WO2023162589A1 - Installation de turbine à gaz et méthode d'utilisation d'ammoniac à l'intérieur de celle-ci - Google Patents

Installation de turbine à gaz et méthode d'utilisation d'ammoniac à l'intérieur de celle-ci Download PDF

Info

Publication number
WO2023162589A1
WO2023162589A1 PCT/JP2023/002983 JP2023002983W WO2023162589A1 WO 2023162589 A1 WO2023162589 A1 WO 2023162589A1 JP 2023002983 W JP2023002983 W JP 2023002983W WO 2023162589 A1 WO2023162589 A1 WO 2023162589A1
Authority
WO
WIPO (PCT)
Prior art keywords
ammonia
hydrogen
gas
heated
steam
Prior art date
Application number
PCT/JP2023/002983
Other languages
English (en)
Japanese (ja)
Inventor
文彦 木曽
秀文 荒木
明典 林
Original Assignee
三菱パワー株式会社
三菱重工業株式会社
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 三菱パワー株式会社, 三菱重工業株式会社 filed Critical 三菱パワー株式会社
Publication of WO2023162589A1 publication Critical patent/WO2023162589A1/fr

Links

Images

Classifications

    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B3/00Hydrogen; Gaseous mixtures containing hydrogen; Separation of hydrogen from mixtures containing it; Purification of hydrogen
    • C01B3/02Production of hydrogen or of gaseous mixtures containing a substantial proportion of hydrogen
    • C01B3/04Production of hydrogen or of gaseous mixtures containing a substantial proportion of hydrogen by decomposition of inorganic compounds, e.g. ammonia
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02CGAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
    • F02C3/00Gas-turbine plants characterised by the use of combustion products as the working fluid
    • F02C3/20Gas-turbine plants characterised by the use of combustion products as the working fluid using a special fuel, oxidant, or dilution fluid to generate the combustion products
    • F02C3/22Gas-turbine plants characterised by the use of combustion products as the working fluid using a special fuel, oxidant, or dilution fluid to generate the combustion products the fuel or oxidant being gaseous at standard temperature and pressure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02CGAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
    • F02C6/00Plural gas-turbine plants; Combinations of gas-turbine plants with other apparatus; Adaptations of gas-turbine plants for special use
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02CGAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
    • F02C6/00Plural gas-turbine plants; Combinations of gas-turbine plants with other apparatus; Adaptations of gas-turbine plants for special use
    • F02C6/18Plural gas-turbine plants; Combinations of gas-turbine plants with other apparatus; Adaptations of gas-turbine plants for special use using the waste heat of gas-turbine plants outside the plants themselves, e.g. gas-turbine power heat plants
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F02COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
    • F02CGAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
    • F02C7/00Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
    • F02C7/22Fuel supply systems
    • F02C7/224Heating fuel before feeding to the burner

Definitions

  • the present invention relates to a gas turbine plant equipped with a gas turbine and a heat recovery steam generator, and a method for utilizing ammonia therefor.
  • Patent Document 1 discloses a gas turbine plant that uses this ammonia as fuel.
  • This gas turbine plant includes a gas turbine and an ammonia tank.
  • a gas turbine has an air compressor, a combustor, and a turbine.
  • a portion of the ammonia from the ammonia tank is supplied upstream in the combustor as fuel.
  • another portion of the ammonia from the ammonia tank is cracked into hydrogen-rich gas. This hydrogen-rich gas is supplied downstream in the combustor as fuel.
  • an object of the present invention is to provide a gas turbine plant that can increase the utility value of ammonia while suppressing equipment costs and running costs, and an ammonia utilization method thereof.
  • a gas turbine plant as one aspect according to the invention for achieving the above object An ammonia tank capable of storing liquid ammonia, a gas turbine capable of being driven using ammonia as fuel, an exhaust heat recovery boiler capable of generating steam using the heat of exhaust gas from the gas turbine, and the exhaust heat recovery boiler.
  • an ammonia vaporizer capable of exchanging heat between the steam or hot water from the ammonia tank and the liquid ammonia from the ammonia tank to vaporize the liquid ammonia to generate gaseous ammonia; and the steam or hot water from the heat recovery boiler.
  • an ammonia heater capable of heating the gaseous ammonia, and part of the heated ammonia, which is gaseous ammonia heated by the ammonia heater, as fuel.
  • a heated ammonia main line that can be led to a gas turbine, a heated ammonia branch line branched from the heated ammonia main line, steam from the heat recovery boiler, and the heated ammonia from the heated ammonia branch line to thermally decompose the heated ammonia to generate a cracked gas containing hydrogen, a hydrogen purification facility capable of purifying hydrogen from at least part of the cracked gas, and the hydrogen purification and a hydrogen line capable of leading high-purity hydrogen, which is hydrogen refined in the facility, to a hydrogen tank.
  • a method for utilizing ammonia as one aspect of the invention for achieving the above object includes: A method for utilizing ammonia in a gas turbine plant comprising a gas turbine and an exhaust heat recovery boiler capable of generating steam using heat of exhaust gas from the gas turbine.
  • an ammonia vaporization step of exchanging heat between steam or hot water from the heat recovery boiler and liquid ammonia to vaporize the liquid ammonia to generate gaseous ammonia;
  • a main fuel supply process for introducing a part of the fuel to the gas turbine, and heat exchange between the steam from the heat recovery steam generator and another part of the heated ammonia to thermally decompose the heated ammonia to produce hydrogen and a hydrogen refining step of refining hydrogen from at least a portion of the cracked gas.
  • FIG. 1 is a system diagram of a gas turbine plant in one embodiment according to the present invention
  • FIG. 1 is a conceptual diagram showing the configuration of a combustor in one embodiment according to the present invention
  • FIG. 1 is a system diagram of an ammonia decomposition facility in one embodiment according to the present invention
  • FIG. 1 is a system diagram of a hydrogen refining facility in one embodiment according to the present invention
  • FIG. It is a flowchart which shows the procedure of the ammonia utilization method in one Embodiment which concerns on this invention.
  • FIG. 1 A first embodiment of a gas turbine plant will be described with reference to FIGS. 1 to 5.
  • FIG. 1 A first embodiment of a gas turbine plant will be described with reference to FIGS. 1 to 5.
  • the gas turbine plant of the present embodiment includes a gas turbine 10, a heat recovery boiler 20, a denitration device 29, a steam turbine facility 30, a generator 39, an ammonia tank 50, an ammonia A vaporizer 51 , an ammonia heater 52 , an ammonia decomposer 53 , an ammonia recovery facility 60 , an ammonia compressor 95 c , a hydrogen refining facility 70 , an offgas compressor 97 c and a hydrogen tank 79 are provided.
  • the gas turbine 10 includes an air compressor 11 capable of compressing air to generate compressed air CA, a combustor 12 capable of combusting fuel in the compressed air CA to generate combustion gas, and combustion from the combustor 12. a gas-operable turbine 13 .
  • the air compressor 11 has a compressor rotor 11r and a compressor casing 11c covering the compressor rotor 11r.
  • the turbine 13 has a turbine rotor 13r and a turbine casing 13c covering the turbine rotor 13r.
  • Compressor rotor 11r and turbine rotor 13r are connected to each other to form gas turbine rotor 14 .
  • the combustor 12 has a cylindrical combustion tube (or transition piece) 12p around the cylinder axis Ac, and a plurality of burners 12b capable of injecting fuel into the combustion tube 12p. All of the plurality of burners 12b extend in the direction in which the cylinder axis Ac extends.
  • the plurality of burners 12b includes a center burner 12bc and a plurality of peripheral burners 12bp arranged around the center burner 12bc.
  • the central burner 12bc is arranged on or near the cylinder axis Ac.
  • the combustor 12 is configured such that compressed air CA is supplied from the air compressor 11 to a plurality of burners 12b.
  • the exhaust heat recovery boiler 20 includes a boiler frame 21 through which the exhaust gas from the gas turbine 10 flows, a low-pressure steam generation system 22, an intermediate-pressure steam generation system 23, a high-pressure steam generation system 25, It has a medium pressure pump 24 and a high pressure pump 26 .
  • the upstream side of the exhaust gas flow in the boiler frame 21 is defined as the boiler upstream side, and the opposite side thereof is defined as the boiler downstream side.
  • a stack 28 for exhausting the exhaust gas to the atmosphere is connected to the end of the boiler frame 21 on the most downstream side of the boiler.
  • the low-pressure steam generation system 22 has an economizer 22a, an evaporator 22b, and a superheater 22c.
  • the economizer 22a heat-exchanges the water and the exhaust gas to heat the water into hot water.
  • the evaporator 22b heat-exchanges part of the hot water from the economizer 22a with the exhaust gas to heat the water into steam.
  • the superheater 22c heats the steam by exchanging heat between the steam from the evaporator 22b and the exhaust gas.
  • the economizer 22 a , at least part of the evaporator 22 b , and the superheater 22 c are all arranged inside the boiler frame 21 .
  • the economizer 22a, at least part of the evaporator 22b, and the superheater 22c are arranged in this order from the boiler downstream side to the boiler upstream side.
  • the medium pressure steam generation system 23 and the high pressure steam generation system 25 each have an economizer, an evaporator, and a superheater like the low pressure steam generation system 22.
  • the medium-pressure pump 24 pressurizes part of the hot water from the economizer 22 a of the low-pressure steam generation system 22 and then sends it to the economizer of the medium-pressure steam generation system 23 .
  • the high-pressure pump 26 pressurizes another part of the hot water from the economizer 22 a of the low-pressure steam generation system 22 and then sends it to the economizer of the high-pressure steam generation system 25 .
  • the superheater of the high-pressure steam generation system 25 is arranged in the boiler frame 21 on the boiler upstream side of the other superheaters.
  • the superheater of the intermediate-pressure steam generation system 23 is arranged in the boiler frame 21 downstream of the superheater of the high-pressure steam generation system 25 and upstream of the boiler from the superheater 22c of the low-pressure steam generation system 22.
  • the denitrification device 29 is arranged, for example, between the high-pressure steam generation system 25 and the medium-pressure steam generation system 23 within the boiler frame 21 .
  • the denitrification device 29 uses aqueous ammonia to decompose NOx contained in the exhaust gas from the gas turbine 10 into nitrogen and water vapor through the action of a catalyst.
  • the steam turbine facility 30 has a low-pressure steam turbine 31, an intermediate-pressure steam turbine 32, a high-pressure steam turbine 33, a condenser 35, a water supply line 36, and a water supply pump 37.
  • the low-pressure steam turbine 31 has a low-pressure steam turbine rotor 31r and a casing 31c covering the low-pressure steam turbine rotor 31r.
  • the intermediate pressure steam turbine 32 has an intermediate pressure steam turbine rotor 32r and a casing 32c covering the intermediate pressure steam turbine rotor 32r.
  • the high pressure steam turbine 33 has a high pressure steam turbine rotor 33r and a casing 33c covering the high pressure steam turbine rotor 33r.
  • the low-pressure steam turbine rotor 31r, the intermediate-pressure steam turbine rotor 32r, and the high-pressure steam turbine rotor 33r are connected to each other to form one steam turbine rotor .
  • One end of the steam turbine rotor 34 is connected to the gas turbine rotor 14 described above.
  • a generator 39 is connected to the other end of the steam turbine rotor 34 .
  • the steam turbine rotor 34 and the gas turbine rotor 14 are connected to each other, and the generator 39 is connected to the end of this rotor.
  • the steam turbine rotor 34 and the gas turbine rotor 14 may not be connected to each other, and the generator may be connected to the end of the steam turbine rotor 34 and the generator to the end of the gas turbine rotor 14 as well. .
  • the superheater of the high-pressure steam generation system 25 and the steam inlet of the high-pressure steam turbine 33 are connected by a high-pressure steam line 43 .
  • a superheater of the intermediate pressure steam generation system 23 and a steam inlet of the intermediate pressure steam turbine 32 are connected by an intermediate pressure steam line 42 .
  • the steam inlet of the intermediate pressure steam turbine 32 is further connected with the steam outlet of the high pressure steam turbine 33 by a high pressure exhaust steam line 44 .
  • a superheater 22 c of the low-pressure steam generation system 22 and the steam inlet of the low-pressure steam turbine 31 are connected by a low-pressure steam line 41 .
  • the steam inlet of the low pressure steam turbine 31 is further connected with the steam outlet of the intermediate pressure steam turbine 32 with an intermediate pressure exhaust steam line 45 .
  • a steam outlet of the low-pressure steam turbine 31 is connected to the condenser 35 described above.
  • This condenser 35 converts the steam exhausted from the low-pressure steam turbine 31 back into water in the liquid phase.
  • the condenser 35 and the economizer of the low-pressure steam generation system 22 are connected by a water supply line 36 .
  • the water supply line 36 is provided with a water supply pump 37 .
  • the ammonia tank 50 is a tank capable of storing liquid ammonia NHL.
  • the ammonia vaporizer 51 is a heat exchanger capable of exchanging heat between vapor and liquid ammonia NHL to vaporize the liquid ammonia NHL and generate gaseous ammonia NHG.
  • the ammonia inlet of the ammonia vaporizer 51 and the ammonia outlet of the ammonia tank 50 are connected by a liquid ammonia line 80 .
  • This liquid ammonia line 80 is provided with an ammonia pump 81 .
  • a steam inlet of the ammonia vaporizer 51 and the low pressure steam line 41 are connected by a low pressure steam branch line 83 .
  • a vapor outlet of the ammonia vaporizer 51 is connected to the condenser 35 by, for example, a low-pressure vapor recovery line 84 .
  • the ammonia vaporizer 51 exchanges heat between the liquid ammonia NHL from the ammonia tank 50 and the low-pressure steam LS from the low-pressure steam generation system 22 .
  • the temperature of this low-pressure steam LS is, for example, 130-180.degree.
  • the liquid ammonia NHL from the ammonia tank 50 and the hot water heated by the economizer of the intermediate-pressure steam generation system 23 may be heat-exchanged.
  • the ammonia heater 52 is a heat exchanger capable of heat-exchanging steam and gaseous ammonia NHG to heat the gaseous ammonia NHG.
  • the ammonia inlet of the ammonia heater 52 and the ammonia outlet of the ammonia vaporizer 51 are connected by a gaseous ammonia line 82 .
  • a first intermediate-pressure steam branch line 85 connects the steam inlet of the ammonia heater 52 and the intermediate-pressure steam line 42 .
  • the steam outlet of this ammonia heater 52 is connected to the condenser 35 by, for example, a first intermediate pressure steam recovery line 86 .
  • the ammonia heater 52 exchanges heat between the gaseous ammonia NHG from the ammonia vaporizer 51 and the intermediate pressure steam IS from the intermediate pressure steam generation system 23 .
  • the temperature of this medium-pressure steam IS is, for example, 250-350.degree.
  • gaseous ammonia NHG from the ammonia vaporizer 51 and hot water from the economizer of the high-pressure steam generation system 25 or hot water and heat from the economizer of the medium-pressure steam generation system 23 are combined. You can exchange it.
  • the ammonia heater 52 may heat-exchange the gaseous ammonia NHG from the ammonia vaporizer 51 and the low-pressure steam LS from the low-pressure steam generation system 22 .
  • the ammonia outlet of the ammonia heater 52 and the plurality of peripheral burners 12 bp (see FIG. 2) of the combustor 12 are connected by a heated ammonia main line 87 . Therefore, the heated ammonia NHH, which is the heated gaseous ammonia NHG, is sent as fuel to the plurality of peripheral burners 12bp of the combustor 12 via the heated ammonia main line 87 by the ammonia heater 52 .
  • the heated ammonia main line 87 is provided with a main fuel valve 88 capable of adjusting the flow rate of the heated ammonia NHH sent to the combustor 12 .
  • the ammonia decomposer 53 is a heat exchanger capable of exchanging heat between steam and heated ammonia NHH, thermally decomposing the heated ammonia NHH, and generating cracked gas DG.
  • This cracked gas DG contains residual ammonia in addition to hydrogen and nitrogen obtained by thermal decomposition of ammonia.
  • the inside of the ammonia decomposer 53 is partitioned into a target gas space in which ammonia or cracked gas DG flows and a steam space in which steam flows, by a heat transfer wall formed of a heat transfer tube or the like.
  • the heat transfer wall is made of Ni steel, for example.
  • the target gas space is filled with a catalyst for accelerating thermal decomposition of ammonia.
  • This catalyst has a catalyst component that activates the decomposition reaction and a carrier that supports the catalyst component.
  • catalyst components include particles of noble metals such as Ru, and metal particles containing transition metals such as Ni, Co, and Fe.
  • carriers include metal oxides such as Al 2 O 3 , ZrO 2 , Pr 2 O 3 , La 2 O 3 and MgO. Note that the catalyst is not limited to the catalysts exemplified above as long as it activates the decomposition reaction of ammonia.
  • the ammonia inlet of the ammonia decomposer 53 and the heated ammonia main line 87 are connected by a heated ammonia branch line 89 . That is, the heated ammonia branch line 89 is a line branched from the heated ammonia main line 87 through which the heated ammonia NHH flows. This heated ammonia branch line 89 is provided with a branch valve 89v.
  • a steam inlet of the ammonia decomposer 53 and the high pressure steam line 43 are connected by a high pressure steam branch line 91 .
  • a steam outlet of the ammonia decomposer 53 is connected to the intermediate pressure steam generation system 23 or the condenser 35 via, for example, a high pressure steam recovery line 92 .
  • the ammonia decomposer 53 heat-exchanges the heated ammonia NHH from the ammonia heater 52 and the high-pressure steam HS from the high-pressure steam generation system 25 .
  • the temperature of this high-pressure steam HS is, for example, 450-550.degree.
  • One end of a cracked gas line 90 is connected to a cracked gas outlet of the ammonia decomposer 53 .
  • the ammonia recovery facility 60 is a facility for recovering ammonia from the cracked gas DG from the ammonia decomposer 53.
  • the ammonia recovery equipment 60 includes an absorption tower 61, a water line 62, an ammonia water line 63, an ammonia water heater 64, a separation tower 65, a water circulation line 66, and a reboiler 67. , a water condenser 68 and a water recovery line 69 .
  • a packing 61a is arranged in an intermediate region of the absorption tower 61 in the vertical direction.
  • the other end of the aforementioned cracked gas line 90 is connected to a portion of the absorption tower 61 below the intermediate region.
  • a water line 62 is connected in the absorber tower 61 above the intermediate region.
  • One end of a treated gas line 96 is connected to the top of the absorption tower 61 .
  • One end of an ammonia water line 63 is connected to the bottom of the absorption tower 61 .
  • the cracked gas DG from the ammonia decomposer 53 flows into the absorber 61 from below the intermediate region of the absorber 61 through the cracked gas line 90 . Furthermore, water from a water line 62 is sprayed into the absorption tower 61 from above the intermediate region of the absorption tower 61 . The cracked gas DG that has flowed into the absorption tower 61 rises inside the absorption tower 61 . On the other hand, the water sprayed inside the absorption tower 61 descends inside this absorption tower 61 . During the process of descending inside the absorption tower 61, the water comes into contact with the packing 61a. Water in contact with the filler 61a forms a water film covering the surface of the filler 61a.
  • the cracked gas DG comes into contact with the water film covering the surface of the packing 61a during the process of ascending inside the absorption tower 61 .
  • the residual ammonia contained in the cracked gas DG dissolves in the water.
  • Ammonia water which is water in which residual ammonia is dissolved, accumulates in the lower part of the absorption tower 61 and flows into the ammonia water line 63 .
  • the treated gas PG which is cracked gas DG from which residual ammonia has been removed, rises in the absorption tower 61 and flows into the treated gas line 96 .
  • a tray 65a is arranged in an intermediate region of the separation tower 65 in the vertical direction.
  • a plurality of stages forming the shelf stage 65a are arranged in the vertical direction.
  • Each of the plurality of steps forming the shelf step 65a is made of a plate in which a large number of holes are formed.
  • the other end of the ammonia water line 63 described above is connected to an intermediate stage among a plurality of stages forming the shelf stage 65a.
  • One end of the water circulation line 66 is connected to the bottom of the separation tower 65, and the other end of the water circulation line 66 is connected to the separation tower 65 above the bottom and below the intermediate region.
  • a reboiler 67 is provided in this water circulation line 66 .
  • This reboiler 67 is a heat exchanger for exchanging heat between water flowing through the water circulation line 66 and steam.
  • a second intermediate-pressure steam branch line 93 connects the steam inlet of the reboiler 67 and the intermediate-pressure steam line 42 .
  • a steam outlet of the reboiler 67 is connected to the condenser 35 by, for example, a second intermediate pressure steam recovery line 94 . Therefore, this reboiler 67 heats the water by heat exchange between the water and the medium-pressure steam IS to turn the water into steam. This steam flows through the water circulation line 66 into the separation tower 65 .
  • high-pressure steam HS from the superheater of the high-pressure steam generation system 25 hot water from the economizer of the high-pressure steam generation system 25, or hot water from the economizer of the intermediate-pressure steam generation system 23 You may heat-exchange hot water and water.
  • Ammonia which evaporates more easily than water, is heated by steam, which is water in the gas phase, and shifts from the liquid phase to the gas phase, and water shifts from the gas phase to the liquid phase.
  • Gas phase ammonia rises in the separation tower 65 .
  • liquid-phase water more precisely, water with a low ammonia concentration accumulates in the lower part of the separation tower 65 . A part of this water passes through the water circulation line 66 and the reboiler 67 and flows into the separation tower 65 again as steam.
  • the water circulation line 66 is connected to the other end of the water line 62 described above. Therefore, part of the water accumulated in the lower part of the separation tower 65 returns to the separation tower 65 again through the water circulation line 66, and the other part of the water accumulated in the lower part of the separation tower 65 returns to the water circulation line 66. and the water line 62 into the absorption tower 61 .
  • the ammonia water heater 64 is provided in the ammonia water line 63 .
  • the ammonia water heater 64 is a heat exchanger for exchanging heat between the ammonia water flowing through the ammonia water line 63 and the water flowing through the water line 62 .
  • the ammonia water heater 64 heats the ammonia water by heat exchange between the ammonia water and water.
  • the heated aqueous ammonia is sprayed into the separation tower 65 as described above.
  • the water cooled by heat exchange with ammonia water is sprayed into the absorption tower 61 through the water line 62 .
  • ammonia recovery line 95 One end of an ammonia recovery line 95 is connected to the top of the separation tower 65 .
  • the other end of the ammonia recovery line 95 is connected to the ammonia inlet of the ammonia heater 52 .
  • the ammonia recovery line 95 is provided with a moisture condenser 68 and an ammonia compressor 95c.
  • the moisture condenser 68 cools the gas containing ammonia in the vapor phase flowing through the ammonia recovery line 95 to condense some of the moisture and ammonia in this gas.
  • the water condensed in the moisture condenser 68 returns to the space above the tray 65a in the separation tower 65 via the water recovery line 69.
  • the ammonia-based gas that has passed through the moisture condenser 68 flows into the ammonia heater 52 via the ammonia recovery line 95 . Therefore, in the ammonia heater 52, the gaseous ammonia NHG from the ammonia vaporizer 51 and the ammonia-based gas from the ammonia recovery facility 60 are heated with steam.
  • the liquid ammonia NHL from the ammonia condenser may be returned to the ammonia tank 50 or the ammonia vaporizer 51.
  • a moisture condenser 68 is arranged outside the separation tower 65 .
  • a water condenser 68 may be placed in the headspace within the separation column 65 .
  • a reboiler 67 is arranged outside the separation tower 65 .
  • a reboiler 67 may be placed inside the separation column 65 .
  • a gas-liquid contact method in the absorption tower 61 a packing system is adopted.
  • the gas-liquid contact method in the separation tower 65 a tray type is adopted. However, since there are other gas-liquid contact methods, other methods may be adopted as the gas-liquid contact method in the absorption tower 61 and separation tower 65 .
  • the optimum method may be selected according to the plant specifications, site conditions, and the like.
  • ammonia recovery equipment 60 described above is a known equipment.
  • This ammonia recovery facility may have other configurations as long as it is a facility capable of recovering ammonia from the cracked gas DG.
  • the hydrogen refining equipment 70 of the present embodiment is equipment that adsorbs and separates ammonia from a gas containing ammonia and hydrogen to purify hydrogen by a pressure swing absorption method.
  • the hydrogen purification equipment 70 includes a first adsorption tower 71a, a second adsorption tower 71b, a first treated gas line 72a, a second treated gas line 72b, and a first treated gas valve 73a, second treated gas valve 73b, first offgas line 74a, second offgas line 74b, first offgas valve 75a, second offgas valve 75b, vacuum pump 76, first hydrogen line 77a, a second hydrogen line 77b, a first hydrogen valve 78a, a second hydrogen valve 78b, and a hydrogen compressor 77c.
  • the hydrogen purification equipment 70 of this embodiment includes two adsorption towers 71a and 71b, but may have three or more adsorption towers.
  • an ammonia adsorbent Ab capable of adsorbing ammonia under high pressure and releasing ammonia under low pressure is arranged.
  • One end of the first treated gas line 72a and one end of the second treated gas line 72b are connected to the other end of the treated gas line 96 described above.
  • the other end of the first treated gas line 72a is connected to the treated gas inlet of the first adsorption tower 71a.
  • the other end of the second treated gas line 72b is connected to the treated gas inlet of the second adsorption tower 71b.
  • the treated gas PG from the ammonia recovery facility 60 that is, the cracked gas DG from which ammonia is recovered by the ammonia recovery facility 60 can flow into the first adsorption tower 71a and the second adsorption tower 71b.
  • the first treated gas line 72a is provided with a first treated gas valve 73a
  • the second treated gas line 72b is provided with a second treated gas valve 73b.
  • first off-gas line 74a One end of a first off-gas line 74a is connected to a position closer to the first adsorption tower 71a than the first treated gas valve 73a in the first treated gas line 72a.
  • a first offgas valve 75a is provided on the first offgas line 74a.
  • One end of the second off-gas line 74b is connected to a position closer to the second adsorption tower 71b than the second treated gas valve 73b in the second treated gas line 72b.
  • a second offgas valve 75b is provided on the second offgas line 74b.
  • One end of the offgas line 97 is connected to the other end of the first offgas line 74a and the other end of the second offgas line 74b.
  • the other end of the offgas line 97 is connected to the central burner 12bc (see FIG. 2) of the combustor 12. As shown in FIG.
  • the offgas line 97 is provided with a vacuum pump 76, an offgas compressor 97c and an auxiliary fuel valve 98. As shown in FIG.
  • One end of the first hydrogen line 77a is connected to the outlet of the first adsorption tower 71a.
  • a first hydrogen valve 78a is provided in the first hydrogen line 77a.
  • One end of the second hydrogen line 77b is connected to the outlet of the second adsorption tower 71b.
  • a second hydrogen valve 78b is provided on the second hydrogen line 77b.
  • One end of a hydrogen line 99 is connected to the other end of the first hydrogen line 77a and the other end of the second hydrogen line 77b.
  • the hydrogen line 99 is provided with a hydrogen compressor 77c.
  • the ammonia adsorption amount of the ammonia adsorbent Ab in the first adsorption tower 71a is extremely small and the ammonia adsorption amount of the ammonia adsorption material Ab in the second adsorption tower 71b is large.
  • the first treated gas valve 73a, the first hydrogen valve 78a, and the second offgas valve 75b are opened, and the second treated gas valve 73b, the second hydrogen valve 78b, and the first offgas valve 75a are closed.
  • the treated gas PG from the ammonia recovery facility 60 flows into the first adsorption tower 71a through the first treated gas line 72a and the first treated gas valve 73a.
  • the treated gas PG flowing into the first adsorption tower 71a passes through the ammonia adsorbent Ab, most of the undecomposed ammonia contained in the treated gas PG is adsorbed by the ammonia adsorbent Ab, and the treated gas PG Most of the hydrogen contained in PG is discharged from the first adsorption tower 71a as high-purity hydrogen.
  • This high-purity hydrogen is sent to the hydrogen tank 79 via the first hydrogen line 77a, the first hydrogen valve 78a, the hydrogen line 99, and the hydrogen compressor 77c.
  • the ammonia adsorbed on the ammonia adsorbent Ab in the second adsorption tower 71b is released from the ammonia adsorbent Ab by vacuum-sucking the inside of the second adsorption tower 71b with the vacuum pump . Then, from the second adsorption tower 71b, this ammonia and the offgas OG containing hydrogen remaining in the second adsorption tower 71b are transferred to the second offgas line 74b, the second offgas valve 75b, the offgas line 97, the vacuum pump 76, It is sent to combustor 12 via offgas compressor 97 c and secondary fuel valve 98 .
  • the first treated gas valve 73a When the ammonia adsorption amount of the ammonia adsorbent Ab in the first adsorption tower 71a increases and the ammonia adsorption amount of the ammonia adsorbent Ab in the second adsorption tower 71b becomes extremely small, the first treated gas valve 73a, the first hydrogen Close the valve 78a and the second offgas valve 75b and open the second treated gas valve 73b, the second hydrogen valve 78b and the first offgas valve 75a.
  • the treated gas PG from the ammonia recovery facility 60 flows into the second adsorption tower 71b via the second treated gas line 72b and the second treated gas valve 73b.
  • the ammonia adsorbed on the ammonia adsorbent Ab in the first adsorption tower 71a is released from the ammonia adsorbent Ab by vacuum-sucking the inside of the first adsorption tower 71a with the vacuum pump . Then, from the first adsorption tower 71a, this ammonia and the offgas OG containing hydrogen remaining in the first adsorption tower 71a are released into the first offgas line 74a, the first offgas valve 75a, the offgas line 97, the vacuum pump 76, It is sent to combustor 12 via offgas compressor 97 c and secondary fuel valve 98 .
  • the hydrogen purification equipment 70 when ammonia is adsorbed by the ammonia adsorbent Ab in the first adsorption tower 71a, ammonia is adsorbed from the ammonia adsorbent Ab in the second adsorption tower 71b. let it release. Further, in the hydrogen purification equipment 70 of the present embodiment, while releasing ammonia from the ammonia adsorbent Ab in the first adsorption tower 71a, the ammonia adsorbent Ab in the second adsorption tower 71b adsorbs ammonia.
  • the hydrogen refining equipment 70 in this embodiment can continuously receive the treated gas PG from the ammonia recovery equipment 60, remove most of the undecomposed ammonia, and continuously discharge high-purity hydrogen. Off-gases OG containing residual ammonia and residual hydrogen can be discharged continuously.
  • the air compressor 11 of the gas turbine 10 compresses air to generate compressed air CA.
  • the combustor 12 burns fuel in this compressed air CA to generate combustion gas.
  • the combustion gases are supplied to turbine 13 to drive this turbine 13 .
  • the exhaust gas which is the combustion gas that has driven the turbine 13 , flows into the boiler frame 21 of the heat recovery steam generator 20 .
  • each steam generation system 22, 23, 25 of the exhaust heat recovery boiler 20 heat is exchanged between the exhaust gas flowing in the boiler frame 21 and the water, and the liquid water is turned into steam.
  • Water is supplied from the water supply pump 37 to the economizer 22 a of the low-pressure steam generation system 22 .
  • the economizer 22a heat-exchanges the water with the exhaust gas to heat the water into hot water.
  • a part of this hot water is sent to the high-pressure steam generation system 25 after being pressurized by the high-pressure pump 26 .
  • the hot water sent to the high-pressure steam generation system 25 becomes high-pressure steam HS through heat exchange with the exhaust gas.
  • This high pressure steam HS is supplied to the high pressure steam turbine 33 via a high pressure steam line 43 .
  • the high pressure steam turbine 33 is driven by this high pressure steam HS.
  • Another part of the hot water from the economizer 22a of the low-pressure steam generation system 22 is sent to the medium-pressure steam generation system 23 after being pressurized by the medium-pressure pump 24.
  • the hot water sent to the intermediate-pressure steam generation system 23 becomes intermediate-pressure steam IS through heat exchange with the exhaust gas.
  • This intermediate pressure steam IS is supplied to the intermediate pressure steam turbine 32 via an intermediate pressure steam line 42 .
  • Steam exhausted from the high pressure steam turbine 33 is supplied to the intermediate pressure steam turbine 32 via a high pressure exhaust steam line 44 . That is, the intermediate pressure steam turbine 32 is supplied with the intermediate pressure steam IS from the intermediate pressure steam generation system 23 and the steam exhausted from the high pressure steam turbine 33 .
  • the intermediate pressure steam turbine 32 is driven by steam supplied to this intermediate pressure steam turbine 32 .
  • Another part of the hot water from the economizer 22a of the low-pressure steam generation system 22 is heated by the exhaust gas in the evaporator 22b of the low-pressure steam generation system 22 to become steam.
  • This steam is superheated by the exhaust gas in the superheater 22c of the low-pressure steam generating system 22 and becomes low-pressure steam LS.
  • This low-pressure steam LS is supplied to the low-pressure steam turbine 31 via a low-pressure steam line 41 .
  • Steam exhausted from the intermediate pressure steam turbine 32 is supplied to the low pressure steam turbine 31 via an intermediate pressure exhaust steam line 45 . That is, the low-pressure steam turbine 31 is supplied with the low-pressure steam LS from the low-pressure steam generation system 22 and the steam exhausted from the intermediate-pressure steam turbine 32 .
  • the low pressure steam turbine 31 is driven by the steam supplied to this low pressure steam turbine 31 .
  • the steam exhausted from the low-pressure steam turbine 31 is returned to water in the condenser 35.
  • the water in the condenser 35 is sent to the economizer 22 a of the low-pressure steam generation system 22 via the water supply line 36 and the water supply pump 37 .
  • the liquid ammonia NHL in the ammonia tank 50 is pressurized by the ammonia pump 81 and then flows into the ammonia vaporizer 51 .
  • ammonia vaporizer 51 heat is exchanged between the low-pressure steam LS from the low-pressure steam generation system 22 of the heat recovery boiler 20 and the liquid ammonia NHL to vaporize the liquid ammonia NHL and generate gaseous ammonia NHG (ammonia vaporization step S1).
  • the low pressure steam LS cooled by heat exchange with the liquid ammonia NHL is sent to the condenser 35, for example.
  • the medium for heating the liquid ammonia NHL in the ammonia vaporizer 51 may not be the low-pressure steam LS. good too.
  • the gaseous ammonia NHG flows into the ammonia heater 52 .
  • the ammonia heater 52 heats the gaseous ammonia NHG by exchanging heat between the medium pressure steam IS from the medium pressure steam generation system 23 of the heat recovery boiler 20 and the gaseous ammonia NHG (ammonia heating step S2).
  • the medium for heating the gaseous ammonia NHG in the ammonia heater 52 may not be the medium pressure steam IS. It may be hot water from the economizer of the steam generation system 23 or low pressure steam LS from the low pressure steam generation system 22 .
  • Another part of the heated ammonia NHH flows into the ammonia decomposer 53 via the heated ammonia branch line 89 .
  • the ammonia decomposer 53 heat is exchanged between the high-pressure steam HS from the high-pressure steam generation system 25 of the heat recovery boiler 20 and the heated ammonia NHH in a catalytic environment, and the heated ammonia NHH is thermally decomposed to produce cracked gas DG. generated (ammonia decomposition step S4).
  • This cracked gas DG contains residual ammonia in addition to hydrogen and nitrogen obtained by thermal decomposition of heated ammonia NHH.
  • the cracked gas DG flows into the absorption tower 61 of the ammonia recovery equipment 60 .
  • the absorption tower 61 the cracked gas DG and water are brought into contact to dissolve residual ammonia in the cracked gas DG in water.
  • ammonia water is produced in the absorption tower 61 .
  • the treated gas PG which is the cracked gas DG from which residual ammonia has been substantially removed, is exhausted.
  • Ammonia water flows into the separation tower 65 of the ammonia recovery facility 60 via the ammonia water line 63 .
  • the separation tower 65 also flows from the reboiler 67 , steam generated by heat exchange between water and the medium pressure steam IS from the medium pressure steam generation system 23 of the heat recovery boiler 20 .
  • the medium for heating water in the reboiler 67 may not be the intermediate pressure steam IS.
  • Hot water from the economizer or hot water from the economizer of the intermediate pressure steam generation system 23 may be used.
  • the ammonia water that has flowed into the separation tower 65 is heated by the steam that has flowed into the separation tower 65 , and the ammonia in the ammonia water shifts from the liquid phase to the gas phase and is discharged from the separation tower 65 .
  • Gas phase ammonia discharged from the separation tower 65 that is, gaseous ammonia NHG is pressurized by the ammonia compressor 95c and sent to the ammonia heater 52 through the ammonia recovery line 95 (ammonia recovery step S5).
  • the gaseous ammonia NHG from the ammonia recovery facility 60 is heated with steam.
  • the liquid ammonia NHL from the ammonia condenser may be returned to the ammonia tank 50 or the ammonia vaporizer 51. good.
  • the liquid ammonia NHL from the ammonia recovery facility 60 is also heated by steam and vaporized.
  • the treated gas PG exhausted from the absorption tower 61 flows into the hydrogen refining equipment 70 via the treated gas line 96 .
  • hydrogen is refined from the treated gas PG, and an off-gas OG containing hydrogen is generated (hydrogen refining step S6).
  • High-purity hydrogen purified from the treated gas PG is sent to the hydrogen tank 79 via the hydrogen line 99 .
  • the offgas OG obtained in the hydrogen refining process is supplied as fuel to the central burner 12bc of the combustor 12 via the offgas line 97 (auxiliary fuel supply step S7).
  • the hydrogen-containing offgas OG sent to the central burner 12bc is ejected from the central burner 12bc into the combustion cylinder 12p and burned in the compressed air.
  • the heated ammonia NHH sent to the plurality of peripheral burners 12bp is ejected from the plurality of peripheral burners 12bp into the combustion cylinder 12p and combusted in the compressed air.
  • Combustion gases produced by combustion of the off-gas OG and hot ammonia NHH flow into the turbine 13 to drive the turbine 13 .
  • the combustion gas that has driven the turbine 13 flows into the boiler frame 21 of the heat recovery steam generator 20 as exhaust gas.
  • Hydrogen burns faster than ammonia. Therefore, when a fuel containing hydrogen is burned, localized high temperature is likely to occur in the combustion cylinder 12p, and there is a possibility that the NOx concentration in the combustion gas increases. Therefore, in this embodiment, the off-gas OG containing hydrogen is injected into the combustion cylinder 12p from the central burner 12bc, and the jet of the off-gas OG is surrounded by the jet of ammonia from the plurality of peripheral burners 12bp. . Therefore, in the present embodiment, even if the hydrogen-containing off-gas OG is burned, localized high temperature is suppressed in the combustion cylinder 12p, and the NOx concentration in the combustion gas can be suppressed.
  • heated ammonia NHH is generated by heating gaseous ammonia NHG from liquid ammonia NHL. Then, in the present embodiment, part of this heated ammonia NHH is supplied to the gas turbine 10 as fuel. Furthermore, in the present embodiment, another part of this heated ammonia NHH is thermally decomposed to generate a cracked gas DG containing hydrogen, and then hydrogen is purified from at least a part of this cracked gas DG to produce a high Purity hydrogen is led to hydrogen tank 79 . Therefore, in the present embodiment, it is possible to increase the utility value of the liquid ammonia NHL as compared to simply using all of the liquid ammonia NHL as fuel for the gas turbine 10 .
  • the ammonia vaporizer 51 and the ammonia heater 52 necessary for generating heated ammonia NHH to be supplied as fuel to the gas turbine 10 from liquid ammonia NHL are also used for refining high-purity hydrogen. Therefore, equipment costs and running costs can be reduced. Furthermore, in the present embodiment, as a heat source for heating the liquid ammonia NHL in the ammonia vaporizer 51, heating the gaseous ammonia NHG in the ammonia heater 52, and thermally decomposing the gaseous ammonia NHG in the ammonia decomposer 53, Steam or hot water from the heat recovery boiler 20 is used. Therefore, in this embodiment, the running cost can be suppressed also from this point of view.
  • ammonia is recovered from the cracked gas DG from the ammonia decomposer 53, and the cracked gas DG from which ammonia is recovered is sent to the hydrogen refining facility 70, while the ammonia recovered by the ammonia recovery facility 60 is converted to ammonia. It can be returned to any of tank 50 , ammonia vaporizer 51 and ammonia heater 52 . Therefore, this embodiment can effectively utilize most of the ammonia in the ammonia tank 50 .
  • the hydrogen-containing offgas OG generated in the process of refining hydrogen in the hydrogen refining equipment 70 is sent to the gas turbine 10 as fuel, so the hydrogen in the offgas OG can also be effectively used.
  • the ammonia adsorbent Ab capable of adsorbing ammonia is used in the hydrogen purification equipment 70 in the above embodiment, a hydrogen adsorbent capable of adsorbing hydrogen may be used.
  • the hydrogen refining equipment has a hydrogen adsorbent capable of adsorbing hydrogen under high pressure and releasing hydrogen under low pressure, and is capable of refining hydrogen from at least part of the cracked gas by a pressure swing adsorption method. .
  • gas containing hydrogen and undecomposed ammonia that has passed through the hydrogen adsorbent is supplied to the combustor 12 as an off gas, and the gas is supplied to the combustor 12 under low pressure.
  • the hydrogen released from the hydrogen adsorbent is supplied to the hydrogen tank 79 .
  • the heat recovery boiler 20 in the above embodiment has three types of steam generation systems 22, 23, 25 with different steam pressures and temperatures. However, if the heat recovery boiler 20 can supply steam or hot water at an appropriate temperature to each of the ammonia vaporizer 51, the ammonia heater 52, the ammonia decomposer 53, and the ammonia recovery equipment 60, the steam generation system , one type or two types.
  • the steam turbine facility 30 in the above embodiment has three types of steam turbines 31, 32, and 33 with different incoming steam pressures.
  • the steam turbine installation 30 may have only one type of steam turbine as the steam turbine.
  • the steam from the heat recovery steam generator 20 may be used, for example, as a heat source in a factory or the like without being used in a steam turbine.
  • the steam generation system of the heat recovery boiler 20 may have only one type of steam generation system for generating steam for driving the steam turbine.
  • the ammonia vaporizer 51 and the ammonia heater 52 are separate devices. However, the ammonia vaporizer 51 and the ammonia heater 52 may be integrated. That is, in one heat exchanger, heat is exchanged between steam or hot water and liquid ammonia NHL, the liquid ammonia NHL is heated, the liquid ammonia NHL is converted into gaseous ammonia NHG, and then the gaseous ammonia NHG is further heated. may be converted into heated ammonia NHH.
  • An ammonia tank 50 capable of storing liquid ammonia NHL, a gas turbine 10 capable of being driven using ammonia as fuel, an exhaust heat recovery boiler 20 capable of generating steam using the heat of the exhaust gas from the gas turbine 10, an ammonia vaporizer 51 capable of exchanging heat between the steam or hot water from the heat recovery boiler 20 and the liquid ammonia NHL from the ammonia tank 50 to vaporize the liquid ammonia NHL and generate gaseous ammonia NHG; an ammonia heater 52 capable of exchanging heat between steam or hot water from the heat recovery boiler 20 and the gaseous ammonia NHG from the ammonia vaporizer 51 to heat the gaseous ammonia NHG;
  • a heated ammonia main line 87 that can lead to the gas turbine 10 as a fuel a part of the heated ammonia NHH, which is gaseous ammonia NHG heated by 89, the steam from the heat recovery boiler 20 and the heated ammonia NHH from the heated ammonia branch line 89 are heat-
  • heated ammonia NHH is generated by heating gaseous ammonia NHG from liquid ammonia NHL. Then, in this aspect, part of this heated ammonia NHH is supplied to the gas turbine 10 as fuel. Furthermore, in this embodiment, another part of the heated ammonia NHH is thermally decomposed to generate a cracked gas DG containing hydrogen, and then hydrogen is purified from at least a part of this cracked gas DG to obtain a high-purity Hydrogen is led to the hydrogen tank 79 . Therefore, in this aspect, it is possible to increase the utility value of the liquid ammonia NHL as compared to simply using all of the liquid ammonia NHL as fuel for the gas turbine 10 .
  • the ammonia vaporizer 51 and the ammonia heater 52 necessary for generating heated ammonia NHH to be supplied as fuel to the gas turbine 10 from liquid ammonia NHL are also used for refining high-purity hydrogen. Therefore, equipment costs and running costs can be suppressed.
  • a heat source for heating the liquid ammonia NHL in the ammonia vaporizer 51 heating the gaseous ammonia NHG in the ammonia heater 52, and thermally decomposing the gaseous ammonia NHG in the ammonia decomposer 53, Steam or hot water from the heat recovery boiler 20 is used. Therefore, in this aspect, the running cost can be suppressed also from this point of view.
  • the hydrogen refining equipment 70 has an ammonia adsorbent Ab capable of adsorbing ammonia under high pressure and releasing ammonia under low pressure. Hydrogen can be purified by removing undecomposed ammonia from at least part of.
  • an off-gas line 97 capable of guiding the off-gas OG containing hydrogen generated in the process of refining hydrogen in the hydrogen refining equipment 70 to the gas turbine 10 as fuel.
  • the hydrogen-containing offgas OG generated in the process of refining hydrogen in the hydrogen refining equipment 70 is sent to the gas turbine 10 as fuel, so the hydrogen in the offgas OG can also be effectively used.
  • the gas turbine 10 includes an air compressor 11 capable of compressing air to generate compressed air, and a combustor capable of burning fuel in the compressed air to generate combustion gas. and a turbine 13 operable by the combustion gases from the combustor 12 .
  • the combustor 12 has a cylinder 12p in which the fuel can be combusted and has a cylindrical shape around a cylinder axis Ac, and a plurality of burners 12b capable of injecting fuel into the cylinder 12p.
  • the plurality of burners 12b includes a center burner 12bc and a plurality of peripheral burners 12bp arranged around the center burner 12bc.
  • the off-gas line 97 is connected to the central burner 12bc.
  • the heated ammonia main line 87 is connected to the plurality of peripheral burners 12bp.
  • Hydrogen burns faster than ammonia. Therefore, when hydrogen is used as fuel and burned, localized high temperature is likely to occur in the combustion cylinder 12p, and there is a possibility that the NOx concentration in the combustion gas increases. Therefore, in this embodiment, the off-gas OG containing hydrogen is injected from the central burner 12bc into the cylinder 12p, and the jet of the off-gas OG is surrounded by the jet of ammonia from the plurality of peripheral burners 12bp. Therefore, in this aspect, even if the hydrogen-containing off-gas OG is burned, localized high temperature is suppressed in the cylinder 12p, and the NOx concentration in the combustion gas can be suppressed.
  • ammonia is recovered from the cracked gas DG from the ammonia decomposer 53, and the cracked gas DG from which ammonia is recovered is converted into the hydrogen Ammonia recovery facility 60 capable of being sent to refining facility 70; and an ammonia recovery line 95 that can be led to.
  • ammonia is recovered from the cracked gas DG from the ammonia decomposer 53, and the cracked gas DG from which the ammonia is recovered is sent to the hydrogen refining facility 70, while the ammonia recovered by the ammonia recovery facility 60 is transferred to the ammonia tank. 50 , ammonia vaporizer 51 and ammonia heater 52 . Therefore, in this aspect, most of the ammonia in the ammonia tank 50 can be effectively used.
  • the method for utilizing ammonia in the sixth aspect is A method for utilizing ammonia in a gas turbine plant comprising a gas turbine 10 and an exhaust heat recovery boiler 20 capable of generating steam using the heat of exhaust gas from the gas turbine 10.
  • the steam or hot water from the exhaust heat recovery boiler 20 and liquid ammonia NHL are heat-exchanged to vaporize the liquid ammonia NHL to generate gaseous ammonia NHG;
  • the method for utilizing ammonia in the seventh aspect is in the method for utilizing ammonia in the sixth aspect, in the hydrogen refining step S6, an ammonia adsorbent Ab capable of adsorbing ammonia under high pressure and releasing ammonia under low pressure is used to convert the cracked gas DG Remove undecomposed ammonia from at least a portion of to purify hydrogen.
  • the method for utilizing ammonia in the eighth aspect is In the ammonia utilization method according to the seventh aspect, an auxiliary fuel supply step S7 is executed to introduce the hydrogen-containing off-gas OG generated in the process of refining hydrogen in the hydrogen refining step S6 to the gas turbine 10 as fuel. do.
  • the method for utilizing ammonia in the ninth aspect is in the ammonia utilization method according to any one of the sixth aspect to the eighth aspect.
  • an ammonia recovery step S5 of recovering ammonia from the cracked gas DG is performed.
  • hydrogen is purified from the cracked gas DG from which ammonia has been recovered in the ammonia recovery step S5.
  • heat exchange is performed between the ammonia recovered in the ammonia recovery step S5 and the steam or hot water from the exhaust heat recovery boiler 20.
  • ammonia in the ammonia tank 50 can be effectively used as in the gas turbine plant in the fifth aspect.

Landscapes

  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Organic Chemistry (AREA)
  • Health & Medical Sciences (AREA)
  • General Health & Medical Sciences (AREA)
  • Inorganic Chemistry (AREA)
  • Treating Waste Gases (AREA)
  • Engine Equipment That Uses Special Cycles (AREA)

Abstract

Cette installation de turbine à gaz comprend : une chaudière de récupération de chaleur perdue ; un vaporisateur d'ammoniac qui produit de l'ammoniac gazeux en provoquant l'échange de chaleur entre la vapeur provenant de la chaudière de récupération de chaleur perdue et l'ammoniac liquide ; un dispositif de chauffage d'ammoniac qui produit de l'ammoniac chauffé en provoquant l'échange de chaleur entre la vapeur provenant de la chaudière de récupération de chaleur perdue et l'ammoniac gazeux pour chauffer l'ammoniac gazeux ; une conduite principale d'ammoniac chauffé qui guide une partie de l'ammoniac chauffé vers une turbine à gaz en tant que combustible ; une conduite de ramification d'ammoniac chauffé qui se ramifie à partir de la conduite principale d'ammoniac chauffé ; un décomposeur d'ammoniac qui produit un gaz de décomposition en amenant la chaleur à être échangée entre la vapeur provenant de la chaudière de récupération de chaleur perdue et l'ammoniac chauffé provenant de la conduite de ramification d'ammoniac chauffé pour décomposer thermiquement l'ammoniac chauffé ; et un équipement de purification d'hydrogène qui purifie l'hydrogène à partir d'au moins une partie du gaz de décomposition.
PCT/JP2023/002983 2022-02-25 2023-01-31 Installation de turbine à gaz et méthode d'utilisation d'ammoniac à l'intérieur de celle-ci WO2023162589A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
JP2022028471A JP2023124601A (ja) 2022-02-25 2022-02-25 ガスタービンプラント、及びそのアンモニア利用方法
JP2022-028471 2022-02-25

Publications (1)

Publication Number Publication Date
WO2023162589A1 true WO2023162589A1 (fr) 2023-08-31

Family

ID=87765570

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/JP2023/002983 WO2023162589A1 (fr) 2022-02-25 2023-01-31 Installation de turbine à gaz et méthode d'utilisation d'ammoniac à l'intérieur de celle-ci

Country Status (3)

Country Link
JP (1) JP2023124601A (fr)
TW (1) TW202346703A (fr)
WO (1) WO2023162589A1 (fr)

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20190084831A1 (en) * 2016-03-14 2019-03-21 Equinor Energy As Ammonia cracking
JP2020147481A (ja) * 2019-03-15 2020-09-17 三菱日立パワーシステムズ株式会社 アンモニア分解設備、これを備えるガスタービンプラント、アンモニア分解方法
JP2020147478A (ja) * 2019-03-15 2020-09-17 三菱日立パワーシステムズ株式会社 アンモニア分解設備、これを備えるガスタービンプラント、アンモニア分解方法
US20220162999A1 (en) * 2020-11-20 2022-05-26 Raytheon Technologies Corporation Cracking and separation of ammonia fuel

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20190084831A1 (en) * 2016-03-14 2019-03-21 Equinor Energy As Ammonia cracking
JP2020147481A (ja) * 2019-03-15 2020-09-17 三菱日立パワーシステムズ株式会社 アンモニア分解設備、これを備えるガスタービンプラント、アンモニア分解方法
JP2020147478A (ja) * 2019-03-15 2020-09-17 三菱日立パワーシステムズ株式会社 アンモニア分解設備、これを備えるガスタービンプラント、アンモニア分解方法
US20220162999A1 (en) * 2020-11-20 2022-05-26 Raytheon Technologies Corporation Cracking and separation of ammonia fuel

Also Published As

Publication number Publication date
JP2023124601A (ja) 2023-09-06
TW202346703A (zh) 2023-12-01

Similar Documents

Publication Publication Date Title
JP7285098B2 (ja) アンモニア分解設備、これを備えるガスタービンプラント、アンモニア分解方法
CA2542610C (fr) Travaux de purification pour centrale thermique
US11939915B2 (en) Raw material fluid treatment plant and raw material fluid treatment method
RU2315186C2 (ru) Тепловая электростанция с малым выделением загрязняющих веществ
RU2495707C2 (ru) Способ и устройство для отделения диоксида углерода от отходящего газа работающей на ископаемом топливе электростанции
ES2387008T3 (es) Integración térmica de centrales de oxígeno
ES2377877T3 (es) Proceso y sistema para utilizar calor residual a baja temperatura para la preparación de gas de síntesis
US20090117024A1 (en) Process for the Production of Hydrogen with Co-Production and Capture of Carbon Dioxide
WO2020189575A1 (fr) Équipement de décomposition d'ammoniac, installation de turbine à gaz pourvue dudit équipement et procédé de décomposition d'ammoniac
CN102089062A (zh) 用于从化石燃料发电设备的废气中分离二氧化碳的方法和装置
WO2012013596A1 (fr) Turboréacteur à capture de carbone
CN104254673A (zh) 联合循环发电设备
WO2023162589A1 (fr) Installation de turbine à gaz et méthode d'utilisation d'ammoniac à l'intérieur de celle-ci
JPH07119491A (ja) Lng改質ガス燃焼ガスタービン複合発電プラント
ES2897549T3 (es) Un procedimiento de fabricación de urea y una planta de fabricación que usa CO2 producido por oxicombustión
JP2022027600A (ja) 後燃焼co2捕集のためのガス状排出物の前処理方法およびシステム
KR102583688B1 (ko) 복합 발전 시스템 및 복합 발전 시스템의 구동 방법
US20180058316A1 (en) Vapor plant and method of operating a vapor plant
KR20240048395A (ko) 복합 발전 시스템 및 복합 발전 시스템의 구동 방법
JP2001289008A (ja) ガスタービンシステム
JPH04126512A (ja) 混合ガスの分離回収システム及び運転方法
KR20230161180A (ko) 복합 화력 발전 장치
JP2002138803A (ja) 炭酸ガス回収型ガスタービン発電プラント及びその運転方法
WO2024013617A2 (fr) Système de récupération pour fours industriels à combustion de type oxy-combustible
WO2018200526A1 (fr) Procédés de récupération de dioxyde de carbone avec récupération d'énergie améliorée

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 23759595

Country of ref document: EP

Kind code of ref document: A1