water W (fluid) from the low pressure economizer 74a is circulated as the heat medium MM to the cooling air cooler 54 by the high pressure feed pump 76f and then flows into the second high pressure economizer 76b. In this way, the exhaust heat from the cooling air cooler 54 is recovered.

  The preheating unit 880 is a heat exchanger provided between the outlet of the first recovery unit 870 and the second high pressure economizer 76b, and the fuel F from the fuel supply unit 773 is introduced, and the first recovery unit The fuel F is preheated by exchanging heat with the water W from 870.

  According to the gas turbine plant 801 of this reference example, the heating amount of the fuel F can be easily adjusted by indirectly heating the fuel F without directly heating it with the exhaust heat from the cooling air cooler 54. In addition, since the preheating unit 880 uses liquid water W, that is, by using the heat medium M having a large density and heat transfer coefficient in the preheating unit 880, the preheating unit 880 can be downsized.

  Here, in this reference example, the installation position of the preheating part 880 is not limited to the above-mentioned case. For example, as shown in FIG. 16, the first recovery unit 970 is connected at its inlet to the outlet of the first high-pressure economizer 76a, connected at the outlet to the inlet of the high-pressure evaporator 76c, and the preheating unit 980 is It may be provided between the inlet of the recovery unit 9770 and the outlet of the first high pressure economizer 76a.

"Other variations of gas turbine plant"
Although the gas turbine plant of each reference example, embodiment, and modification example described above has been described, various other modification examples can be employed as described below.

  For example, four or more of the recovery units in the exhaust heat recovery apparatus may be provided.

  The configurations of the above-described embodiments can be combined as appropriate.

1 ... Gas turbine plant
10 ... Gas turbine
11 ... Compressor
13 ... Compressor rotor
17 ... Compressor casing
21 ... Combustor
31 ... Turbine
33 ... Turbine rotor
34 ... Rotor shaft
35 ... Rotor blade
37 ... Turbine casing
38 ... Static wings
40 ... Gas turbine rotor
41 ... Generator
54 ... Cooling air cooler
51 ... Waste heat recovery device
61 ... Waste heat recovery system
65 ... Waste heat recovery boiler
66 ... Water supply pump
67 ... Steam turbine
68 ... Generator
69 ... Condenser
70: First recovery unit
71. Second recovery unit
72 ... Steam generating section
74 ... Low pressure steam generator
75 ... Medium pressure steam generator
76 ... High-pressure steam generator
74a ... Low pressure economizer
74b ... Low pressure evaporator
74c ... Low pressure superheater
75a ... Medium pressure economizer
75b ... Medium pressure evaporator
75c ... Medium pressure superheater
75d ... Medium pressure feed pump
76a ... The first high pressure economizer
76b ... Second high pressure economizer
76c ... High pressure evaporator
76d ... first high pressure superheater
76e ... second high pressure superheater
76f ... High pressure water supply pump
77 ... Low pressure steam turbine
78 ... Medium pressure steam turbine
79 ... High pressure steam turbine
83. First reheater
84 ... Second reheater
O ... axis
CA ... cooling air
M ... Heat medium
A ... Air
F ... Fuel
G ... Combustion gas
S ... Steam
EG ... Exhaust gas
W ... water
LS ... Low pressure steam
MS ... Medium pressure steam
HS ... high pressure steam
70A ... First recovery unit
70Aa ... 1st heat exchange part
70 Ab ... second heat exchange section
70Ac ... Third heat exchange section
71A ... Second recovery unit
70B ... 1st collection part
70Ba ... 1st heat exchange part
70Bb ... Second heat exchange section
71B ... Second recovery unit
71Ba ... Third heat exchange section
71Bb ... Fourth heat exchange section
101 ... Gas turbine plant
120 ... First recovery section
121. Second recovery unit
141 ... Gas turbine plant
151 ... Waste heat recovery device
165: Low boiling point medium Rankine cycle
166 ... Pump
167 (low boiling point medium) turbine
168 ... Generator
169 ... Condenser
170 ... first recovery section
171 ... Second recovery unit
180 ... Steam recovery line
LM ... Low boiling point medium
191 ... Gas turbine plant
192 ... Waste heat recovery device
196 ... Third recovery department
198 ... Evaporator
201 ... Gas turbine plant
251 ... Waste heat recovery device
270 ... First recovery unit
271 ... Second recovery unit
272 ... Evaporator
273 ... Superheater
301 ... Gas turbine plant
351 ... Waste heat recovery device
370 ... First recovery unit
371 ... Second recovery unit
373 ... First evaporator
374 ... Second evaporator
375 ... Superheater
376 ... Third recovery unit
401 ... Gas turbine plant
476 ... Third recovery section
501 ... Gas turbine plant
551 ... Waste heat recovery device
555 ... Auxiliary compressor
601 ... Gas turbine plant
651 ... Waste heat recovery device
661 ... Waste heat recovery system
676 ... Third recovery section
701 ... Gas turbine plant
770 ... First recovery unit
773 ... Fuel supply unit
801 ... Gas turbine plant
851 ... Waste heat recovery device 870 ... First recovery unit
880 ... Preheating part
970 ... First recovery unit
980 ... Preheating part

Claims (23)

Extracting the air from the compressor in a gas turbine having a compressor for compressing air, a combustor for burning fuel in the compressed air to generate combustion gas, and a turbine driven by the combustion gas; A cooling air cooler that generates cooling air that cools the extracted air and cools high-temperature components;
An exhaust heat recovery device for recovering exhaust heat from the cooling air cooler;
With
The exhaust heat recovery device has a plurality of recovery units that recover the exhaust heat by causing a plurality of fluids having different temperature levels to flow as heat media to the cooling air cooler,
The plurality of recovery units are arranged so as to sequentially recover from a heat medium having a high temperature level to a heat medium having a low temperature level from the high-temperature exhaust heat toward the low-temperature exhaust heat,
The exhaust heat recovery device includes:
A low-boiling-point medium Rankine cycle in which the low-boiling-point medium circulates repeatedly by condensation and evaporation by the recovered exhaust heat;
An exhaust heat recovery boiler having a plurality of economizers that sequentially heat water with exhaust gas from the turbine;
After supplying the water as the fluid to the cooling air cooler, a water supply unit that supplies a low-pressure economizer provided on the coldest side among the economizers;
Have
The low boiling point medium Rankine cycle is an exhaust heat recovery system driven by the heat of water from the outlet of the low pressure economizer. The exhaust heat recovery system according to claim 1,
The said recovery part is an exhaust heat recovery system which distribute | circulates the fluid which is mutually the same substance as the said some fluid, and mutually differs in a pressure to the said cooling air cooler. In the exhaust heat recovery system according to claim 1 or 2,
The said recovery part is an exhaust-heat recovery system which distribute | circulates the fluid which is mutually the same substance as the said some fluid, and the phase of a substance differs to the said cooling air cooler. In the exhaust heat recovery system according to claim 1 or 2,
The recovery unit is an exhaust heat recovery system in which fluids having different boiling points are circulated through the cooling air cooler as the plurality of fluids. In the exhaust heat recovery system according to any one of claims 1 to 4,
The cooling air cooler is an exhaust heat recovery system having an evaporator for evaporating at least one of the plurality of fluids. In the exhaust heat recovery system according to any one of claims 1 to 5,
The recovery unit in the exhaust heat recovery apparatus has an exhaust heat recovery boiler that heats water with exhaust gas from the turbine,
The exhaust heat recovery boiler is an exhaust heat recovery system that distributes the water as the plurality of fluids to the cooling air cooler. The exhaust heat recovery system according to claim 6,
In addition to the exhaust heat recovery boiler, the exhaust heat recovery device further includes a steam turbine that drives the water heated by the exhaust heat recovery boiler as a working medium. The exhaust heat recovery system according to claim 7,
The recovery unit in the exhaust heat recovery apparatus is an exhaust heat recovery system that distributes steam from an outlet of the steam turbine to the cooling air cooler as at least one of the plurality of fluids. In the exhaust heat recovery system according to any one of claims 1 to 8,
The cooling air cooler is an exhaust heat recovery system that generates cooling air that cools at least one of the components of the turbine and the combustor as the high-temperature component. In the exhaust heat recovery system according to any one of claims 1 to 9,
An exhaust heat recovery system in which at least three of the recovery units in the exhaust heat recovery apparatus are provided. In the exhaust heat recovery system according to any one of claims 1 to 10,
The recovery unit in the exhaust heat recovery apparatus is an exhaust heat recovery system that distributes the fuel burned in the combustor to the cooling air cooler as at least one of the plurality of fluids. In the exhaust heat recovery system according to any one of claims 1 to 10,
The exhaust heat recovery device is an exhaust heat recovery system that heats the fuel burned in the combustor with at least one of the plurality of fluids. An exhaust heat recovery system according to any one of claims 1 to 12,
A compressor for compressing air, a combustor for combusting fuel in the compressed air to generate combustion gas, and a gas turbine having a turbine driven by the combustion gas;
A gas turbine plant comprising: An extraction step of extracting air from the compressor in a gas turbine having a compressor that compresses air, a combustor that burns fuel in the compressed air to generate combustion gas, and a turbine that is driven by the combustion gas When,
A cooling step for cooling the extracted air to generate cooling air for cooling high-temperature components;
An exhaust heat recovery step of recovering exhaust heat when the cooling air is generated by a plurality of fluids having different temperature levels as a heat medium;
Including
In the exhaust heat recovery step, from the high-temperature exhaust heat toward the low-temperature exhaust heat, the heat medium having a high temperature level is sequentially recovered from the heat medium having a low temperature level,
In the exhaust heat recovery step, the exhaust heat is recovered by driving a low boiling point medium Rankine cycle in which the low boiling point medium circulates repeatedly by condensation and evaporation,
In the exhaust heat recovery process, after recovering the exhaust heat using water from an exhaust heat recovery boiler having a plurality of economizers that sequentially heat water with exhaust gas from the turbine as the plurality of fluids, An exhaust heat recovery method in which the low boiling point Rankine cycle is driven by the heat of water from an outlet of the low pressure economizer, which is supplied to a low pressure economizer provided on the lowest temperature side of the economizer. The exhaust heat recovery method according to claim 14,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat using fluids that are the same substance and have different pressures as the plurality of fluids. The exhaust heat recovery method according to claim 14,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat using fluids that are the same substance and have different phases of the substances as the plurality of fluids. The exhaust heat recovery method according to claim 14,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat using fluids having different boiling points as the plurality of fluids. The exhaust heat recovery method according to any one of claims 14 to 17,
In the cooling step, an exhaust heat recovery method for evaporating at least one of the plurality of fluids. The exhaust heat recovery method according to any one of claims 14 to 18,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat with water from an exhaust heat recovery boiler that heats water with exhaust gas from the turbine as the plurality of fluids. The exhaust heat recovery method according to claim 19,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat by steam of water from an outlet of a steam turbine that drives the water heated by the exhaust heat recovery boiler as a working medium. The exhaust heat recovery method according to any one of claims 14 to 20,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat generated when the cooling air is generated by at least three fluids having different temperature levels as the heat medium. The exhaust heat recovery method according to any one of claims 14 to 21,
In the exhaust heat recovery step, the exhaust heat recovery method recovers the exhaust heat with the fuel burned in the combustor as at least one of the plurality of fluids. The exhaust heat recovery method according to any one of claims 14 to 21,
In the exhaust heat recovery step, the exhaust heat recovery method of heating the fuel burned in the combustor with at least one of the plurality of fluids.

Images