KR20190100391A - Natural Gas Combined Cycle Power Generation System and Natural Gas Combined Cycle Power Generation Method - Google Patents

Abstract

It is a natural gas combined cycle power generation system, and is provided with a vaporizer, a cooler, a circulation flow path, a pump, and a gas turbine combined cycle power generation apparatus. The vaporizer includes an intermediate medium having a freezing point lower than the freezing point of water, and water discharged from the cooler. An intermediate medium evaporation unit for evaporating at least a portion of the intermediate medium by heat exchange, and a liquefied natural gas vaporization unit for vaporizing at least a portion of the liquefied natural gas by heat-exchanging the intermediate medium and the liquefied natural gas.

Description

Natural Gas Combined Cycle Power Generation System and Natural Gas Combined Cycle Power Generation Method

The present invention relates to a natural gas combined cycle power generation system.

BACKGROUND ART Conventionally, a natural gas combined cycle power generation system is known that uses cold heat recovered from liquefied natural gas in a vaporizer for vaporizing liquefied natural gas (LNG) to cool air supplied to a gas turbine combined cycle power generator.

For example, Patent Document 1 discloses an LNG combined cycle power plant equipped with an LNG vaporizer, a gas turbine intake cooler, a gas turbine intake cooling water circulation system, a gas turbine intake cooling water circulation pump, and a gas turbine power generator. have. The LNG vaporizer includes a heat transfer pipe for flowing LNG. In this LNG vaporizer, LNG is vaporized by heat-exchanging the LNG which flows in the heat exchanger tube, and the water which contacts the surface of a heat exchanger tube. The gas turbine intake cooler cools the air by heat-exchanging air with water (cooling water) flowing out of the LNG vaporizer. As the gas turbine intake cooling water circulation system, an LNG vaporizer and a gas turbine intake cooler are connected. Water circulates through the gas turbine intake cooling water circulation system, thereby flowing the LNG vaporizer and the gas turbine intake cooler in this order. The gas turbine intake cooling water circulation pump is provided in the downstream side part of a gas turbine intake cooling machine in a gas turbine intake cooling water circulation system. The gas turbine power generation apparatus is connected to a gas turbine compressor for compressing air flowing out of a cooler, a gas turbine driven by a mixed gas of air discharged from the gas turbine compressor and combustion gas of natural gas (NG), and a gas turbine. Has a generator. In this facility, the air supplied to the gas turbine compressor of a gas turbine power generation apparatus is cooled by the cold heat which water collect | recovered from LNG in an LNG vaporizer.

In the vaporizer | carburetor of the LNG composite thermal power plant described in patent document 1, icing may generate | occur | produce on the surface of the heat exchanger tube through which LNG flows.

Japanese Patent Laid-Open No. 06-213001

An object of the present invention is to provide a natural gas combined cycle power generation system and a natural gas combined cycle power generation method capable of suppressing the occurrence of icing in a vaporizer.

A natural gas combined cycle power generation system according to one aspect of the present invention is a vaporizer that vaporizes at least a portion of the liquefied natural gas by heating liquefied natural gas with water, and cools the air by heat-exchanging water and air discharged from the vaporizer. Driven by a gas including a cooler to be connected to the vaporizer and the cooler so that water flows through the vaporizer and the cooler in this order, a pump provided in the circulation flow path, and air discharged from the cooler. A gas turbine hybrid power generation apparatus having a gas turbine and a gas turbine generator connected to the gas turbine, wherein the vaporizer is heat exchanged between the intermediate medium having a freezing point lower than the freezing point of water and the water discharged from the cooler. Medium medium build up to evaporate at least a portion of the medium It has unit, and a portion of liquefied natural gas vaporization of vaporizing at least a portion of the liquefied natural gas by heat exchange of the intermediate medium and the liquefied natural gas.

In addition, the natural gas combined cycle power generation method according to one aspect of the present invention, the gas turbine and the gas turbine generator connected to the gas turbine and the gas turbine, the cold heat recovered from the liquefied natural gas in the vaporizer for vaporizing liquefied natural gas A natural gas combined cycle power generation method used for cooling air supplied to a gas turbine hybrid power generator having a vaporization step of vaporizing at least a portion of the liquefied natural gas by heating the liquefied natural gas with water, and water in the vaporization step. And a cooling step of cooling the air supplied to the gas turbine combined cycle power unit by the cold heat recovered from the liquefied natural gas. In the vaporization step, water is cooled by cooling the air in the cooling step in the vaporizer. The heat recovered from air is lower than the freezing point of water. By heating the liquified natural gas as that for evaporating at least a portion of that intermediate medium by supplying to the intermediate medium, the intermediate medium is conducted to vaporize at least a portion of that liquefied natural gas.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline of the structure of the natural gas combined cycle thermal power generation system of 1st Embodiment of this invention.
It is an enlarged view of the periphery of the vaporizer | carburetor and a warmer of 1st Embodiment.
It is a figure which shows the modified example of the natural gas combined cycle power generation system shown in FIG.
It is a figure which shows the outline of the structure of the natural gas combined-cycle power generation system of 2nd Embodiment of this invention.
5 is an enlarged view of the periphery of the vaporizer and the warmer of the second embodiment.

Preferred embodiment of this invention is described below, referring drawings.

(1st embodiment)

The natural gas combined cycle power generation system 1 according to the first embodiment of the present invention will be described with reference to FIGS. 1 and 2. The natural gas combined cycle power generation system 1 supplies the cold heat recovered from liquefied natural gas through water in the vaporizer 10 for vaporizing liquefied natural gas (LNG) to the gas turbine combined cycle power generation device 50. It is a power generation system which generate | occur | produces with the gas turbine composite power generation apparatus 50, using for cooling of the said air. Specifically, the natural gas combined cycle power generation system 1 includes a vaporizer 10, a cooler 20, a circulation passage 30, a pump 40, and a gas turbine combined cycle apparatus 50. have. The circulation flow path 30 connects the vaporizer | carburetor 10 and the cooler 20 in this order.

The vaporizer | carburetor 10 is an intermediate | middle medium type | mold vaporizer (IFV) which vaporizes liquefied natural gas by heat-exchanging water and liquefied natural gas through the intermediate | middle medium (propane etc.) which has a freezing point lower than the freezing point of water. That is, in this vaporizer | carburetor 10, an intermediate medium is heated by water instead of brine etc., and liquefied natural gas is heated by this intermediate medium. The detail of this vaporizer | carburetor 10 is mentioned later.

The cooler 20 cools the air by heat-exchanging water and air flowing out of the vaporizer 10.

The pump 40 is provided in the downstream side part of the vaporizer | carburetor 10 in the circulation flow path 30. As shown in FIG. The pump 40 sends the water (cooling water) which flowed out from the vaporizer | carburetor 10 to the cooler 20. FIG. In this embodiment, the pump 41 is provided also in the downstream side part of the cooler 20 among the circulation flow paths 30. This pump 41 sends the water (hot water) which flowed out from the cooler 20 to the vaporizer | carburetor 10. As shown in FIG. In addition, a cold heat storage tank 42 having a function of storing cold heat may be provided at a portion between the vaporizer 10 and the pump 40 in the circulation flow path 30. Similarly, a heat storage tank 43 having a function of storing heat may be provided at a portion between the cooler 20 and the pump 41 in the circulation flow path 30. In addition, a back-up warmer 44 that heats water by a heat source (sea water or the like) may be provided at a portion between the cooler 20 and the thermal storage tank 43 in the circulation flow path 30.

The gas turbine combined cycle generator 50 includes an air compressor 51, a gas turbine 52, a heat recovery boiler 53, a steam turbine 54, and a gas turbine generator 55. The air compressor 51 compresses the air flowing out of the cooler 20. The gas turbine 52 is driven by the mixed gas of the compressed air discharged from the air compressor 51 and the combustion gas produced by the combustion of the natural gas NG. The heat recovery boiler 53 evaporates water by heat-exchanging the exhaust gas discharged from the gas turbine 52 and water. The steam turbine 54 is driven by the steam which flowed out from the heat recovery boiler 53. The gas turbine generator 55 is connected to the gas turbine 52 and the steam turbine 54, and generates electric power by these rotations.

The natural gas combined cycle thermal power generation system 1 may further have a heater 60 provided in a portion between the cooler 20 and the vaporizer 10 in the circulation flow path 30.

Here, the vaporizer | carburetor 10 and the warmer 60 are demonstrated, referring FIG.

The vaporizer | carburetor 10 has the intermediate | middle medium evaporation part E1, the liquefied natural gas vaporization part E2, the intermediate medium evaporation part E1, the liquefied natural gas vaporization part E2, and the intermediate medium M. The shell 11 is accommodated.

The intermediate medium evaporator E1 evaporates at least a part of the intermediate medium M by heat-exchanging the liquid medium medium M and the water (hot water) flowing out of the cooler 20. In this embodiment, the intermediate | middle medium evaporator E1 is comprised by the heat exchanger tube. The intermediate medium evaporation unit E1 is disposed in the lower portion of the shell 11 (the position of the intermediate medium evaporated in the liquid medium medium M in the shell 11). That is, the intermediate medium M in contact with the intermediate medium evaporator E1 is heated by the water flowing in the intermediate medium evaporator E1.

The liquefied natural gas vaporization unit E2 vaporizes at least a portion of the liquefied natural gas by heat-exchanging the liquefied natural gas and the gaseous intermediate medium M. In this embodiment, the liquefied natural gas vaporization part E2 is comprised by the heat exchanger tube formed in U shape. The liquefied natural gas vaporization part E2 is disposed in the upper part of the shell 11 (region above the surface of the liquid intermediate medium M in the shell 11). That is, the liquefied natural gas flowing in the liquefied natural gas vaporization part E2 is heated by the gaseous intermediate medium M in contact with the surface of the liquefied natural gas vaporization part E2.

The inlet chamber 12 and the outlet chamber 13 partitioned by the partition board 14 are connected to the shell 11. The inlet chamber 12 is connected to one end of the liquefied natural gas vaporization part E2 so that the inside of the inlet chamber 12 and the liquefied natural gas vaporization part E2 communicate with each other. The outlet chamber 13 is connected to the other end of the liquefied natural gas vaporization part E2 such that the inside of the outlet chamber 13 and the liquefied natural gas vaporization part E2 communicate with each other. That is, the liquefied natural gas flowing into the liquefied natural gas vaporization unit E2 from the inlet chamber 12 is heated to the intermediate medium M in the gaseous phase in the course of passing through the liquefied natural gas vaporization unit E2, so that at least a part thereof is vaporized. Flows into (13).

In addition, the water inlet chamber 15 and the water outlet chamber 16 are connected to the shell 11. The water inlet chamber 15 is connected to one side of the shell 11 so that the inside of the water inlet chamber 15 and the intermediate medium evaporator E1 communicate with each other. The water outlet chamber 16 is connected to the other side of the shell 11 so that the inside of the water outlet chamber 16 and the intermediate medium evaporator E1 communicate with each other. That is, the water introduced into the intermediate medium evaporator E1 from the water inlet chamber 15 recovers cold heat from the liquid medium M in the course of passing through the intermediate medium evaporator E1, and passes through the water outlet chamber 16. It flows out to the circulation flow path 30.

The warmer 60 is provided in the upstream side of the vaporizer | carburetor 10 among the circulation flow paths 30. The warmer 60 warms the natural gas which flowed out from the vaporizer | carburetor 10. As shown in FIG. The warmer 60 has a heating portion E3 and a casing 61 for accommodating the heating portion E3.

The heating part E3 heats the natural gas by heat-exchanging the natural gas which flowed out from the liquefied natural gas vaporization part E2 and the water which flowed out from the cooler 20. In this embodiment, the heating part E3 is comprised by the heat exchanger tube formed in U shape.

The inlet chamber 62 and the outlet chamber 63 partitioned with the partition plate 64 from each other are connected to the casing 61 via the flange 65. In addition, the structure of the entrance chamber 62 and the exit chamber 63 is the same as that of the entrance chamber 12 and the exit chamber 13 connected to the shell 11. The natural gas flowing out of the outlet chamber 13 of the vaporizer 10 is introduced into the inlet chamber 62 and then heated by the water in the casing 61 in the course of passing through the heating section E3, thereby leaving the outlet chamber 63. Flows into). The flange 65 is detachably connected to the casing 61. That is, the heating part E3, the inlet chamber 62, the outlet chamber 63, and the partition plate 64 can be separated from the casing 61.

As shown in FIG. 1, the natural gas combined cycle thermal power generation system 1 has a calorific value adjusting passage 31. The calorie adjustment flow path 31 is connected to the circulation flow path 30 and bypasses the heater 60. For this reason, the water which flowed out from the cooler 20 and passed through the warmer 60, and the water which passed through the calorie adjustment flow path 31 flow into the intermediate medium evaporator E1.

As described above, in the natural gas combined cycle power generation system 1 of the present embodiment, since heat exchange between water and liquefied natural gas is performed through an intermediate medium (such as propane) having a freezing point lower than the freezing point of water, water and liquefaction are performed. The occurrence of icing in the intermediate medium evaporator E1 is suppressed as compared with the case where the natural gas performs direct heat exchange. In addition, in order to prevent icing troubles, it is not necessary to use expensive brine water (ethylene glycol water or the like) as the cooling heat medium.

Moreover, the heater 60 which heats natural gas by the water which flowed out from the cooler 20 is provided in the upstream of the vaporizer | carburetor 10. As shown in FIG. For this reason, natural gas is heated with a simple structure compared with the case where the natural gas which flowed out from the liquefied natural gas vaporization part E2 is heated with a heating medium different from the water which flowed out from the cooler 20. FIG.

In the warmer 60, it is possible to separate the heating portion E3, the inlet chamber 62, the outlet chamber 63, and the partition plate 64 from the casing 61. For this reason, the cleaning (washing) in the heating part E3 and the casing 61 becomes easy.

As shown in FIG. 3, the natural gas combined cycle power generation system 1 may further include a cooler bypass flow path 32 and a cold heat recovery unit 45. The cooler bypass flow path 32 is connected to the circulation flow path 30, and bypasses the cooler 20. The cold heat recovery part 45 recovers cold heat of the water which flowed out from the vaporizer | carburetor 10. FIG. As the cold heat recovery part 45, the cooling apparatus which cools indoors and a cable pit is mentioned. In this aspect, the surplus of cold heat required for cooling the air in the cooler 20 is effectively recovered by the cold heat recovery unit 45.

(2nd embodiment)

Next, the natural gas combined cycle power generation system 1 according to the second embodiment of the present invention will be described with reference to FIGS. 4 and 5. In addition, in 2nd Embodiment, only a part different from 1st Embodiment is demonstrated, and description of the structure, operation | movement, and effect similar to 1st Embodiment is abbreviate | omitted.

The natural gas combined cycle power generation system 1 of the present embodiment further includes a direct expansion turbine 80, an expansion turbine generator 90, a heating part bypass flow path 33, and an additional heating part E4. have.

The direct expansion turbine 80 is driven by the natural gas which flowed out from the heating part E3. The expansion turbine generator 90 is directly connected to the expansion turbine 80.

The warming part bypass flow path 33 is connected to the circulation flow path 30 and bypasses the warming part E3.

The additional heating part E4 is provided in the heating part bypass flow path 33. The additional heating section E4 heats the natural gas by heat-exchanging the water flowing through the heating section bypass flow path 33 and the natural gas flowing out from the expansion turbine 80 directly. The further heating part E4 is comprised by the heat exchanger tube formed in U shape. In this embodiment, the additional heating part E4 is accommodated in the casing 61. In other words, the casing 61 of this embodiment has the shape which can accommodate and accommodate the heating part E3 and the additional heating part E4. The inlet chamber 72 and the outlet chamber 73 partitioned by the partition plate 74 from each other through the flange 75 are further connected to this casing 61. The inlet chamber 72 and the outlet chamber 73 communicate with the interior of the additional heating section E4. The natural gas flowing out of the direct expansion turbine 80 flows into the casing 61 through the warmer bypass flow path 33 in the course of passing through the additional warmer E4 after flowing into the inlet chamber 72. Heated by the liquid, and flows into the outlet chamber 73. This additional heating part E4 can also be separated from the casing 61 together with the inlet chamber 72, the outlet chamber 73, and the partition plate 74. For this reason, the cleaning (washing) of the additional heating part E4 also becomes easy.

In addition, in this embodiment, since the energy which natural gas which flowed out from the heating part E3 has is recovered as electric power in the expansion turbine generator 90, the amount of power generation as a whole system increases.

In addition, the temperature of the natural gas lowered by passing through the expansion turbine 80 directly by the water flowing out of the cooler 20 is not a dedicated heating medium for heating the natural gas flowing out of the direct expansion turbine 80. You can. Specifically, although the temperature of the natural gas is lowered by passing the natural gas directly through the expansion turbine 80, a portion of the heat quantity of the water flowing out from the cooler 20 is not introduced into the heating portion E3, but instead of the heating portion bypass flow path ( Since it is put into the additional heating part E4 via 33), the natural gas which flowed out from the expansion turbine 80 directly is heated up effectively. In addition, since the water has a sufficient amount of heat even after the natural gas is heated in the additional heating part E4, the intermediate medium M is effectively warmed in the intermediate medium evaporator E1 by the water.

In addition, embodiment disclosed this time is an illustration in all the points, Comprising: It should be thought that it is not restrictive. The scope of the present invention is shown not by the description of the above embodiments but by the claims, and includes the meanings of the claims and equivalents and all modifications within the scope.

For example, the heating part E3 and the additional heating part E4 may be accommodated in different casings, respectively. Also in this case, it is preferable that the water which flowed out from the additional heating part E4 is supplied to the intermediate medium evaporation part E1.

Here, the above embodiment will be described schematically.

The natural gas combined cycle power generation system according to the embodiment includes a vaporizer for vaporizing at least a portion of the liquefied natural gas by heating liquefied natural gas with water, a cooler for cooling the air by heat-exchanging water and air discharged from the vaporizer; And a gas turbine driven by a gas including a circulation passage connecting the vaporizer and the cooler so that water flows in the order, the vaporizer and the cooler, a pump provided in the circulation passage, and air flowing out of the cooler. And a gas turbine combined cycle power generation apparatus having a gas turbine generator connected to the gas turbine, wherein the vaporizer heat exchanges the intermediate medium having a freezing point lower than the freezing point of water and the water discharged from the cooler. An intermediate medium evaporator for evaporating a portion, and By heat exchange with the intermediate medium, the liquefied natural gas, liquefied natural gas gasification unit have to vaporize at least a portion of the liquefied natural gas.

In the natural gas combined cycle power generation system, heat exchange between water and liquefied natural gas is performed through an intermediate medium (propane or the like) having a freezing point lower than that of water, so that icing in the intermediate medium evaporation unit is suppressed.

In the natural gas combined cycle power generation system, the gas is provided at a portion between the cooler and the vaporizer in the circulation passage, and the natural gas discharged from the liquefied natural gas vaporizer is exchanged with the water discharged from the cooler. It is preferable to further provide the heating part which heats natural gas.

In this way, the structure is simplified compared with the case where the natural gas flowing out from the liquefied natural gas vaporization unit is heated with a heating medium different from the water flowing out from the cooler.

Moreover, in the said natural gas combined cycle power generation system, it is preferable to further provide the direct expansion turbine driven by the natural gas which flowed out from the said heating part, and the expansion turbine generator connected to the said direct expansion turbine.

In this case, since the energy of the natural gas flowing out from the heating unit is recovered as electric power in the expansion turbine generator, the amount of power generation as a whole of the system increases.

Furthermore, in the natural gas combined cycle power generation system, the natural gas flowing out from the direct flow turbine and the water flowing through the warmer bypass flow passage connected to the circulation flow passage and bypassing the warming portion, the warming portion bypass flow passage. It is preferable to further provide an additional heating section for heating the natural gas by heat-exchanging the gas.

In this way, the temperature of the degraded natural gas can be increased by passing directly through the expansion turbine by water flowing out of the cooler, rather than a dedicated heating medium for heating the natural gas flowing out of the direct expansion turbine. Specifically, although the temperature of the natural gas is lowered by passing the natural gas directly through the expansion turbine, part of the heat quantity of the water flowing out from the cooler is added to the warming unit through the warming unit bypass flow passage instead of being input to the warming unit. The natural gas, which flows out from the direct expansion turbine, is effectively heated up. In addition, even after the natural gas is heated in the additional heating portion, the water has a sufficient amount of heat, and the water effectively warms up the intermediate medium in the intermediate medium evaporation portion.

Further, in the natural gas combined cycle power generation system, it is preferable to further include a casing that houses the heating unit and the additional heating unit integrally.

In this way, compared with the case where a heating part and an additional heating part are accommodated in a different casing, respectively, the structure of a heating part and an additional heating part is simplified and further miniaturized.

Moreover, it is preferable that the said heating part is comprised so that attachment or detachment is possible with respect to the said casing.

In this way, cleaning (washing) in a heating part and a casing becomes easy.

Moreover, in the said natural gas combined cycle power generation system, it is preferable that the said additional heating part is comprised so that attachment or detachment is possible with respect to the said casing.

This facilitates cleaning (washing) in the additional heating portion and the casing.

The natural gas combined cycle power generation system preferably further includes a cooler bypass flow path connected to the circulation flow path and bypassing the cooler, and a cold heat recovery unit provided in the cooler bypass flow path.

In this way, the surplus of cold heat required for cooling the air in the cooler is effectively recovered in the cold heat recovery unit.

Moreover, the natural gas combined cycle thermal power generation method of the said embodiment has the gas turbine which has the cold heat collect | recovered from the said liquefied natural gas in the vaporizer for vaporizing liquefied natural gas, and has a gas turbine and the gas turbine generator connected to the said gas turbine. A natural gas combined cycle power generation method used for cooling air supplied to a complex power generation apparatus, comprising: a vaporization step of vaporizing at least a portion of the liquefied natural gas by heating the liquefied natural gas with water, and water in the vaporization step And a cooling step of cooling the air supplied to the gas turbine combined cycle power unit by the cold heat recovered from the gas. In the vaporization step, water is recovered from the air by cooling the air in the cooling step in the vaporizer. Middle of a row with a freezing point lower than the freezing point of water Evaporating at least a part of the liquefied natural gas by heating the liquefied natural gas with the intermediate medium by supplying the medium to the medium.

In the vaporization process of the present natural gas combined cycle power generation method, since the liquefied natural gas is vaporized through an intermediate medium (propane, etc.) having a freezing point lower than the freezing point of water in the vaporizer, the occurrence of icing in the vaporizer is suppressed. .

Claims (10)

Natural gas combined cycle power generation system,
A vaporizer for vaporizing at least a portion of the liquefied natural gas by heating the liquefied natural gas with water,
A cooler for cooling the air by heat-exchanging air with water flowing out of the vaporizer;
A circulation passage connecting the vaporizer and the cooler so that water flows in the order of the vaporizer and the cooler;
A pump provided in the circulation passage;
A gas turbine hybrid power generation apparatus having a gas turbine driven by a gas containing air discharged from the cooler and a gas turbine generator connected to the gas turbine,
The carburetor,
An intermediate medium having a freezing point lower than the freezing point of water, an intermediate medium evaporator for evaporating at least a portion of the intermediate medium by heat-exchanging water flowing out of the cooler,
Liquefied natural gas vaporization unit for vaporizing at least a portion of the liquefied natural gas by heat-exchanging the intermediate medium and the liquefied natural gas
Having a natural gas combined cycle power generation system. The warming according to claim 1, wherein the heating gas is provided at a portion between the cooler and the vaporizer in the circulation flow path, and warms the natural gas by heat-exchanging the natural gas discharged from the liquefied natural gas vaporizer and the water discharged from the cooler. A natural gas combined cycle power generation system, further comprising a unit. According to claim 2, Direct expansion turbine driven by natural gas flowing out of the heating portion,
A natural gas combined cycle power generation system, further comprising an expansion turbine generator connected to said direct expansion turbine. The heating part bypass flow path of claim 3, further comprising: a heating part bypass flow path connected to the circulation flow path and bypassing the heating part;
And a further heating section for warming the natural gas by heat-exchanging water flowing through the warming section bypass flow passage and the natural gas flowing out of the direct expansion turbine. The natural gas combined cycle power generation system according to claim 4, further comprising a casing which integrally houses the warming portion and the additional warming portion. The natural gas combined cycle thermal power generation system according to claim 5, wherein the heating portion is configured to be detachable from the casing. The natural gas combined cycle power generation system according to claim 5, wherein the additional heating portion is configured to be detachable from the casing. The cooler bypass flow path of claim 1, further comprising: a cooler bypass flow path connected to the circulation flow path and bypassing the cooler;
A natural gas combined cycle thermal power generation system further comprising a cold heat recovery unit provided in the cooler bypass flow path. A vaporizer used for the natural gas combined cycle power generation system according to claim 1. In the vaporizer for vaporizing liquefied natural gas, the natural gas composite which uses the cooling heat recovered from the liquefied natural gas for the cooling of the air supplied to the gas turbine hybrid power generation apparatus having a gas turbine and a gas turbine generator connected to the gas turbine. Thermal power generation method,
A vaporization step of vaporizing at least a portion of the liquefied natural gas by heating the liquefied natural gas with water,
And a cooling step of cooling the air supplied to the gas turbine combined cycle power generator by cold heat recovered from the liquefied natural gas by the water in the vaporization step
In the vaporization step, at least part of the intermediate medium is evaporated by supplying heat recovered from the air to the intermediate medium having a freezing point lower than the water freezing point by cooling the air in the cooling step. The natural gas combined cycle power generation method which vaporizes at least one part of the said liquefied natural gas by heating the said liquefied natural gas with an intermediate medium.

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