KR20230161567A - Floating storage power generation unit - Google Patents

Abstract

The floating storage power generation facility according to an embodiment of the present invention is installed on the facility body 100, which can float, and is capable of burning LNG fuel (1) or ammonia fuel (2). It is installed in the fuel engine 200 and the facility body 100, and the regasification unit 300, which vaporizes the LNG fuel (1) into natural gas fuel (4), is installed in the facility body (100) and LNG fuel (1 ) is installed in the LNG supply unit 400, which supplies ammonia fuel 2 to the multi-fuel engine 200, the facility main body 100, and the ammonia supply unit 500, which supplies ammonia fuel 2 to the multi-fuel engine 200, the facility main body ( 100), a hydrogen production unit (600) that decomposes ammonia fuel (2) to produce hydrogen fuel (3), and a gas turbine that is installed in the facility body (100) and generates power using hydrogen fuel (3). Includes a power generation unit (10).

Description

Floating storage power generation equipment {FLOATING STORAGE POWER GENERATION UNIT}

The present invention relates to a floating storage power generation facility, and more specifically, to a floating storage power generation facility using LNG fuel and ammonia fuel. More specifically, it floats on the sea and is capable of supplying, storing, and generating power using LNG. This relates to a floating storage power generation facility that can solve the greenhouse gas reduction problem by using fuel and ammonia fuel.

으로 압축 냉각하여 얻어지는 것으로 가스 상태의 천연 가스일 때보다 그 부피가 대략 1/600로 줄어들므로 해상을 통한 원거리 운반에 매우 적합하다.Natural gas is transported in gaseous form through onshore or offshore gas pipelines, or stored in an LNG carrier as liquefied natural gas (LNG) and transported to distant consumers. Liquefied natural gas is natural gas that is stored at cryogenic temperatures (approximately -160°C).

It is obtained by compressing and cooling, and its volume is reduced to approximately 1/600 compared to gaseous natural gas, making it very suitable for long-distance transportation through the sea.

LNG carriers are intended to carry liquefied natural gas on the sea and unload liquefied natural gas at land-based destinations. For this purpose, LNG storage tanks (commonly referred to as 'cargo holds') that can withstand the extremely low temperatures of liquefied natural gas are installed. Includes. Typically, these LNG carriers unload the liquefied natural gas in the LNG storage tank on land in its liquefied state, and the unloaded LNG is regasified by an LNG regasification facility installed on land and then transported through gas pipes to natural gas consumers. do.

These onshore LNG regasification facilities are known to be economically advantageous when installed in places where there is a stable demand for natural gas because the natural gas market is well established. However, in the case of natural gas demand places where natural gas demand is seasonal, short-term, or periodic, it is economically very disadvantageous to install LNG regasification facilities on land due to high installation and management costs.

In particular, if the LNG regasification facility on land is destroyed due to a natural disaster, etc., natural gas transportation using existing LNG carriers has limitations in that the LNG cannot be regasified even if the LNG carrier reaches the required destination with LNG. holding it

Accordingly, for example, an offshore LNG regasification system is installed in an offshore plant or LNG carrier, regasifies liquefied natural gas at sea, and supplies the natural gas obtained through the regasification to land. was developed.

Examples of offshore structures equipped with storage tanks capable of storing liquefied gas at extremely low temperatures and regasification equipment for regasifying liquefied gas include ships such as LNG regasification vessels (RVs) or LNG floating storage regasification vessels. Plants such as facilities (Floating Storage Regasification Unit, FSRU) can be mentioned.

An LNG regasification vessel is an LNG regasification facility installed on a liquefied gas carrier capable of sailing and floating under its own power, and an LNG floating storage regasification facility stores liquefied natural gas unloaded from an LNG carrier at sea far from land in a storage tank. It is an offshore structure that stores and vaporizes liquefied natural gas as needed and supplies it to onshore consumers. The offshore structure referred to here may be a concept that includes not only ships such as liquefied gas carriers and LNG regasification ships, but also plants such as LNG floating storage and regasification facilities.

These LNG floating storage and regasification facilities use a diesel engine as a power generation engine using diesel as fuel, or a dual fuel engine using diesel and natural gas as fuel. However, due to the strengthened International Maritime Organization (IMO) greenhouse gas (GHC) and carbon dioxide (CO ₂ ) reduction regulations, the current fuel supply system cannot achieve international exhaust gas emission standards. difficult.

In particular, when the LNG floating storage regasification facility uses a diesel engine as a power generation engine, the exhaust gas of the diesel engine has a high carbon dioxide (CO ₂ ) content, and the LNG floating storage regasification facility uses diesel and diesel engines as a power generation engine. When using a dual-fuel engine fueled by natural gas, the exhaust gas of the dual-fuel engine has a high content of methane slip, which is unburned methane. The greenhouse effect of methane (CH ₄ ) is very high, at 21 times that of carbon dioxide.

Meanwhile, as greenhouse gas emissions regulations are strengthened, demand for hydrogen fuel is increasing. However, there are difficulties in transporting liquefied hydrogen by ship. Therefore, technology is being developed to produce hydrogen fuel by transporting ammonia by ship and then decomposing the ammonia. However, it is difficult to obtain government permission for ammonia facilities such as ammonia unloading facilities, storage facilities, supply facilities, etc. when installed on land due to the toxicity and explosiveness of ammonia, and it is difficult to select a region as facilities are avoided by residents.

Korean Patent Publication No. 10-2020-0049933 (Floating Platform, 2020.05.11.)

The technical problem to be achieved by the idea of the present invention is to provide a floating storage power generation facility that floats on the sea and is capable of fuel supply, storage, and power generation, and can solve the greenhouse gas reduction problem by using LNG fuel and ammonia fuel.

A floating storage power generation facility according to an embodiment of the present invention includes a facility body 100 capable of floating; A multi-fuel engine (200) installed in the facility body (100) and capable of burning LNG fuel (1) or ammonia fuel (2); A regasification unit 300 installed in the facility body 100 and vaporizing the LNG fuel 1 into natural gas fuel 4; An LNG supply unit 400 installed in the facility body 100 and supplying the LNG fuel 1 to the multi-fuel engine 200; An ammonia supply unit 500 installed in the facility main body 100 and supplying the ammonia fuel 2 to the multi-fuel engine 200; A hydrogen production unit 600 installed in the facility main body 100 and producing hydrogen fuel 3 by decomposing the ammonia fuel 2; And it is installed in the facility main body 100 and includes a gas turbine power generation unit 10 that generates power using the hydrogen fuel 3.

Here, it is installed in the facility main body 100 and may further include a waste heat treatment unit 20 that processes waste heat generated in the gas turbine power generation unit 10.

At this time, the gas turbine power generation unit 10 includes a combustor 12, and the combustor 12 is one of the hydrogen fuel 3, the natural gas fuel 4, and the ammonia fuel 2. By burning the above, high temperature and high pressure hydrogen co-combustion gas can be generated.

In addition, the gas turbine power generation unit 10 includes a compressor 11 that generates compressed air, a combustor 12 that supplies the compressed air to generate the high-temperature and high-pressure hydrogen co-combustion gas, and the hydrogen co-combustion gas. It may further include a gas turbine 13 driven using a gas turbine 13, and a gas turbine generator 14 generating power using the driving force of the gas turbine 13.

In addition, the waste heat treatment unit 20 includes a waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, a steam turbine 22 that generates and drives steam using the waste heat, And it may include a steam turbine generator 23 that generates power using the driving force of the steam turbine 22.

In addition, the waste heat treatment unit 20 includes a waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, and a hot water generator 24 that generates hot water using the waste heat. It can be included.

In addition, it may further include an ammonia transfer unit 900 that transfers the ammonia fuel (2) to the ammonia demand source (E3) on land.

In addition, the ammonia supply unit 500 includes an ammonia storage tank 510 for storing the ammonia fuel 2, and the ammonia transfer unit 900 includes the ammonia storage tank 510 and the ammonia demand source (E3). ) and may include an ammonia storage pipe 910 for transferring the ammonia fuel (2), and an ammonia deck tank 920 connected to the ammonia storage pipe 910 and storing the ammonia fuel (2). there is.

In addition, the ammonia transfer unit 900 includes an ammonia compressor 940 that compresses the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and stores it in the ammonia deck tank 920, and the ammonia deck. It may further include an ammonia meter 950 that measures the ammonia fuel 2 stored in the tank 920 and supplies it to the ammonia demander E3.

In addition, the ammonia supply unit 500 connects the ammonia storage tank 510 and the multi-fuel engine 200, and includes an ammonia supply pipe 520 for transferring the ammonia fuel 2, and the ammonia storage tank. It may further include a re-liquefaction device 530 that re-liquefies the ammonia boil-off gas (B2) generated in 510 and transfers it to the ammonia storage tank 510.

In addition, the hydrogen production unit 600 is installed on the connection pipe 610, which connects the ammonia deck tank 920 and the combustor 12, and decomposes the ammonia fuel 2. Installed on the ammonia decomposition unit 620 for producing the hydrogen fuel 3, the hydrogen separation unit 630 for separating the hydrogen fuel 3 from the ammonia decomposition unit 620, and the connection pipe 610. and an ammonia heat exchanger 640 that vaporizes the ammonia fuel 2 using the waste heat generated in the gas turbine power generation unit 10 to produce ammonia gas fuel 7, and in the ammonia deck tank 920. It includes a fourth heater 650 that heats the supplied ammonia fuel 2 and supplies it to the combustor 12, and the hydrogen fuel 3 separated from the hydrogen separation unit 630 is supplied to the combustor 12. can be supplied to

In addition, the LNG supply unit 400 includes an LNG storage tank 410 that stores the LNG fuel 1, vaporizes the LNG fuel 1, and supplies the natural gas fuel 5 to the multi-fuel engine 200. It includes a first heater 420 that supplies, and an LNG pipe 430 that connects the LNG storage tank 410 and the first heater 420 and transfers the LNG fuel 1, and the reliquefaction (530) may be installed on the LNG pipe (430).

In addition, the LNG supply unit 400 may further include a natural gas pipe 440 that connects the first heater 420 and the multi-fuel engine 200 and transfers the natural gas fuel 5. .

In addition, a first electricity supply unit connects the gas turbine power generation unit 10 and the onshore electricity demand source (E1) on land, and supplies electricity produced by the gas turbine power generation unit 10 to the land electricity demand source (E1). It may further include (710).

In addition, a device connects the multi-fuel engine 200 and the on-board electricity consumer (E4) of the equipment main body 100, and supplies electricity produced by the multi-fuel engine 200 to the on-board electricity consumer (E4). 2 It may further include an electricity supply unit 720.

In addition, it further includes a diesel supply unit 800 that supplies diesel fuel 6 to the multi-fuel engine 200, and the multi-fuel engine 200 is supplied with the LNG fuel 1, the ammonia fuel 2, or It is an engine capable of burning the diesel fuel 6, and the diesel supply unit 800 includes a diesel storage tank 810 installed in the equipment main body 100 and storing the diesel fuel 6, and the diesel It may further include a diesel pipe 820 that transfers fuel 6 from the diesel storage tank 810 to the multi-fuel engine 200.

Meanwhile, a floating storage power generation facility according to another embodiment of the present invention includes a facility body 100 capable of floating; A multi-fuel engine (200) installed in the facility body (100) and capable of burning LNG fuel (1) or ammonia fuel (2); A regasification unit 300 installed in the facility body 100 and vaporizing the LNG fuel 1 into natural gas fuel 4; An LNG supply unit 400 installed in the facility body 100 and supplying the LNG fuel 1 to the multi-fuel engine 200; An ammonia supply unit 500 installed in the facility main body 100 and supplying the ammonia fuel 2 to the multi-fuel engine 200; A hydrogen production unit (600) installed on land (E), which decomposes the ammonia fuel (2) to produce hydrogen fuel (3); And it is installed on land (E) and includes a gas turbine power generation unit (10) that generates power using the hydrogen fuel (3).

Here, it is installed on land (E) and may further include a waste heat treatment unit 20 that processes waste heat generated in the gas turbine power generation unit 10.

At this time, the gas turbine power generation unit 10 includes a combustor 12, and the combustor 12 is one of the hydrogen fuel 3, the natural gas fuel 4, and the ammonia fuel 2. By burning the above, high temperature and high pressure hydrogen co-combustion gas can be generated.

In addition, the gas turbine power generation unit 10 includes a compressor 11 that generates compressed air, a combustor 12 that supplies the compressed air to generate the high-temperature and high-pressure hydrogen co-combustion gas, and the hydrogen co-combustion gas. It may further include a gas turbine 13 driven using a gas turbine 13, and a gas turbine generator 14 generating power using the driving force of the gas turbine 13.

In addition, the waste heat treatment unit 20 includes a waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, a steam turbine 22 that generates steam using the waste heat and generates power, And it may include a steam turbine generator 23 that generates power using the driving force of the steam turbine 22.

In addition, the waste heat treatment unit 20 includes a waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, and a hot water generator 24 that generates hot water using the waste heat. It can be included.

In addition, it may further include an ammonia transfer unit 900 that transfers the ammonia fuel (2) to the ammonia demand source (E3) on land (E).

In addition, the ammonia supply unit 500 includes an ammonia storage tank 510 for storing the ammonia fuel 2, and the ammonia transfer unit 900 includes the ammonia storage tank 510 and the ammonia demand source (E3). ) and may include an ammonia storage pipe 910 for transferring the ammonia fuel (2), and an ammonia deck tank 920 connected to the ammonia storage pipe 910 and storing the ammonia fuel (2). there is.

In addition, the gas turbine power generation unit 10 includes an ammonia land tank 16 connected to the ammonia deck tank 920 and installed on land (E), and the ammonia supplied from the ammonia land tank 16. It may further include a third heater 15 that vaporizes the fuel 2, and the ammonia fuel 2 vaporized in the third heater 15 can be supplied to the combustor 12.

In addition, the ammonia transfer unit 900 includes an ammonia compressor 940 that compresses the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and stores it in the ammonia deck tank 920, and the ammonia deck. It may further include an ammonia meter 950 that measures the ammonia fuel 2 stored in the tank 920 and supplies it to the ammonia demander E3.

In addition, the ammonia supply unit 500 connects the ammonia storage tank 510 and the multi-fuel engine 200, and includes an ammonia supply pipe 520 for transferring the ammonia fuel 2, and the ammonia storage tank. It may further include a re-liquefaction device 530 that re-liquefies the ammonia boil-off gas (B2) generated in 510 and transfers it to the ammonia storage tank 510.

In addition, the hydrogen production unit 600 is installed on the connection pipe 610, which connects the ammonia deck tank 920 and the combustor 12, and decomposes the ammonia fuel 2. On the ammonia decomposition unit 620 for producing the hydrogen fuel 3, the hydrogen separation unit 630 for separating the hydrogen fuel 3 from the ammonia decomposition unit 620, and the connection pipe 610. It is installed and includes an ammonia heat exchanger 640 that vaporizes the ammonia fuel 2 using the waste heat generated in the gas turbine power generation unit 10 to produce ammonia gas fuel 7, and the hydrogen separation unit ( The hydrogen fuel 3 separated in 630) may be supplied to the combustor 12.

In addition, the LNG supply unit 400 includes an LNG storage tank 410 that stores the LNG fuel 1, vaporizes the LNG fuel 1, and supplies the natural gas fuel 5 to the multi-fuel engine 200. It includes a first heater 420 that supplies, and an LNG pipe 430 that connects the LNG storage tank 410 and the first heater 420 and transfers the LNG fuel 1, and the reliquefaction (530) may be installed on the LNG pipe (430).

In addition, the LNG supply unit 400 may further include a natural gas pipe 440 that connects the first heater 420 and the multi-fuel engine 200 and transfers the natural gas fuel 5. .

In addition, the gas turbine power generation unit 10 is connected to the land-based electricity consumer (E1) on land (E), and the electricity produced by the gas turbine power generation unit 10 is supplied to the land-based electricity consumer (E1). It may further include a first electricity supply unit 710.

In addition, a device connects the multi-fuel engine 200 and the on-board electricity consumer (E4) of the equipment main body 100, and supplies electricity produced by the multi-fuel engine 200 to the on-board electricity consumer (E4). 2 It may further include an electricity supply unit 720.

In addition, it further includes a diesel supply unit 800 that supplies diesel fuel 6 to the multi-fuel engine 200, and the multi-fuel engine 200 is supplied with the LNG fuel 1, the ammonia fuel 2, or It is an engine capable of burning the diesel fuel 6, and the diesel supply unit 800 includes a diesel storage tank 810 installed in the equipment main body 100 and storing the diesel fuel 6, and the diesel It may further include a diesel pipe 820 that transfers fuel 6 from the diesel storage tank 810 to the multi-fuel engine 200.

The floating storage power generation facility according to an embodiment of the present invention includes a multi-fuel engine capable of burning LNG fuel and ammonia fuel, a hydrogen production unit that produces hydrogen fuel using ammonia fuel, and gas that generates power using hydrogen fuel. By including a turbine power generation unit, a multi-fuel engine can be driven using LNG fuel and ammonia fuel, which emit low greenhouse gases, and power generation can be generated using hydrogen fuel, thereby reducing greenhouse gases in compliance with international exhaust gas emission standards. .

In addition, by installing a floating storage power generation facility using LNG fuel and ammonia fuel at sea, there is no need to install ammonia facilities such as separate ammonia fuel unloading facilities, storage facilities, decomposition facilities, and supply facilities on land, so the government It can be free from permission or avoidance by residents.

Additionally, by supplying low-carbon electricity produced by a multi-fuel engine to the facility body, the generation of greenhouse gases can be minimized.

In addition, the generation of greenhouse gases can be minimized by supplying carbon-free electricity produced by the gas turbine power generation unit to land using hydrogen fuel produced by the hydrogen production unit.

1 is a schematic diagram of a floating storage power plant according to a first embodiment of the present invention.
Figure 2 is a detailed diagram of a floating storage power generation facility according to a first embodiment of the present invention.
Figure 3 is a detailed diagram of a floating storage power generation facility according to a second embodiment of the present invention.
Figure 4 is a detailed diagram of a floating storage power generation facility according to a third embodiment of the present invention.
Figure 5 is a detailed diagram of a floating storage power generation facility according to a fourth embodiment of the present invention.
Figure 6 is a detailed diagram of a floating storage power generation facility according to a fifth embodiment of the present invention.
Figure 7 is a detailed diagram of a floating storage power generation facility according to the sixth embodiment of the present invention.
Figure 8 is a detailed diagram of a floating storage power generation facility according to the seventh embodiment of the present invention.
Figure 9 is a detailed diagram of a floating storage power generation facility according to the eighth embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

FIG. 1 is a schematic diagram of a floating storage power generation facility according to a first embodiment of the present invention, and FIG. 2 is a detailed diagram of a floating storage power generation facility according to a first embodiment of the present invention.

As shown in Figures 1 and 2, the floating storage power generation facility according to the first embodiment of the present invention includes a facility body 100, a multi-fuel engine 200, a regasification unit 300, and an LNG supply unit 400. , an ammonia supply unit 500, a hydrogen production unit 600, a gas turbine power generation unit 10, a waste heat treatment unit 20, an electricity supply unit 700, a diesel supply unit 800, and an ammonia transfer unit 900.

The facility main body 100 may be a marine structure capable of floating on the sea (S). Here, offshore structures are a broad concept that includes ships, barges, or plants. The facility main body 100 includes a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, an ammonia supply unit 500, a hydrogen production unit 600, a gas turbine power generation unit 10, and a waste heat treatment unit 20. , an electricity supply unit 700, a diesel supply unit 800, and an ammonia transfer unit 900 may be installed.

The multi-fuel engine 200 can burn LNG fuel (1), ammonia fuel (2), and diesel fuel (6). Here, the ammonia fuel 2 can be supplied to the multi-fuel engine 200 in a liquid state.

In this way, the multi-fuel engine 200 can be driven or generate power by burning various fuels, so it is efficient and easy to achieve international exhaust gas emission regulation standards.

The regasification unit 300 can vaporize the LNG fuel 1 to create natural gas fuel 4 and supply it to the natural gas demand source E2 on land (E).

The regasification unit 300 includes a compressor 310, a recondenser 320, a suction drum 330, a high pressure pump (HP), a vaporizer 340, and a meter. ) (350), and may include a regasification pipe (360).

The LNG fuel 1 is heated by the heat flowing into the LNG storage tank 410, thereby generating boil-off gas (BOG) of LNG (B1) in the LNG storage tank 410.

The compressor 310 may compress the boil-off gas (B1) and supply it to the re-condenser 320.

The re-condenser 320 can re-condense the boil-off gas (B1) and mix it with the LNG fuel (1) supplied from the LNG storage tank (410). At this time, the recondenser 320 condenses the boil-off gas (B1) with the cold heat of the LNG fuel (1), and for this purpose, more LNG fuel (1) than the boil-off gas (B1) can be used at a ratio of 1:10.

The suction drum 330 is located between the recondenser 320 and the high pressure pump (HP) and can function as a buffer so that the high pressure pump (HP) can stably pump the LNG fuel 1.

The high pressure pump (HP) is installed at the rear of the recondenser 320 and compresses the LNG fuel 1 to the pressure required to supply the natural gas fuel 4 to the natural gas demand source E2 on land (E). can do. The high pressure pump (HP) may be a reciprocating pump capable of pressurizing the LNG fuel 1 by applying it at extremely low temperatures, and can compress the LNG fuel 1 to a high pressure of approximately 150 to 300 bar.

The vaporizer 340 can vaporize the LNG fuel (1) into natural gas fuel (4) using an intermediate heat medium such as glycol. The intermediate heat medium is cooled by heat exchange with the LNG fuel (1), and can be heated again by heat exchange with seawater pumped by the seawater pump. The vaporizer 340 may be a shell and tube type heat exchanger. However, it is not necessarily limited to this, and may be a vaporizer of various structures.

The meter 350 can measure the natural gas fuel 4 vaporized in the vaporizer 340 and supply it to the natural gas demand source E2 on land (E).

The regasification pipe 360 may be a pipe connecting the compressor 310, the recondenser 320, the suction drum 330, the vaporizer 340, the meter 350, and the natural gas demand source (E2).

At least one flow control valve (not shown) may be installed in the regasification pipe 360 to control the flow rate of the LNG fuel 1 or the natural gas fuel 4.

The LNG supply unit 400 may supply LNG fuel 1 to the multi-fuel engine 200.

The LNG supply unit 400 includes an LNG storage tank 410, a medium pressure pump (LP), a first heater 420, an LNG pipe 430, a natural gas pipe 440, and an LNG pump 450. It can be included.

The LNG storage tank 410 can store LNG fuel 1. LNG fuel 1 may include liquefied natural gas (LNG) obtained by compressing and cooling natural gas (NG) to extremely low temperatures.

The medium pressure pump (MP) may provide pump pressure to transfer the LNG fuel 1 to the multi-fuel engine 200 according to the fuel supply conditions of the multi-fuel engine 200.

The first heater 420 can vaporize the liquid LNG fuel 1 into gaseous natural gas fuel 5 and supply the gaseous natural gas fuel 5 to the multi-fuel engine 200.

The LNG pipe 430 connects the LNG storage tank 410 and the first heater 420 and can transport LNG fuel 1 in a liquid state.

The natural gas pipe 440 connects the first heater 420 and the multi-fuel engine 200 and can transport natural gas fuel 5 in a gaseous state.

At least one flow control valve (not shown) may be installed on the LNG pipe 430 and the natural gas pipe 440 to control the flow rates of the LNG fuel 1 and the natural gas fuel 5.

The LNG pump 450 may be installed inside the LNG storage tank 410 to provide pump pressure to discharge the LNG fuel 1 from the LNG storage tank 410 to the outside. In particular, the LNG pump 450 may be a submerged pump or a deep well pump installed inside the LNG fuel 1 of the LNG storage tank 410.

The ammonia supply unit 500 may supply ammonia fuel 2 to the multi-fuel engine 200.

The ammonia supply unit 500 may include an ammonia storage tank 510, an ammonia supply pipe 520, a medium pressure pump (MP), a second heater 550, a reliquefaction unit 530, and an ammonia pump 540. there is.

The ammonia storage tank 510 can store ammonia fuel 2. Ammonia fuel 2 may include ammonia (NH ₃ ) and may be supplied to the multi-fuel engine 200 in a liquid state. Ammonia (NH ₃ ) is a chemical substance that has been used on land for over 100 years. It is easy to use because the entire supply chain, including production, storage, transportation, and supply, has been sufficiently verified. Ammonia fuel (2) can be obtained by various known methods, for example, the Harbor-Bosh process, Monsniute process, NEC process, Pauza process, Kazare process, Crood process, etc. It can be obtained or produced through a method.

The ammonia supply pipe 520 connects the ammonia storage tank 510 and the multi-fuel engine 200 and can transport ammonia fuel 2 in a liquid state.

Ammonia fuel 2 may be supplied to the multi-fuel engine 200 according to the fuel supply conditions of the multi-fuel engine 200 while passing through the medium pressure pump (MP) and the second heater 550. At this time, in cases where it is oversupplied or when the fuel consumption rate changes due to engine load changes and it is necessary to prevent the supply pressure from dropping, a portion of the supplied ammonia fuel (2) is recirculated to the ammonia storage tank (510), and is used in multi-fuel engines. It can be supplied from 200 to the ammonia storage tank 510 through a return line (not shown).

The reliquefaction unit 530 can reliquefy the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and transfer it to the ammonia storage tank 510. This reliquefaction unit 530 may be installed on the LNG pipe 430 before the first heater 420. Accordingly, the reliquefaction device 530 can reliquefy the ammonia boil-off gas (B2) using the cold heat of the LNG fuel (1) transported along the LNG pipe (430).

In addition, since the reliquefaction unit 530 is located in front of the first heater 420 of the LNG supply unit 400, the load on the first heater 420 that must heat the LNG fuel 1 can be reduced.

The ammonia pump 540 may be installed inside the ammonia storage tank 510 to provide pump pressure to discharge the ammonia fuel 2 from the ammonia storage tank 510 to the outside. In particular, the ammonia pump 540 may be a submerged pump or a deep well pump installed inside the ammonia fuel 2 of the ammonia storage tank 510.

A medium pressure pump (MP) is installed on the ammonia supply pipe 520 to boost the ammonia fuel 2 supplied from the ammonia storage tank 510 to the ammonia supply pipe 520 to a predetermined pressure and supply it to the first heater 420. You can.

At least one flow control valve (not shown) may be installed on the ammonia supply pipe 520 to control the flow rate of the ammonia fuel 2.

Therefore, the multi-fuel engine 200 can be driven using ammonia fuel 2, which emits less greenhouse gases.

The ammonia transfer unit 900 can transfer ammonia fuel (2) to the ammonia demand source (E3) on land (E).

The ammonia transport unit 900 may include an ammonia storage pipe 910, an ammonia deck tank 920, an ammonia compressor 940, and an ammonia meter 950.

The ammonia storage pipe 910 connects the ammonia storage tank 510 and the ammonia consumer (E3) and may provide a path for transferring the ammonia fuel (2).

The ammonia deck tank 920 is installed on the deck of the facility main body 100 and may be connected to the ammonia storage pipe 910. Ammonia deck tank 920 can store ammonia fuel 2.

The ammonia compressor 940 may compress the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and store it in the ammonia deck tank 920.

The ammonia meter 950 can measure the ammonia fuel (2) stored in the ammonia deck tank 920 and supply it to the ammonia demand source (E3) on land (E).

The hydrogen production unit 600 can produce hydrogen fuel (3) by decomposing ammonia fuel (2). The hydrogen production unit 600 may include a connection pipe 610, an ammonia decomposition unit 620, a hydrogen separation unit 630, an ammonia heat exchanger 640, and a fourth heater 650. The hydrogen production unit 600 may be installed in the facility main body 100 floating in the sea (S).

The connection pipe 610 may connect the ammonia deck tank 920 and the gas turbine power generation unit 10.

The ammonia decomposition unit 620 is installed on the connection pipe 610 and can produce hydrogen fuel (3) by decomposing the ammonia fuel (2).

The ammonia decomposition unit 620 can pyrolyze and reform the liquid ammonia fuel 2 stored in the ammonia deck tank 920. That is, the ammonia decomposition unit 620 can decompose the ammonia fuel 2 into hydrogen (H ₂ ) and nitrogen (N ₂ ) through thermal decomposition (cracking reformer). At this time, undecomposed ammonia (NH ₃ ) may be generated.

Additionally, the ammonia decomposition unit 620 may include an ammonia decomposition catalyst to enable ammonia reforming at a lower temperature. The ammonia decomposition catalyst is not particularly limited as long as it has catalytic activity in the ammonia decomposition reaction, but examples include catalysts containing non-metallic transition metals, rare earth materials, and noble metal materials as a composition, and the above-mentioned catalysts have a high It can be used by supporting it on a carrier with a specific surface area.

The hydrogen separation unit 630 may separate the hydrogen fuel 3 from the hydrogen (H ₂ ) and nitrogen (N ₂ ) decomposed in the ammonia decomposition unit 620.

Although not shown, the nitrogen separated from the hydrogen separation unit 630 may be stored in a separate storage tank and then supplied to a necessary consumer or discharged into the atmosphere. Additionally, undecomposed ammonia may be re-supplied to the ammonia decomposition unit 620.

The ammonia heat exchanger 640 can vaporize the ammonia fuel 2 in a liquid state to generate ammonia gas fuel 7 in a gaseous state. This ammonia heat exchanger 640 may be a shell and tube type heat exchanger. However, it is not necessarily limited to this, and heat exchangers of various structures are possible.

The fourth heater 650 can heat the ammonia fuel 2 supplied from the ammonia deck tank 920 and directly supply it to the gas turbine power generation unit 10.

In this way, by producing hydrogen fuel 3 using the hydrogen production unit 600 and stably supplying and generating power to the gas turbine power generation unit 10, greenhouse gases can be reduced in accordance with international exhaust gas emission regulation standards.

In addition, by installing floating storage power generation facilities using LNG fuel and ammonia fuel at sea, there is no need to install ammonia facilities such as separate ammonia fuel unloading facilities, storage facilities, decomposition facilities, and supply facilities on land, so the government It can be free from permission or avoidance by residents.

The gas turbine power generation unit 10 may generate power using ammonia fuel 2, hydrogen fuel 3, and/or natural gas fuel 4. The gas turbine power generation unit 10 may be installed in the facility main body 100 floating on the sea (S).

The gas turbine power generation unit 10 may include a compressor 11, a combustor 12, a gas turbine 13, and a gas turbine generator 14.

The compressor 11 may generate compressed air by compressing external air.

The combustor 12 can combust ammonia fuel 2, hydrogen fuel 3, and/or natural gas fuel 4 and supply compressed air to produce high-temperature and high-pressure hydrogen co-combustion gas containing hydrogen. . The combustor 12 may be connected to the ammonia deck tank 920 through a connecting pipe 610.

The gas turbine 13 may be a heat engine driven using high temperature and high pressure hydrogen co-combustion gas.

The gas turbine generator 14 can generate power using the driving force of the gas turbine 13. Carbon-free electricity (e) produced by the gas turbine generator 14 can be supplied to onshore electricity demand (E1) on land (E).

In this way, carbon-free electricity is produced in the gas turbine power generation unit 10 using hydrogen fuel produced in the hydrogen production unit 600, and this carbon-free electricity is supplied to land, thereby minimizing the generation of greenhouse gases. .

The waste heat treatment unit 20 may process waste heat generated in the gas turbine power generation unit 10. The waste heat treatment unit 20 may be installed in the facility main body 100 floating in the sea (S).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a steam turbine 22, a steam turbine generator 23, and a nitrogen oxide reduction device 25.

The waste heat recovery unit 21 can recover waste heat generated in the gas turbine power generation unit 10. Specifically, the extremely high temperature exhaust gas of 650 degrees or higher generated from the gas turbine 13 is heat exchanged in the ammonia heat exchanger 640 to become high temperature exhaust gas, and this high temperature exhaust gas can be recovered to the waste heat recovery unit 21. there is.

The steam turbine 22 may be a heat engine that generates and drives steam using waste heat.

The steam turbine generator 23 can generate power using the driving force of the steam turbine 22. Carbon-free electricity (e) produced by the steam turbine generator 23 can be supplied to onshore electricity demand (E1) on land (E).

The nitrogen oxide reduction device 25 is connected to the waste heat recovery unit 21 and the ammonia deck tank 920, and utilizes the ammonia fuel 2 from the ammonia deck tank 920 to discharge the waste heat recovery unit 21. Nitrogen oxides can be treated. This nitrogen oxide reduction device 25 may include a selective catalytic reduction (SCR) device, and in this case, ammonia fuel 2 may be used as a catalyst.

Since the ammonia fuel 2 may generate nitrogen oxides depending on combustion conditions, the nitrogen oxide reduction device can remove nitrogen oxides discharged from the waste heat recovery unit 21 and discharge them as exhaust gas.

Meanwhile, although not shown, the nitrogen oxide reduction device 25 is connected to the multi-fuel engine 200, or a separate nitrogen oxide reduction device is provided to treat nitrogen oxides emitted from the multi-fuel engine 200. . Therefore, greenhouse gas (GHC) can be minimized.

The diesel supply unit 800 may supply diesel fuel 6 to the multi-fuel engine 200. Diesel fuel (6) includes heavy fuel oil (HFO), marine gas oil (MGO), marine diesel oil, MDO), low sulfur fuel oil (LSFO), or very low sulfur fuel oil (VLSFO).

The diesel supply unit 800 includes a diesel storage tank 810 that stores diesel fuel 6, and a diesel pipe 820 that transfers the diesel fuel 6 from the diesel storage tank 810 to the multi-fuel engine 200. It can be included. A plurality of flow control valves (not shown) may be installed on the diesel pipe 820 to control the flow rate of the diesel fuel 6.

As such, the floating storage power generation facility according to the first embodiment of the present invention includes a multi-fuel engine capable of burning LNG fuel and ammonia fuel, a hydrogen production unit that produces hydrogen fuel using ammonia fuel, and hydrogen fuel using hydrogen fuel. By including a gas turbine power generation unit that generates power, a multi-fuel engine can be driven using LNG fuel and ammonia fuel, which emit low greenhouse gases, and power generation can be generated using hydrogen fuel, thereby reducing greenhouse gas emissions in accordance with international exhaust gas emission standards. It can be reduced.

Meanwhile, the electricity supply unit 700 may include a first electricity supply unit 710 and a second electricity supply unit 720.

The first electricity supply unit 710 may connect the gas turbine power generation unit 10, the waste heat treatment unit 20, and the onshore electricity demand source (E1) on land (E). This first electricity supply unit 710 can supply the carbon-free electricity produced by the gas turbine power generation unit 10 to the land electricity consumer (E1), and the carbon-free electricity produced by the waste heat treatment unit 20 to the land electricity consumer (E1). It can be supplied to E1). In this way, the carbon-free electricity produced by the gas turbine power generation unit 10 and the carbon-free electricity produced by the waste heat treatment unit 20 are supplied to land using the hydrogen fuel produced by the hydrogen production unit 600, thereby reducing greenhouse gas emissions. Occurrence can be minimized.

The second electricity supply unit 720 may connect the multi-fuel engine 200 and the on-board electricity demand source (E4) inside the facility main body 100. This second electricity supply unit 720 can supply low-carbon electricity (e) produced by the multi-fuel engine 200 to the shipboard electricity consumer (E4). In this way, by supplying low-carbon electricity produced by the multi-fuel engine 200 to the facility main body 100, the generation of greenhouse gases can be minimized.

Meanwhile, in the first embodiment shown in FIGS. 1 and 2, the waste heat treatment unit includes a steam turbine and a steam turbine generator, but a second embodiment in which the waste heat treatment unit includes a hot water generator is also possible.

Below, with reference to FIG. 3, the floating storage power generation facility according to the second embodiment of the present invention will be described in detail.

Figure 3 is a detailed diagram of a floating storage power generation facility according to a second embodiment of the present invention.

The second embodiment shown in FIG. 3 is substantially the same as the first embodiment shown in FIG. 2 except for the waste heat treatment unit 20, so repeated descriptions will be omitted.

As shown in Figure 3, the floating storage power generation facility according to the second embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a hydrogen production unit (600), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a hot water generator 24, and a nitrogen oxide reduction device 25.

The hot water generator 24 may generate hot water using the waste heat recovered from the waste heat recovery unit 21. Hot water generated in the hot water generator 24 may be supplied to hot water consumers.

Meanwhile, in the first embodiment shown in FIGS. 1 and 2, the hydrogen production unit 600, the gas turbine power generation unit 10, and the waste heat treatment unit 20 are installed in the facility main body 100, but the hydrogen production unit 600 ), a third embodiment in which the gas turbine power generation unit 10 and the waste heat treatment unit 20 are installed on land (E) is also possible.

Below, with reference to FIG. 4, the floating storage power generation facility according to the third embodiment of the present invention will be described in detail.

Figure 4 is a detailed diagram of a floating storage power generation facility according to a third embodiment of the present invention.

The third embodiment shown in FIG. 4 is substantially the same as the first embodiment shown in FIG. 2 except for the hydrogen production unit 600, the gas turbine power generation unit 10, and the waste heat treatment unit 20. Any necessary explanations are omitted.

As shown in FIG. 4, the floating storage power generation facility according to the third embodiment of the present invention includes a facility body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a hydrogen production unit (600), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The hydrogen production unit 600 may include a connection pipe 610, an ammonia decomposition unit 620, a hydrogen separation unit 630, and an ammonia heat exchanger 640. The hydrogen production unit 600 is installed on land (E) and can easily supply hydrogen fuel 3 to the gas turbine power generation unit 10 installed on land (E).

The connection pipe 610 may connect the ammonia deck tank 920 and the gas turbine power generation unit 10.

The ammonia decomposition unit 620 is installed on the connection pipe 610 and can produce hydrogen fuel (3) by decomposing the ammonia fuel (2).

The ammonia decomposition unit 620 can pyrolyze and reform the liquid ammonia fuel 2 stored in the ammonia deck tank 920. That is, the ammonia decomposition unit 620 can decompose the ammonia fuel 2 into hydrogen (H ₂ ) and nitrogen (N ₂ ) through thermal decomposition (cracking reformer). At this time, undecomposed ammonia (NH ₃ ) may be generated.

Additionally, the ammonia decomposition unit 620 may include an ammonia decomposition catalyst to enable ammonia reforming at a lower temperature. The ammonia decomposition catalyst is not particularly limited as long as it has catalytic activity in the ammonia decomposition reaction, but examples include catalysts containing non-metallic transition metals, rare earth materials, and noble metal materials as a composition, and the above-mentioned catalysts have a high It can be used by supporting it on a carrier with a specific surface area.

The hydrogen separation unit 630 may separate the hydrogen fuel 3 from the hydrogen (H ₂ ) and nitrogen (N ₂ ) decomposed in the ammonia decomposition unit 620.

Although not shown, the nitrogen separated from the hydrogen separation unit 630 may be stored in a separate storage tank and then supplied to a necessary consumer or discharged into the atmosphere. Additionally, undecomposed ammonia may be re-supplied to the ammonia decomposition unit 620.

The ammonia heat exchanger 640 can vaporize the ammonia fuel 2 in a liquid state to generate ammonia gas fuel 7 in a gaseous state. This ammonia heat exchanger 640 may be a shell and tube type heat exchanger. However, it is not necessarily limited to this, and heat exchangers of various structures are possible.

In this way, by producing hydrogen fuel 3 using the hydrogen production unit 600 and stably supplying and generating power to the gas turbine power generation unit 10, greenhouse gases can be reduced in accordance with international exhaust gas emission regulation standards.

The gas turbine power generation unit 10 may generate power using LNG fuel (1), ammonia fuel (2), hydrogen fuel (3), and/or natural gas fuel (4). The gas turbine power generation unit 10 may be installed on land (E).

The gas turbine power generation unit 10 may include a compressor 11, a combustor 12, a gas turbine 13, a gas turbine generator 14, a third heater 15, and an ammonia land tank 16. .

The compressor 11 may generate compressed air by compressing external air.

The combustor 12 can combust ammonia fuel 2, hydrogen fuel 3, and/or natural gas fuel 4 and supply compressed air to produce high-temperature and high-pressure hydrogen co-combustion gas containing hydrogen. . The combustor 12 may be connected to the ammonia deck tank 920 through a connecting pipe 610.

The gas turbine 13 may be a heat engine driven using high temperature and high pressure hydrogen co-combustion gas.

The gas turbine generator 14 can generate power using the driving force of the gas turbine 13. Carbon-free electricity (e) produced by the gas turbine generator 14 can be supplied to onshore electricity demand (E1) on land (E).

The ammonia land tank 16 is connected to the ammonia deck tank 920 and can be installed on land (E). The ammonia land tank 16 can store liquid ammonia fuel.

The third heater 15 can heat and vaporize the ammonia fuel 2 supplied from the ammonia land tank 16. Gaseous ammonia fuel (2) can be supplied to the combustor (12).

In this way, carbon-free electricity is produced in the gas turbine power generation unit 10 using hydrogen fuel produced in the hydrogen production unit 600, and this carbon-free electricity is supplied to land, thereby minimizing the generation of greenhouse gases. .

The waste heat treatment unit 20 may process waste heat generated in the gas turbine power generation unit 10. The waste heat treatment unit 20 may be installed on land (E).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a steam turbine 22, a steam turbine generator 23, and a nitrogen oxide reduction device 25.

The waste heat recovery unit 21 can recover waste heat generated in the gas turbine power generation unit 10. Specifically, the extremely high temperature exhaust gas of 650 degrees or higher generated from the gas turbine 13 is heat exchanged in the ammonia heat exchanger 640 to become high temperature exhaust gas, and this high temperature exhaust gas can be recovered to the waste heat recovery unit 21. there is.

The steam turbine 22 may be a heat engine that generates and drives steam using waste heat.

The steam turbine generator 23 can generate power using the driving force of the steam turbine 22. Carbon-free electricity (e) produced by the steam turbine generator 23 can be supplied to onshore electricity demand (E1) on land (E).

The nitrogen oxide reduction device 25 is connected to the waste heat recovery unit 21 and can treat nitrogen oxides discharged from the waste heat recovery unit 21. This nitrogen oxide reduction device may include a selective catalytic reduction (SCR) device. Although not shown, it is connected to the ammonia land tank 16 and the ammonia fuel 20 from the ammonia land tank 16 can be used as a catalyst.

Meanwhile, although not shown, the nitrogen oxide reduction device 25 is also connected to the multi-fuel engine 200, or is provided with a separate nitrogen oxide reduction device to treat nitrogen oxides emitted from the multi-fuel engine 200. , Although not shown, it is connected to the ammonia deck tank 920 and the ammonia fuel 2 from the ammonia deck tank 920 can be used as a catalyst. Therefore, greenhouse gas (GHC) can be minimized.

Meanwhile, in the third embodiment shown in FIG. 4, the waste heat treatment unit 20 includes a steam turbine 22 and a steam turbine generator 23, but the waste heat treatment unit 20 includes a hot water generator 24. A fourth embodiment is also possible.

Below, with reference to FIG. 5, the floating storage power generation facility according to the fourth embodiment of the present invention will be described in detail.

Figure 5 is a detailed diagram of a floating storage power generation facility according to a fourth embodiment of the present invention.

The fourth embodiment shown in FIG. 5 is substantially the same as the third embodiment shown in FIG. 4 except for the waste heat treatment unit 20, so repeated descriptions will be omitted.

As shown in Figure 5, the floating storage power generation facility according to the fourth embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a hydrogen production unit (600), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a hot water generator 24, and a nitrogen oxide reduction device 25.

The hot water generator 24 may generate hot water using the waste heat recovered from the waste heat recovery unit 21. Hot water generated in the hot water generator 24 may be supplied to hot water consumers.

Meanwhile, in the first embodiment shown in FIGS. 1 and 2, the hydrogen production unit 600 is installed in the facility main body 100, but in the fifth embodiment in which the hydrogen production unit 600 is not installed in the facility main body 100. possible.

Below, with reference to FIG. 6, the floating storage power generation facility according to the fifth embodiment of the present invention will be described in detail.

Figure 6 is a detailed diagram of a floating storage power generation facility according to the fifth embodiment of the present invention.

The fifth embodiment shown in FIG. 6 is substantially the same as the first embodiment shown in FIG. 2 except for the hydrogen production unit 600 and the gas turbine power generation unit 10, so repeated descriptions will be omitted.

As shown in FIG. 6, the floating storage power generation facility according to the fifth embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The ammonia transport unit 900 may include an ammonia storage pipe 910, an ammonia deck tank 920, an ammonia compressor 940, and an ammonia meter 950.

The ammonia storage pipe 910 connects the ammonia storage tank 510 and the ammonia consumer (E3) and may provide a path for transferring the ammonia fuel (2).

The ammonia deck tank 920 is installed on the deck of the facility main body 100 and may be connected to the ammonia storage pipe 910. Ammonia deck tank 920 can store ammonia fuel 2.

The ammonia compressor 940 may compress the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and store it in the ammonia deck tank 920.

The ammonia meter 950 can measure the ammonia fuel (2) stored in the ammonia deck tank 920 and supply it to the ammonia demand source (E3) on land (E).

The gas turbine power generation unit 10 may generate power using ammonia fuel 2 and/or natural gas fuel 4. The gas turbine power generation unit 10 may be installed in the facility main body 100 floating on the sea (S).

The gas turbine power generation unit 10 may include a compressor 11, a combustor 12, a gas turbine 13, a gas turbine generator 14, and a third heater 15.

The compressor 11 may generate compressed air by compressing external air.

The combustor 12 may combust the ammonia fuel 2 and/or the natural gas fuel 4 and supply compressed air to produce high-temperature and high-pressure co-combustion gas containing ammonia and/or natural gas.

The gas turbine 13 may be a heat engine driven using high-temperature and high-pressure co-fired gas.

The gas turbine generator 14 can generate power using the driving force of the gas turbine 13. Carbon-free electricity (e) produced by the gas turbine generator 14 can be supplied to onshore electricity demand (E1) on land (E).

In this way, carbon-free electricity is produced in the gas turbine power generation unit 10 using ammonia fuel 2 and/or natural gas fuel 4, and this carbon-free electricity is supplied to land, thereby generating greenhouse gases. can be minimized.

The waste heat treatment unit 20 may process waste heat generated in the gas turbine power generation unit 10. The waste heat treatment unit 20 may be installed in the facility main body 100 floating in the sea (S).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a steam turbine 22, a steam turbine generator 23, and a nitrogen oxide reduction device 25.

The waste heat recovery unit 21 can recover waste heat generated in the gas turbine power generation unit 10. Specifically, extremely high temperature exhaust gas of 650 degrees or higher generated from the gas turbine 13 can be recovered by the waste heat recovery unit 21.

The steam turbine 22 may be a heat engine that generates and drives steam using waste heat.

The steam turbine generator 23 can generate power using the driving force of the steam turbine 22. Carbon-free electricity (e) produced by the steam turbine generator 23 can be supplied to onshore electricity demand (E1) on land (E).

The nitrogen oxide reduction device 25 is connected to the waste heat recovery unit 21 and the ammonia deck tank 920, and utilizes the ammonia fuel 2 from the ammonia deck tank 920 to discharge the waste heat recovery unit 21. Nitrogen oxides can be treated. This nitrogen oxide reduction device 25 may include a selective catalytic reduction (SCR) device, and in this case, ammonia fuel 2 may be used as a catalyst.

Since the ammonia fuel 2 may generate nitrogen oxides depending on combustion conditions, the nitrogen oxide reduction device can remove nitrogen oxides discharged from the waste heat recovery unit 21 and discharge them as exhaust gas.

Meanwhile, although not shown, the nitrogen oxide reduction device 25 is connected to the multi-fuel engine 200, or a separate nitrogen oxide reduction device is provided to treat nitrogen oxides emitted from the multi-fuel engine 200. . Therefore, greenhouse gas (GHC) can be minimized.

Meanwhile, in the fifth embodiment shown in FIG. 6, the waste heat treatment unit 20 includes a steam turbine 22 and a steam turbine generator 23, but the waste heat treatment unit 20 includes a hot water generator 24. A sixth embodiment is also possible.

Below, with reference to FIG. 7, the floating storage power generation facility according to the sixth embodiment of the present invention will be described in detail.

Figure 7 is a detailed diagram of a floating storage power generation facility according to the sixth embodiment of the present invention.

The sixth embodiment shown in FIG. 7 is substantially the same as the fifth embodiment shown in FIG. 6 except for the waste heat treatment unit 20, so repeated descriptions will be omitted.

As shown in FIG. 7, the floating storage power generation facility according to the sixth embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a hot water generator 24, and a nitrogen oxide reduction device 25.

The hot water generator 24 may generate hot water using the waste heat recovered from the waste heat recovery unit 21. Hot water generated in the hot water generator 24 may be supplied to hot water consumers.

Meanwhile, in the fifth embodiment shown in FIG. 6, the gas turbine power generation unit 10 and the waste heat treatment unit 20 are installed in the facility main body 100, but the gas turbine power generation unit 10 and the waste heat treatment unit 20 are A seventh embodiment installed on land (E) is also possible.

Below, with reference to FIG. 8, the floating storage power generation facility according to the seventh embodiment of the present invention will be described in detail.

Figure 8 is a detailed diagram of a floating storage power generation facility according to the seventh embodiment of the present invention.

The seventh embodiment shown in FIG. 8 is substantially the same as the fifth embodiment shown in FIG. 6 except for the gas turbine power generation unit 10 and the waste heat treatment unit 20, so repeated descriptions will be omitted.

As shown in FIG. 8, the floating storage power generation facility according to the seventh embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The gas turbine power generation unit 10 can generate power using natural gas fuel 4 and ammonia fuel 2. The gas turbine power generation unit 10 may be installed on land (E).

The gas turbine power generation unit 10 may include a compressor 11, a combustor 12, a gas turbine 13, a gas turbine generator 14, a third heater 15, and an ammonia land tank 16. .

The compressor 11 may generate compressed air by compressing external air.

The combustor 12 may combust the ammonia fuel 2 and/or the natural gas fuel 4 and supply compressed air to produce high-temperature and high-pressure co-combustion gas containing ammonia and/or natural gas.

The gas turbine 13 may be a heat engine driven using high-temperature and high-pressure co-fired gas.

The gas turbine generator 14 can generate power using the driving force of the gas turbine 13. Carbon-free electricity (e) produced by the gas turbine generator 14 can be supplied to onshore electricity demand (E1) on land (E).

The ammonia land tank 16 is connected to the ammonia deck tank 920 and can be installed on land (E). The ammonia land tank 16 can store liquid ammonia fuel.

The third heater 15 can heat and vaporize the ammonia fuel 2 supplied from the ammonia land tank 16. The third heater 15 can supply gaseous ammonia fuel 2 to the combustor 12.

In this way, carbon-free electricity is produced in the gas turbine power generation unit 10 using ammonia fuel 2 and/or natural gas fuel 4, and this carbon-free electricity is supplied to land, thereby generating greenhouse gases. can be minimized.

The waste heat treatment unit 20 may process waste heat generated in the gas turbine power generation unit 10. The waste heat treatment unit 20 may be installed on land (E).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a steam turbine 22, a steam turbine generator 23, and a nitrogen oxide reduction device 25.

The waste heat recovery unit 21 can recover waste heat generated in the gas turbine power generation unit 10. Specifically, extremely high temperature exhaust gas of 650 degrees or higher generated from the gas turbine 13 can be recovered by the waste heat recovery unit 21.

The steam turbine 22 may be a heat engine that generates and drives steam using waste heat.

The steam turbine generator 23 can generate power using the driving force of the steam turbine 22. Carbon-free electricity (e) produced by the steam turbine generator 23 can be supplied to onshore electricity demand (E1) on land (E).

The nitrogen oxide reduction device 25 is connected to the waste heat recovery unit 21 and can treat nitrogen oxides discharged from the waste heat recovery unit 21. This nitrogen oxide reduction device may include a selective catalytic reduction (SCR) device. Although not shown, it is connected to the ammonia land tank 16 and the ammonia fuel 20 from the ammonia land tank 16 can be used as a catalyst.

Meanwhile, although not shown, the nitrogen oxide reduction device 25 is also connected to the multi-fuel engine 200, or is provided with a separate nitrogen oxide reduction device to treat nitrogen oxides emitted from the multi-fuel engine 200. , Although not shown, it is connected to the ammonia deck tank 920 and the ammonia fuel 2 from the ammonia deck tank 920 can be used as a catalyst. Therefore, greenhouse gas (GHC) can be minimized.

Meanwhile, in the seventh embodiment shown in FIG. 8, the waste heat treatment unit 20 includes a steam turbine 22 and a steam turbine generator 23, but the waste heat treatment unit 20 includes a hot water generator 24. An eighth embodiment is also possible.

Below, with reference to FIG. 9, the floating storage power generation facility according to the eighth embodiment of the present invention will be described in detail.

Figure 9 is a detailed diagram of a floating storage power generation facility according to the eighth embodiment of the present invention.

The eighth embodiment shown in FIG. 9 is substantially the same as the seventh embodiment shown in FIG. 8 except for the waste heat treatment unit 20, so repeated descriptions will be omitted.

As shown in Figure 9, the floating storage power generation facility according to the eighth embodiment of the present invention includes a facility main body 100, a multi-fuel engine 200, a regasification unit 300, an LNG supply unit 400, and an ammonia supply unit. It includes (500), a hydrogen production unit (600), a gas turbine power generation unit (10), a waste heat treatment unit (20), an electricity supply unit (700), a diesel supply unit (800), and an ammonia transfer unit (900).

The waste heat treatment unit 20 may include a waste heat recovery unit 21, a hot water generator 24, and a nitrogen oxide reduction device 25.

The hot water generator 24 may generate hot water using the waste heat recovered from the waste heat recovery unit 21. Hot water generated in the hot water generator 24 may be supplied to hot water consumers.

Above, the present invention has been described with reference to the embodiments shown in the drawings. However, the present invention is not limited thereto, and various modifications or other embodiments within the scope equivalent to the present invention can be made by those skilled in the art. Therefore, the true scope of protection of the present invention will be determined by the following claims.

10: Gas turbine power generation unit 20: Waste heat treatment unit
100: Equipment body 200: Multi-fuel engine
300: Regasification unit 400: LNG supply unit
500: Ammonia supply department 600: Hydrogen production department
700: Electricity supply unit 800: Diesel supply unit
900: Ammonia transfer unit

Claims (33)

A facility body (100) capable of floating;
A multi-fuel engine (200) installed in the facility body (100) and capable of burning LNG fuel (1) or ammonia fuel (2);
A regasification unit 300 installed in the facility body 100 and vaporizing the LNG fuel 1 into natural gas fuel 4;
An LNG supply unit 400 installed in the facility body 100 and supplying the LNG fuel 1 to the multi-fuel engine 200;
An ammonia supply unit 500 installed in the facility main body 100 and supplying the ammonia fuel 2 to the multi-fuel engine 200;
A hydrogen production unit 600 installed in the facility main body 100 and producing hydrogen fuel 3 by decomposing the ammonia fuel 2; and
It is installed in the facility main body 100 and includes a gas turbine power generation unit 10 that generates power using the hydrogen fuel 3,
Floating storage power plant. According to claim 1,
It is installed in the facility main body 100 and further includes a waste heat treatment unit 20 that processes waste heat generated in the gas turbine power generation unit 10,
Floating storage power plant. According to claim 2,
The gas turbine power generation unit 10 includes a combustor 12,
The combustor 12 combusts any one or more of the hydrogen fuel 3, the natural gas fuel 4, and the ammonia fuel 2 to generate high temperature and high pressure hydrogen co-combustion gas,
Floating storage power plant. According to claim 3,
The gas turbine power generation unit 10,
Compressor (11) producing compressed air,
The combustor 12 that supplies the compressed air to generate the high-temperature and high-pressure hydrogen co-combustion gas,
A gas turbine 13 driven using the hydrogen co-combustion gas, and
Further comprising a gas turbine generator 14 that generates power using the driving force of the gas turbine 13,
Floating storage power plant. According to claim 4,
The waste heat treatment unit 20,
A waste heat recovery unit (21) that recovers the waste heat generated in the gas turbine power generation unit (10),
A steam turbine 22 that generates and drives steam using the waste heat, and
Including a steam turbine generator 23 that generates power using the driving force of the steam turbine 22,
Floating storage power plant. According to claim 4,
The waste heat treatment unit 20,
A waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, and
Comprising a hot water generator 24 that generates hot water using the waste heat,
Floating storage power plant. According to claim 3,
Further comprising an ammonia transfer unit 900 that transfers the ammonia fuel (2) to the ammonia demand source (E3) on land,
Floating storage power plant. According to claim 7,
The ammonia supply unit 500,
It includes an ammonia storage tank 510 for storing the ammonia fuel 2,
The ammonia transport unit 900,
An ammonia storage pipe 910 that connects the ammonia storage tank 510 and the ammonia consumer (E3) and transports the ammonia fuel (2), and
Comprising an ammonia deck tank 920 connected to the ammonia storage pipe 910 and storing the ammonia fuel 2,
Floating storage power plant. According to claim 8,
The ammonia transport unit 900,
An ammonia compressor 940 that compresses the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and stores it in the ammonia deck tank 920, and
Further comprising an ammonia meter 950 that measures the ammonia fuel (2) stored in the ammonia deck tank 920 and supplies it to the ammonia demand source (E3),
Floating storage power plant. According to claim 8,
The ammonia supply unit 500,
An ammonia supply pipe 520 that connects the ammonia storage tank 510 and the multi-fuel engine 200 and transports the ammonia fuel 2, and
Further comprising a reliquefaction device 530 that reliquefies the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and transfers it to the ammonia storage tank 510.
Floating storage power plant. According to claim 8,
The hydrogen production unit 600,
A connecting pipe 610 connecting the ammonia deck tank 920 and the combustor 12,
An ammonia decomposition unit 620 that is installed on the connection pipe 610 and decomposes the ammonia fuel 2 to produce the hydrogen fuel 3,
A hydrogen separation unit 630 that separates the hydrogen fuel 3 from the ammonia decomposition unit 620,
An ammonia heat exchanger 640 installed on the connection pipe 610 and vaporizing the ammonia fuel 2 using the waste heat generated in the gas turbine power generation unit 10 to produce ammonia gas fuel 7, and
It includes a fourth heater 650 that heats the ammonia fuel 2 supplied from the ammonia deck tank 920 and supplies it to the combustor 12,
The hydrogen fuel 3 separated in the hydrogen separation unit 630 is supplied to the combustor 12,
Floating storage power plant. According to claim 10,
The LNG supply unit 400,
An LNG storage tank (410) storing the LNG fuel (1),
A first heater 420 that vaporizes the LNG fuel 1 and supplies the natural gas fuel 5 to the multi-fuel engine 200, and
It includes an LNG pipe 430 that connects the LNG storage tank 410 and the first heater 420 and transports the LNG fuel 1,
The reliquefaction unit 530 is installed on the LNG pipe 430,
Floating storage power plant. According to claim 12,
The LNG supply unit 400,
Further comprising a natural gas pipe 440 connecting the first heater 420 and the multi-fuel engine 200 and transporting the natural gas fuel 5,
Floating storage power plant. According to claim 2,
A first electricity supply unit 710 connects the gas turbine power generation unit 10 and the onshore electricity demand source (E1), and supplies electricity produced by the gas turbine power generation unit 10 to the land electricity demand source (E1). ), which further includes
Floating storage power plant. According to claim 14,
A second electric generator connects the multi-fuel engine 200 and the on-board electricity consumer (E4) of the equipment main body 100, and supplies electricity produced by the multi-fuel engine 200 to the on-board electricity consumer (E4). Further comprising a supply unit 720,
Floating storage power plant. According to claim 2,
It further includes a diesel supply unit 800 that supplies diesel fuel 6 to the multi-fuel engine 200,
The multi-fuel engine 200 is an engine capable of burning the LNG fuel (1), the ammonia fuel (2), or the diesel fuel (6),
The diesel supply unit 800,
A diesel storage tank 810 installed in the facility main body 100 and storing the diesel fuel 6, and
Further comprising a diesel pipe 820 that transfers the diesel fuel 6 from the diesel storage tank 810 to the multi-fuel engine 200,
Floating storage power plant. A facility body (100) capable of floating;
A multi-fuel engine (200) installed in the facility body (100) and capable of burning LNG fuel (1) or ammonia fuel (2);
A regasification unit 300 installed in the facility body 100 and vaporizing the LNG fuel 1 into natural gas fuel 4;
An LNG supply unit 400 installed in the facility body 100 and supplying the LNG fuel 1 to the multi-fuel engine 200;
An ammonia supply unit 500 installed in the facility main body 100 and supplying the ammonia fuel 2 to the multi-fuel engine 200;
A hydrogen production unit (600) installed on land (E), which decomposes the ammonia fuel (2) to produce hydrogen fuel (3); and
Installed on land (E) and comprising a gas turbine power generation unit (10) that generates power using the hydrogen fuel (3),
Floating storage power plant. According to claim 17,
Installed on land (E), further comprising a waste heat treatment unit 20 that processes waste heat generated in the gas turbine power generation unit 10,
Floating storage power plant. According to claim 18,
The gas turbine power generation unit 10 includes a combustor 12,
The combustor 12 combusts any one or more of the hydrogen fuel 3, the natural gas fuel 4, and the ammonia fuel 2 to generate high temperature and high pressure hydrogen co-combustion gas,
Floating storage power plant. According to claim 19,
The gas turbine power generation unit 10,
Compressor (11) producing compressed air,
The combustor 12 that supplies the compressed air to generate the high-temperature and high-pressure hydrogen co-combustion gas,
A gas turbine 13 driven using the hydrogen co-combustion gas, and
Further comprising a gas turbine generator 14 that generates power using the driving force of the gas turbine 13,
Floating storage power plant. According to claim 20,
The waste heat treatment unit 20,
A waste heat recovery unit (21) that recovers the waste heat generated in the gas turbine power generation unit (10),
A steam turbine 22 that generates steam using the waste heat and generates power, and
Including a steam turbine generator 23 that generates power using the driving force of the steam turbine 22,
Floating storage power plant. According to claim 20,
The waste heat treatment unit 20,
A waste heat recovery unit 21 that recovers the waste heat generated in the gas turbine power generation unit 10, and
Comprising a hot water generator 24 that generates hot water using the waste heat,
Floating storage power plant. According to claim 19,
Further comprising an ammonia transfer unit 900 that transfers the ammonia fuel (2) to the ammonia demand source (E3) on land (E),
Floating storage power plant. According to claim 23,
The ammonia supply unit 500,
It includes an ammonia storage tank 510 for storing the ammonia fuel 2,
The ammonia transport unit 900,
An ammonia storage pipe 910 that connects the ammonia storage tank 510 and the ammonia consumer (E3) and transports the ammonia fuel (2), and
Comprising an ammonia deck tank 920 connected to the ammonia storage pipe 910 and storing the ammonia fuel 2,
Floating storage power plant. According to claim 24,
The gas turbine power generation unit 10,
An ammonia land tank (16) connected to the ammonia deck tank (920) and installed on land (E), and
It further includes a third heater (15) that vaporizes the ammonia fuel (2) supplied from the ammonia land tank (16),
The ammonia fuel 2 vaporized in the third heater 15 is supplied to the combustor 12,
Floating storage power plant. According to claim 24,
The ammonia transport unit 900,
An ammonia compressor 940 that compresses the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and stores it in the ammonia deck tank 920, and
Further comprising an ammonia meter 950 that measures the ammonia fuel (2) stored in the ammonia deck tank 920 and supplies it to the ammonia demand source (E3),
Floating storage power plant. According to claim 24,
The ammonia supply unit 500,
An ammonia supply pipe 520 that connects the ammonia storage tank 510 and the multi-fuel engine 200 and transports the ammonia fuel 2, and
Further comprising a reliquefaction device 530 that reliquefies the ammonia boil-off gas (B2) generated in the ammonia storage tank 510 and transfers it to the ammonia storage tank 510.
Floating storage power plant. According to claim 24,
The hydrogen production unit 600,
A connecting pipe 610 connecting the ammonia deck tank 920 and the combustor 12,
An ammonia decomposition unit 620 that is installed on the connection pipe 610 and decomposes the ammonia fuel 2 to produce the hydrogen fuel 3,
A hydrogen separation unit 630 that separates the hydrogen fuel 3 from the ammonia decomposition unit 620, and
An ammonia heat exchanger 640 is installed on the connection pipe 610 and vaporizes the ammonia fuel 2 using the waste heat generated in the gas turbine power generation unit 10 to produce ammonia gas fuel 7. Contains,
The hydrogen fuel 3 separated in the hydrogen separation unit 630 is supplied to the combustor 12,
Floating storage power plant. According to clause 27,
The LNG supply unit 400,
An LNG storage tank (410) storing the LNG fuel (1),
A first heater 420 that vaporizes the LNG fuel 1 and supplies the natural gas fuel 5 to the multi-fuel engine 200, and
It includes an LNG pipe 430 that connects the LNG storage tank 410 and the first heater 420 and transports the LNG fuel 1,
The reliquefaction unit 530 is installed on the LNG pipe 430,
Floating storage power plant. According to clause 29,
The LNG supply unit 400,
Further comprising a natural gas pipe 440 connecting the first heater 420 and the multi-fuel engine 200 and transporting the natural gas fuel 5,
Floating storage power plant. According to claim 18,
A first device that connects the gas turbine power generation unit 10 and the land-based electricity demand source (E1) on land (E) and supplies electricity produced by the gas turbine power generation unit 10 to the land-based electricity demand source (E1). Further comprising an electricity supply unit 710,
Floating storage power plant. According to claim 31,
A second electric generator connects the multi-fuel engine 200 and the on-board electricity consumer (E4) of the equipment main body 100, and supplies electricity produced by the multi-fuel engine 200 to the on-board electricity consumer (E4). Further comprising a supply unit 720,
Floating storage power plant. According to claim 18,
It further includes a diesel supply unit 800 that supplies diesel fuel 6 to the multi-fuel engine 200,
The multi-fuel engine 200 is an engine capable of burning the LNG fuel (1), the ammonia fuel (2), or the diesel fuel (6),
The diesel supply unit 800,
A diesel storage tank 810 installed in the facility main body 100 and storing the diesel fuel 6, and
Further comprising a diesel pipe 820 that transfers the diesel fuel 6 from the diesel storage tank 810 to the multi-fuel engine 200,
Floating storage power plant.