KR20210045330A - Bunkering Vessel - Google Patents

Abstract

The present invention is a bunkering vessel for loading and unloading liquefied gas to a liquefied gas storage tank of a bunkering target, comprising: a bunkering tank for storing liquefied gas; a manifold communicating the bunkering vessel and the bunkering target to flow liquefied gas; and a buffer tank for receiving and storing liquefied gas from the bunkering tank and the manifold. When the liquefied gas stored in the bunkering tank is loaded into the liquefied gas storage tank, the buffer tank receives boil-off gas generated in the bunkering tank and liquefied gas discharged from the liquefied gas storage tank and condenses and stores at least a portion of the same.

Description

Bunkering Vessel

The present invention relates to a bunkering ship and a method of operating a bunkering ship.

As environmental regulations have recently been strengthened, the use of liquefied natural gas, which is close to eco-friendly fuels, among various fuels is increasing. Liquefied natural gas is generally transported through an LNG carrier, and in this case, the liquefied natural gas can be stored in a tank of an LNG carrier in a liquid state by lowering the temperature to -162°C or less under 1 atmosphere. When the liquefied natural gas becomes a liquid state, the volume of the gaseous state is reduced to one-600th, so that the transport efficiency can be increased.

Terminals can be used when the distance from the place of production of liquefied natural gas to the place of consumption is long, and bunkering ships can receive liquefied natural gas from a liquefied gas supplier such as a terminal and transport liquefied natural gas or redistribute it to ships that use it as fuel. have. Unlike the conventional bunkering process of diesel fuel, when the liquefied natural gas is loaded or unloaded, the liquefied natural gas must be maintained in a cryogenic state. However, even though the liquefied natural gas is treated at cryogenic temperatures, a large amount of evaporated gas may be generated during loading or unloading of the liquefied natural gas. Therefore, in order to stably store the liquefied natural gas, the storage tank in which the liquefied natural gas is stored is required. Temperature and pressure must be controlled.

Recently, the bunkering technology to maintain the liquefied natural gas in a liquid state and supply it to the liquefied natural gas carrier or propulsion ship, and continuous research and development of ships using the same, and higher bunkering efficiency and evaporative gas generated during the bunkering process. Research is being conducted on the treatment plan of

An object of the present invention is to provide a bunkering vessel capable of loading and unloading liquefied gas into a liquefied gas storage tank to be bunkered.

In addition, it is an object of the present invention to provide a bunkering vessel capable of processing boil-off gas generated from a bunkering target and boil-off gas generated from a bunkering vessel using a buffer tank.

One aspect of the present invention is a bunkering vessel for loading and unloading liquefied gas into a liquefied gas storage tank to be bunkered, a bunkering tank storing liquefied gas, and communicating the bunkering vessel with the bunkering target to flow liquefied gas A manifold, and the bunkering tank and a buffer tank receiving and storing liquefied gas from the manifold, wherein the buffer tank is, when loading the liquefied gas stored in the bunkering tank into the liquefied gas storage tank, the bunkering The boil-off gas generated in the tank and the liquefied gas discharged from the liquefied gas storage tank may be supplied and stored by condensing at least a portion of the liquefied gas.

Specifically, the bunkering ship includes a power generation engine that uses liquefied gas as a fuel to generate electric power, a liquid transfer line that connects the bunkering tank and the manifold to flow liquid liquefied gas, and the bunkering tank and the manifold. A gaseous-phase transfer line for flowing gaseous liquefied gas by connecting to, a gas processing line for supplying liquefied gas to the power generation engine by branching from the gaseous-phase transfer line, and supplying liquefied gas to the buffer tank by branching from the gas processing line It may further include a condensation line.

Specifically, the gas processing line comprises a gas-liquid separator for separating the liquefied gas into a gaseous phase and a liquid phase and returning the liquid liquefied gas to the bunkering tank, and a gaseous liquefied gas supplied from the gas-liquid separator and pressurized to the power generation engine. And a supplying LD compressor, and the condensation line may branch from the lower end of the LD compressor in the gas treatment line.

Specifically, the buffer tank may be a state in which liquid liquefied gas is stored in an internal space, and receives and stores boil-off gas generated in the bunkering tank and liquefied gas discharged from the liquefied gas storage tank.

Specifically, the buffer tank stores liquid liquefied gas at a water level of 40 to 80% with respect to the height of the inner space of the buffer tank, and the condensation line includes liquefied gas into the liquid liquefied gas stored in the buffer tank. It may be to inject.

Specifically, the bunkering vessel may further include a boil-off gas supply line for supplying boil-off gas generated in the buffer tank to the gas-liquid separator.

Specifically, when the internal pressure of the buffer tank is higher than a predetermined value, the bunkering ship may supply gaseous liquefied gas to at least one of a power generation engine and a gas combustion unit through the boil-off gas supply line.

Specifically, the bunkering vessel may return the liquid liquefied gas stored in the buffer tank to the bunkering tank when the loading of the liquefied gas storage tank is completed.

Specifically, the bunkering vessel may return the liquid liquefied gas stored in the buffer tank to the bunkering tank when the liquid liquefied gas level with respect to the height of the inner space of the buffer tank is higher than 80%.

Specifically, the bunkering ship supplies liquid liquefied gas stored in the buffer tank to the gas-liquid separator, so that the separated liquid liquefied gas is returned to the bunkering tank, and the separated gaseous liquefied gas is supplied from the LD compressor. It may be pressurized and supplied to the power generation engine.

The bunkering ship according to the present invention can load and unload cryogenic liquefied gas into a liquefied gas storage tank for bunkering.

In addition, the bunkering ship according to the present invention can minimize waste of liquefied gas by processing the boil-off gas generated in the bunkering tank by itself or using it as fuel for the bunkering ship.

In addition, the bunkering vessel according to the present invention controls the internal environment of the liquefied gas storage tank to be bunkered to an environment suitable for liquefied gas loading before loading, thereby reducing the flow rate of the boil-off gas generated in the liquefied gas storage tank during bunkering. I can.

In addition, the bunkering ship according to the present invention receives the boil-off gas generated during loading and unloading into a buffer tank and condenses it to process it, thereby increasing the boil-off gas treatment capacity and the condensed boil-off gas can be reused as fuel for the bunkering ship. have.

In addition, the bunkering vessel according to the present invention can use the boil-off gas generated in each tank as fuel for the bunkering vessel while maintaining the internal pressure of the bunkering tank and the buffer tank within a safe range.

1 is a conceptual diagram of a bunkering system of a bunkering ship according to an embodiment of the present invention.
2 is a flow chart showing a method of operating a bunkering ship according to an embodiment of the present invention.
3 is a graph showing the level and internal pressure of liquid liquefied gas stored in the bunkering tank and the buffer tank when bunkering using a bunkering vessel having a buffer tank according to an embodiment of the present invention.
4 is a conceptual diagram showing a process of loading liquefied gas into a bunkering tank of a bunkering vessel according to an embodiment of the present invention.
5 is a conceptual diagram illustrating a process of treating boil-off gas generated from a bunkering tank and a buffer tank and a fuel supply process when a bunkering vessel is operated according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a process of receiving and processing boil-off gas inside the target liquefied gas storage tank when a bunkering ship according to an embodiment of the present invention is connected to a bunkering target.
7 is a conceptual diagram showing a process of performing gassing for a liquefied gas storage tank to be bunkered using a bunkering vessel according to an embodiment of the present invention.
FIG. 8 is a conceptual diagram illustrating a process of performing a cooling down on a liquefied gas storage tank to be bunkered using a bunkering vessel according to an embodiment of the present invention.
9 is a conceptual diagram showing a process of performing a cooling down on a liquefied gas storage tank to be bunkered using a bunkering vessel according to an embodiment of the present invention.
10 is a conceptual diagram illustrating a bunkering process of supplying liquefied gas to a liquefied gas storage tank to be bunkered using a bunkering vessel according to an embodiment of the present invention.
11 is a conceptual diagram showing a bunkering process of supplying liquefied gas to a liquefied gas storage tank to be bunkered using a bunkering vessel according to an embodiment of the present invention.
12 is a conceptual diagram illustrating a process of processing liquefied gas condensed in a buffer tank after a bunkering process in a bunkering vessel according to an embodiment of the present invention.
13 is a conceptual diagram illustrating a fuel supply process when a bunkering ship according to an embodiment of the present invention operates to a terminal after completing bunkering.
14 is a conceptual diagram showing a process of unloading liquefied gas stored in a bunkering vessel according to an embodiment of the present invention.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings. In adding reference numerals to elements of each drawing in the present specification, it should be noted that, even though they are indicated on different drawings, only the same elements are to have the same number as possible. In addition, in describing the present invention, when it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

Hereinafter, it is noted that high pressure (HP), low pressure (LP), high temperature and low temperature are relative, and do not represent absolute values, and can be used relatively according to each embodiment of the present invention.

Hereinafter, bunkering refers to loading that supplies liquefied gas from a bunkering ship to a target and unloading that a bunkering ship is supplied with by withdrawing liquefied gas from the target. A bunkering ship can receive liquefied gas from a liquefied gas supplier such as terminals, platforms, ports, and other bunkering ships, and load and unload it into the liquefied gas storage tank for bunkering, and use the stored liquefied gas as fuel. it means.

Hereinafter, that the bunkering ship is connected to the target means a state in which a manifold and a pipe are connected so that liquefied gas, boil-off gas, or other gas can communicate between the bunkering ship and the target.

Hereinafter, it is noted that the subject is used in the sense of encompassing all offshore plants such as FSRU and FPSO, in addition to a liquefied gas carrier that transports liquefied gas as cargo and a liquefied gas propulsion ship that can use liquefied gas as fuel. In addition, the target may mean other bunkering ships and liquefied gas transport vehicles having a liquefied gas storage tank. However, in a specific embodiment of the present invention, the target may be limited to any one or more of the above.

Hereinafter, the liquefied gas may be used in the sense of encompassing all gaseous fuels generally stored in a low temperature liquid state such as LNG, LPG, ethylene, ammonia, and the like. However, in the following embodiments and drawings, it will be described as an example that the liquefied gas is a liquefied natural gas.

Hereinafter, the boil off gas (BOG) is a liquefied gas that has been naturally vaporized or forcibly vaporized, and may mean a gaseous liquefied gas. However, the boil-off gas may be used to mean not only the boil-off gas in the gaseous state, but also the liquefied boil-off gas. In addition, hereinafter, it is noted that the liquefied gas may be used as a term encompassing all of a liquid state or a naturally vaporized or forcibly vaporized gas state.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram illustrating a bunkering system as an internal system of a bunkering ship according to an embodiment of the present invention.

1, the bunkering vessel is a bunkering tank 10, a manifold 20, a buffer tank 40, a liquid transfer line (L10), a vapor transfer line (L20), a fuel supply line (L30), a first And a gas processing line L40 and a second gas processing line L50. Hereinafter, although not shown, each line may include a valve for controlling a flow rate of a fluid flowing through the line.

The bunkering tank 10 may be a cargo tank of a bunkering ship as a storage tank for storing liquefied gas for loading and unloading into a target liquefied gas storage tank by being mounted inside a bunkering vessel. The bunkering tank 10 may be a membrane tank having a membrane-type insulating structure suitable for storing cryogenic liquefied gas. A plurality of bunkering tanks 10 may be provided inside the bunkering vessel. For example, the bunkering tank 10 may be provided side by side along the stern from the bow part of the ship, or may be provided side by side on the port side and starboard side of the ship, respectively.

The bunkering tank 10 may be connected to a manifold 20 to be described later to supply liquefied gas stored therein to a target through the manifold 20 or may receive liquefied gas from the target. The bunkering tank 10 may be connected to a liquid transfer line L10, a gaseous transfer line L20, and a spray line L13.

The liquid transfer line L10 has one end connected to the bunkering tank 10 and the other end connected to the manifold 20 to communicate liquid liquefied gas. The liquid transfer line L10 may be provided so that one end extends to the lower end of the bunkering tank 10 and is connected to the first pump 11, and the other end is connected to the liquid manifold 21 of the manifold 20. have. The bunkering ship uses the first pump 11 to withdraw the liquid liquefied gas stored in the bunkering tank 10, transfers it through the liquid transfer line L10, and supplies the liquefied gas to the target through the liquid manifold 21. I can.

Although not shown, the first pump 11 may be provided at the bottom of the pump tower disposed inside the bunkering tank 10, and may be installed to be immersed in the liquid liquefied gas stored in the bunkering tank 10. . The first pump 11 may be installed to be spaced apart from the inner bottom surface of the bunkering tank 10, and may be provided in plural.

The liquid transfer line L10 may further include a liquid return line L11 branched to be connected to the inside of the bunkering tank 10. A separate pump is not provided in the liquid return line L11. When loading a bunkering vessel, that is, when a liquid liquefied gas is loaded into the bunkering tank 10, a liquid liquefied gas is supplied through the liquid manifold 21 and transferred through the liquid transfer line L10, It can be stored in the bunkering tank 10 through the return line (L11).

The gas phase transfer line L20 is a line that has one end connected to the bunkering tank 10 and the other end connected to the manifold 20 to communicate gaseous liquefied gas. The gas phase transfer line L20 may be provided so that one end is connected to the upper end of the bunkering tank 10 and the other end is connected to the gas phase manifold 22 of the manifold 20. The boil-off gas generated from the liquid storage tank stored in the bunkering tank 10 may be withdrawn through the gas phase transfer line L20. For example, the bunkering ship supplies at least one of the liquefied gas stored in the bunkering tank 10 and the boil-off gas generated in the bunkering tank 10 to the power generation engine A, etc., but through a gas phase transfer line (L20). Boil-off gas can be supplied preferentially.

The spray line L13 has one end connected to the bunkering tank 10 and the other end connected to the manifold 20 to communicate liquid liquefied gas. The spray line L13 may be provided so that one end extends to the lower end of the bunkering tank 10 and is connected to the third pump 13, and the other end is connected to the liquid manifold 21 of the manifold 20. . The spray line L13 may be provided to transfer the liquefied gas with a lower flow rate compared to the liquid transfer line L10.

The third pump 13 is provided inside the bunkering tank 10 and may be disposed at a position relatively lower than the first pump 11. The first pump 11 can be used for loading and unloading of liquefied gas by processing a relatively large flow rate, and the third pump 13 remains in the bunkering tank 10 in a trace amount after the loading and unloading process. It may be for pumping out the liquefied gas. The third pump 13 may pump liquefied gas located at a low height that the first pump 11 cannot process. In addition, the third pump 13 may be used to transport the liquefied gas during gassing-up and cool-down processes that require a relatively low flow rate of liquefied gas supply compared to the first pump 11 throughout the bunkering process.

For example, the third pump 13 may be disposed inside a sump (not shown) formed on the bottom of the bunkering tank 10. The sump is provided in a puddle shape at the bottom of the bunkering tank 10, and after most of the liquefied gas is withdrawn from the bunkering tank 10, a small amount of liquefied gas may be provided to collect in the sump. The second pump 13 may withdraw the liquefied gas accumulated in the sump.

The spray line L13 may further include a spray return line L14 branched to be connected to the inside of the bunkering tank 10. The spray return line L14 returns at least a part of the liquefied gas flowing through the spray line L13 into the bunkering tank 10, but may be provided to inject the liquefied gas from the inner upper end of the bunkering tank 10. . The spray return line L14 may be used to lower the temperature inside the bunkering tank 10 by spraying at least a portion of the liquefied gas onto the boil-off gas generated inside the bunkering tank 10.

The fuel withdrawal line L12 is a line through which one end is connected to the bunkering tank 10 and the other end is connected to a first fuel supply line L30 to be described later to communicate liquid liquefied gas. One end of the fuel withdrawal line L12 may extend to a lower end of the bunkering tank 10 and may be connected to the second pump 12. The fuel withdrawal line (L12) withdraws part of the liquefied gas stored in the bunkering tank (10), and is used for demands such as the power generation engine (A), gas combustion unit (B), and auxiliary boiler (not shown) of the bunkering vessel. Can be supplied as fuel. The power generation engine (A) may be to generate power by using liquefied gas as fuel, and the generated power may be supplied to the propulsion of a bunkering ship or to a power demander within the ship. The gas combustion unit (B) may burn the gas handled in the ship using liquefied gas as fuel and discharge it to the outside of the bunkering ship. The auxiliary boiler can use liquefied gas as fuel to heat fresh water or sea water or generate steam.

The manifold 20 is provided at a bunkering station of a bunkering vessel and is connected to a liquid transfer line L10, a gaseous transfer line L20, a spray line L13, etc., so that liquefied gas can flow out and out of the bunkering vessel. The manifold 20 may include a liquid manifold 21 having one end connected to the liquid transfer line L10 and a gaseous manifold 22 having one end connected to the gaseous transfer line L20. The spray line L13 may also have one end connected to the liquid manifold 21. The other end of each manifold can communicate with the target through a separate pipe. The pipe is provided in the loading arm and is suitable for communicating liquefied gas at cryogenic temperatures, and may be connected to the manifold 20 by providing a cryogenic adapter, a cryogenic coupler, or the like. The bunkering ship is connected to the bunkering target through the manifold 20 to maintain a state in which liquefied gas can communicate.

Although not shown, the bunkering station may be equipped with an Emergency Shut-Down system (ESD) connected to the manifold 20, and monitor the temperature, pressure, and flow rate of the liquefied gas communicated through the manifold 20. A sensor for and a valve for controlling the flow rate of the liquefied gas may be provided. The bunkering station may be provided at the top of the bunkering tank 10 in the bunkering ship. For example, the bunkering station may be disposed above or below the upper deck, and the bunkering tank 10 may be disposed between the bottom of the bunkering vessel and the bunkering station.

A plurality of liquid manifolds 21 and gaseous manifolds 22 may be provided in the manifold 20, respectively. A plurality of individual manifolds can be arranged side by side in a bunkering station. For example, the manifold 20 may be provided with two liquid manifolds 21 and one gaseous manifold 22, and one gaseous manifold 22 between the two liquid manifolds 21. ) Can be placed. The two liquid manifolds 21 may be provided to communicate with each other. Although not shown, a plurality of manifolds 20 may be provided on the bunkering vessel. The manifold 20 is provided on one side of the bunkering vessel and can be connected to a liquefied gas carrier, a propulsion vessel, a terminal, a platform, etc., and may be connected to another bunkering vessel through an additional manifold at the stern.

One end of the first fuel supply line L30 is connected to the fuel withdrawal line L12 to receive liquid liquefied gas from the bunkering tank 10 and transfer it to a fuel demander in the bunkering vessel. Alternatively, one end of the first fuel supply line L30 may be connected to the spray line L13 to receive a liquid liquefied gas from the bunkering tank 10. The first fuel supply line L30 may supply liquefied gas to at least one of the power generation engine A and the gas combustion unit B. The power generation engine (A) can use liquefied gas as fuel to generate electric power, and the gas combustion unit (B) can process the liquefied gas by burning it and discharging it to the outside of the bunkering vessel for processing. Preferably, the power generation engine (A) and the gas combustion unit (B) may be supplied with gaseous liquefied gas and used as fuel, and for this purpose, the first fuel supply line (L30) has a forced vaporizer (30), gas-liquid A separator 31, a heater 32, and the like may be provided.

The forced vaporizer 30 may vaporize a liquid liquefied gas using seawater, fresh water, steam, or the like as a heat source and supply it to the gas-liquid separator 31. The gas-liquid separator 31 may be a mist separator, and may separate the liquid liquefied gas still contained in the liquefied gas vaporized through the forced vaporizer 30 and supply only the gaseous liquefied gas. The gaseous liquefied gas passing through the gas-liquid separator 31 may be additionally heated by the heater 32. Since the power generation engine (A) and the gas combustion unit (B) may have different temperature and pressure conditions of the liquefied gas required by each, the degree of heating in the heater 32 may be adjusted according to the customer.

The second fuel supply line L31 has one end connected to the gas phase transfer line L20 to receive gaseous liquefied gas from the bunkering tank 10 or the gaseous manifold 22 and transfer it to a fuel demander in the bunkering ship. . The fuel consumer is as described above, and the second fuel supply line L31 is provided with a high-duty (HD) compressor 33 to pressurize and supply liquefied gas according to the type of the consumer and the requirements according to the type of the consumer. Although not shown, the second fuel supply line L31 may further include a heater at the rear end of the HD compressor 33. The liquefied gas is pressurized while passing through the HD compressor 33 to increase the temperature, but may be lower than the temperature required by the customer. The heater can further heat the liquefied gas and adjust it to the temperature level required by the customer.

The third fuel supply line L32 has one end connected to the gas phase transfer line L20 to receive gaseous liquefied gas from the bunkering tank 10 or the gaseous manifold 22 and transfer it to a fuel demander in the bunkering ship. . For example, the third fuel supply line L32 may have one end connected to the gas phase transfer line L20 and the other end connected to the first fuel supply line L30. The third fuel supply line L32 may be connected to the rear end of the gas-liquid separator 31 of the first fuel supply line L30, and vaporize the gaseous liquefied gas in the forced vaporizer 30 of the first fuel supply line L30. And can be joined to the gaseous liquefied gas that has passed through the gas-liquid separator 31. Thereafter, the liquefied gas of the first fuel supply line L30 may be additionally heated by the heater 32 and then supplied to a customer.

The first gas treatment line L40 is connected to the gaseous phase transfer line L20 at one end to receive gaseous liquefied gas from the bunkering tank 10 or the gaseous manifold 22 and transfer it to a fuel demander within the bunkering vessel. . A gas-liquid separator 42 and a low-duty (LD) compressor 43 may be provided in the first gas processing line L40. Although not shown, a heater may be provided at the rear end of the LD compressor 43. The gas-liquid separator 42 may be a mist separator, and the gaseous liquefied gas is supplied to the LD compressor 43 and pressurized by separating the gaseous phase and the liquid phase, and the liquid liquefied gas is a liquid phase transfer line L10 or a spray line L13. ). The liquid phase separated by the gas-liquid separator 42 is a condensate formed by mixing in the gaseous liquefied gas or condensing at least a part of the gaseous liquefied gas. It may be returned to the bunkering tank 10 through the spray return line L14 through the line L13. The liquefied gas pressurized by the LD compressor 43 may be supplied to a fuel consumer or may be supplied to the buffer tank 40 through a condensation line L43 branching from the first gas treatment line L40.

The bunkering ship according to this embodiment may include a buffer tank 40. The buffer tank 40 is provided separately from the bunkering tank 10, and may be used in a loading and unloading process using a bunkering vessel. The buffer tank 40 may be provided in the form of a pressure container to store contents having a relatively high pressure compared to the bunkering tank 10.

The buffer tank 40 may receive gaseous liquefied gas through a condensation line L43 branching from the first gas treatment line L40. The condensation line (L43) may extend to the lower end of the buffer tank 40, preferably provided to supply the gaseous liquefied gas in a submerged state to the liquid liquefied gas stored in the buffer tank 40. have. The gaseous liquefied gas supplied through the condensation line L43 is supplied with cold heat while passing through the liquid liquefied gas in the buffer tank 40 so that at least a portion of the liquefied gas may be condensed. The arrangement in the buffer tank 40 of the condensation line L43 can improve the condensation performance of the liquefied gas compared to the case where the gaseous liquefied gas is simply injected to the top of the buffer tank 40.

In addition, the condensation performance in the buffer tank 40 may be determined according to the level (water level) of the liquid liquefied gas initially filled in the buffer tank 40. The liquefied gas level may be expressed as a percentage of the height of the liquid liquefied gas filled with respect to the total height of the inner space of the buffer tank 40. When the liquefied gas of the same flow rate is injected while the liquefied gas is initially filled in the buffer tank 40 to a level of approximately 40 to 80%, the rate of increase of the internal pressure of the buffer tank 40 is lowered and the overall condensation rate is improved. It can be linearly or non-linearly proportional to the liquefied gas level. Preferably, the first buffer tank 40 may be filled with liquefied gas to a level of approximately 70 to 80%. When the buffer tank 40 is filled with more than 80% of the liquefied gas, the condensation performance due to the injection of the gaseous liquefied gas may be rapidly lowered.

Therefore, the bunkering ship according to the present embodiment stores a part of the liquefied gas in the internal space of the buffer tank 40 when loading the liquefied gas into the bunkering tank 10, and the bunkering tank 10 and the target liquefied gas storage tank Since the liquefied gas supplied from and supplied through the manifold 20 can be condensed, it is possible to reduce or omit the scale of the reliquefaction facility in the target as well as the bunkering ship.

The fuel withdrawal line L41 of the buffer tank 40 has one end connected to the inside of the buffer tank 40, the other end of which is a liquid transfer line L10, a fuel withdrawal line L12, a spray line L13, and a first gas. It is connected to at least one of the processing lines L40 to transfer the liquid liquefied gas stored in the buffer tank 40.

The fuel withdrawal line L41 may supply the liquefied gas to the bunkering tank 10 through the liquid return line L11 or the spray line L13 through the liquid transfer line L10 through the spray return line L14. As the buffer tank 40 repeats the bunkering process, the level of the liquid liquefied gas may increase, and since it has a relatively small storage capacity compared to the bunkering tank 10, the bunkering process is finished or the bunkering process is liquefied between the bunkering process. At least part of the gas may be supplied to the bunkering tank 10. Accordingly, the bunkering ship condenses the boil-off gas generated in the bunkering process and then stores it in the bunkering tank 10 again, and then can be used in the bunkering process, thereby minimizing waste of boil-off gas.

The fuel withdrawal line L41 is provided with a fourth pump 41 at one end to draw out the liquid liquefied gas stored in the buffer tank 40. Conversely, the fuel withdrawal line L41 further includes a line (not shown) branching from the fuel withdrawing line L41 and returning back to the buffer tank 40, and the liquefied gas flowing through the liquid transfer line L10 May be supplied to the buffer tank 40.

The fuel withdrawal line L41 may be connected to the fuel withdrawal line L12 connected to the bunkering tank 10 and may supply the liquefied gas of the buffer tank 40 to the above-described first fuel supply line L30. That is, in the bunkering ship according to the present embodiment, the liquefied gas stored in the bunkering tank 10 is withdrawn through the fuel withdrawal line L12 and supplied to the customer, or the liquefied gas stored in the buffer tank 40 is supplied to the fuel withdrawal line L41. ) Through the withdrawal and supply to the consumer. The liquid liquefied gas withdrawn from the buffer tank 40 may be supplied to a consumer through the aforementioned forced vaporizer 30 or the like.

The fuel withdrawal line L41 may supply at least a portion of the liquid liquefied gas to the first gas processing line L40. In this case, a liquid liquefied gas or a mixture of liquid and gaseous liquefied gas may flow through the first gas treatment line L40, and may be separated into gaseous liquefied gas and condensate in the gas-liquid separator 42 described above. .

The boil-off gas supply line L42 may supply boil-off gas generated from the liquefied gas stored in the buffer tank 40 to the first gas processing line L40. For example, the boil-off gas supply line (L42) is a power generation engine (A) at least one of the gaseous liquefied gas that is not condensed and the boil-off gas generated in the buffer tank 40 among the liquefied gases supplied by the buffer tank 40. ), etc. The buffer tank 40 can withstand a relatively high internal pressure compared to the bunkering tank, but as the bunkering process proceeds, at least a portion of the boil-off gas may be discharged to lower the internal pressure of the buffer tank 40. The boil-off gas supply line (L42) supplies boil-off gas to the first gas processing line (L40), passes through a gas-liquid separator (42) and an LD compressor (43) to be supplied to a customer, or a condensation line (L43) is used again. Through condensation by transferring to the buffer tank 40, it is possible to reduce the pressure inside the buffer tank 40.

The second gas treatment line L50 may be connected to the gas phase transfer line L20 at one end to receive gas from the bunkering tank 10 or the gas phase manifold 22 and transfer it to a fuel demander in the bunkering vessel. The target liquefied gas storage tank may be filled with outside air, dry gas, or inert gas prior to bunkering, and it is withdrawn through the gaseous manifold 22 and the gas combustion unit (B) through the second gas treatment line (L50). ), etc. That is, the first gas processing line L40 is a configuration for supplying fuel by condensing, pressurizing, and heating vaporized gas such as vaporized gas, and the second gas processing line L40 does not contain liquefied gas or its content. This is a configuration for receiving and treating gas that is very low and cannot be used as fuel for condensation or power generation engine (A).

The bunkering ship according to the present embodiment as described above may be provided with a buffer tank 40 to condense the bunkering tank 10 and the boil-off gas supplied from the target, and the condensed boil-off gas is returned to the bunkering tank 10 By using it again or as fuel in a bunkering ship, it is possible to minimize the loss of liquefied gas and increase bunkering efficiency.

2 is a flowchart illustrating a method of operating a bunkering ship using a bunkering ship according to an embodiment of the present invention.

The operation method of a bunkering ship is largely (1) receiving liquefied gas from a liquefied gas supply and storing it in the bunkering tank, (2) operating the bunkering ship to the location of the bunkering target, (3) the bunkering ship The step of receiving the liquefied gas stored in the liquefied gas storage tank connected to the bunkering target, (4) supplying the liquefied gas of the bunkering tank to the liquefied gas storage tank, and (5) the bunkering ship It can be divided into stages of operation to the location of the liquefied gas supply source.

Referring to FIG. 2, the bunkering operation method includes: loading liquefied gas into the bunkering tank and buffer tank (S100), operating to the bunkering target (S2N0), connecting the bunkering system and preparing bunkering (S2N1), It can be subdivided into a bunkering step (S2N2) and a step of navigating to the terminal after bunkering (S300). Bunkering ships can perform only one bunkering process after loading liquefied gas into the bunkering tank, but this is not limited to this, and if the target is a ship that propels liquefied gas as fuel, the bunkering process for multiple ships can be performed. have. In the following, N is expressed by the bunkering order.

Step S100 is a step of loading the liquefied gas into the bunkering tank 10 of the bunkering ship. Bunkering ships may initially receive liquefied gas from a liquefied gas supply source such as an onshore or offshore platform or terminal or other bunkering ship. Hereinafter, it will be described that the bunkering ship receives the liquefied gas from the terminal and bunkers the target. When the bunkering ship receives liquefied gas from the terminal, loading of the bunkering tank 10 is performed, and at this time, at least part of the liquefied gas is loaded into the buffer tank 40 of the bunkering ship and filled with liquid liquefied gas. Then, in the bunkering process, it is possible to perform the function of condensing the boil-off gas using the buffer tank 40 described above.

Step S210 is a step in which the bunkering ship navigates to the location of the bunkering target in order to perform the first bunkering process. The bunkering ship may be propelled by using the liquefied gas stored in the bunkering tank 10 as fuel, or may drive onboard facilities such as a power generation engine (A). During the operation of the bunkering vessel, the liquefied gas stored in the bunkering tank 10 may evaporate to generate boil-off gas, and if the liquefied gas is also loaded in the buffer tank 40 in step S100, it occurs in the buffer tank 40. It is also necessary to treat the boil-off gas. In this step, as the bunkering ship moves to the target, the boil-off gas generated in each tank is used as fuel in the bunkering ship, so that the internal pressure of each tank can be reduced and waste of liquefied gas can be reduced without a separate reliquefaction device. do.

Step S211 is a step of connecting the target and the bunkering system of the bunkering ship. The manifold 20 of the bunkering ship and the manifold 20 of the target can be connected using the loading arm of the bunkering ship, and the liquefied gas can be transferred. At this time, the bunkering target may be in a state where there is no or little liquefied gas left in the liquefied gas storage tank, and the inside may be in a state filled with the boil-off gas of the liquefied gas. In this step, the bunkering ship can suit the internal conditions of the target liquefied gas storage tank suitable for liquefied gas loading prior to the full-scale bunkering process. For example, the bunkering ship may receive other gas stored in the target liquefied gas storage tank and process it in the gas combustion unit B, or may receive and process the boil-off gas supplied to the buffer tank 40.

Step S212 is a step of loading the liquid liquefied gas stored in the bunkering tank 10 into the target liquefied gas storage tank. As the liquefied gas of a large flow rate flows, boil-off gas may be generated in the bunkering tank 10 and the target liquefied gas storage tank, and the bunkering ship can also condense such boil-off gas or use it as fuel for a bunkering ship. In this step, the liquefied gas is loaded to the bunkering target and the boil-off gas is processed at the same time, so that the bunkering process can be more efficiently performed without a separate reliquefaction device and the internal pressure of each tank can be managed.

After completing step S212, the bunkering ship may perform an additional bunkering process in the order of the second bunkering S220 to S222, the third bunkering S230 to S232, and the fourth bunkering S240 to S242. It will be appreciated that this may vary depending on the amount of liquefied gas stored in the bunkering vessel and the type of bunkering target. For example, the bunkering ship may sequentially repeat steps S2N0 to S2N2 until the amount of liquefied gas stored in the bunkering tank 10 is less than a predetermined value, and then step S300 may be performed.

Step S300 is a step in which the bunkering ship completes all bunkering processes and operates to the platform or terminal again. The bunkering ship may unload the liquefied gas remaining in the bunkering tank 10 to the terminal. Alternatively, the process from step S100 may be performed by loading the liquefied gas again.

The bunkering ship according to the present embodiment further includes a buffer tank 40 to process liquefied gas generated from the bunkering ship and the target during the bunkering process. Hereinafter, referring to FIG. 3, the buffer tank 40 ) Enhance the effect of the arrangement.

3 is a graph showing the level and internal pressure of liquid liquefied gas stored in the bunkering tank 10 and the buffer tank 40 of the bunkering vessel when bunkering to a target using a bunkering vessel having a buffer tank 40 to be.

Referring to FIG. 3, the graph at the top relates to the bunkering tank 10 of the bunkering ship, and the graph at the bottom relates to the buffer tank 40 of the bunkering ship. The horizontal axis of the graph represents time, and indicates each step described in FIG. 2 from the start of loading of the bunkering vessel to the process of returning to the terminal after bunkering. The vertical axis represents the internal pressure of each tank in barg, and the bunkering tank 10 may be approximately 0.3 barg and the buffer tank 10 may be approximately 10 barg. As described above, the buffer tank 40 may be provided to withstand a relatively high internal pressure compared to the bunkering tank 10. In addition, the vertical axis represents the liquid level as a percentage (%) based on the total height of each tank in the bunkering tank 10 and the buffer tank 40. Hereinafter, it is assumed that the target is a ship that receives liquefied gas from a bunkering ship and propels it with fuel, and a process in which the bunkering ship bunkers the liquefied gas to the target ship for a total of four times will be described.

In step S100, the liquefied gas is loaded for each of the bunkering tank 10 and the buffer tank 40 of the bunkering vessel. For the bunkering tank 10, liquefied gas may be loaded to a liquid level of approximately 98% of the total height, and liquefied gas may be loaded to a liquid level of approximately 70% for the buffer tank 40. During the loading process, boil-off gas is generated inside each tank over time, which leads to an increase in internal pressure.

In step S210, the bunkering vessel may use the liquid liquefied gas stored in the bunkering tank 10 as fuel while operating to the primary bunkering target vessel. At the same time, the boil-off gas generated in the bunkering tank 10 and the boil-off gas generated in the buffer tank 40 may also be used as fuel. The boil-off gas generated from the bunkering tank 10 and the buffer tank 40 may be supplied to the power generation engine A through the first gas treatment line L40. The liquid level of the bunkering tank 10 is lowered according to the fuel withdrawal of the liquid liquefied gas and the generation of boil-off gas, but the internal pressure may decrease as the boil-off gas is also used as fuel. The liquid level of the buffer tank 40 is lowered according to the generation of boil-off gas, and the boil-off gas is used as fuel, so that the internal pressure decreases. In this step, the boil-off gas generated in the buffer tank 40 can be preferentially consumed, so that the internal pressure of the buffer tank 40 can be kept very low. This is to prevent the injection of boil-off gas into the buffer tank 40 in a step to be described later. Accordingly, it provides an effect that can maximize the condensation capacity and performance.

In step S211, the boil-off gas stored in the target liquefied gas storage tank while the bunkering ship is connected to the primary bunkering target ship may be supplied to the buffer tank 40 and condensed, or may be used as fuel for the bunkering ship. The boil-off gas supplied from the target is supplied to the condensation line (L43) through the first gas treatment line (L40) through the gas phase manifold (22), and the liquid liquefied gas stored in the buffer tank (40) is supplied to the medium to be liquefied. It can be condensed and liquefied by the cold heat of the gas. Accordingly, the liquid level of the buffer tank 40 rises, and since not all of the boil-off gas supplied to the buffer tank 40 is condensed, the internal pressure also rises. The boil-off gas generated from the bunkering tank 10 may also be supplied to the bunker tank 40 and condensed, but the internal pressure of the bunkering tank 10 may increase due to the generation of boil-off gas over time.

In step S212, the liquid liquefied gas is loaded into the liquefied gas storage tank of the primary bunkering target vessel using the first pump 11 of the bunkering tank 10. The liquid liquefied gas is supplied to the target through the liquid manifold 21, and the boil-off gas generated from the bunkering tank 10 and the target liquefied gas storage tank is supplied from the bunkering vessel through the gas phase manifold 22 and buffered. It can be condensed in the tank 40. Accordingly, the liquid level and the internal pressure of the bunkering tank 10 are lowered, and the liquid level and the internal pressure of the buffer tank 40 are increased.

Thereafter, the bunkering ship disconnects from the first bunkering target ship, and operates to the position of the second bunkering target ship in step S220. In step S220, similar to step S210, it is possible to operate while consuming the boil-off gas generated in each tank as fuel. The bunkering tank 10 uses an insulating material to minimize heat exchange with the outside, but the temperature of the liquefied gas stored inside increases as time passes and the bunkering process goes through, and bunkering due to the decrease of the internal pressure in the previous bunkering process. Since factors such as an increase in the evaporation rate in the process of matching the internal equilibrium of the tank 10 act in combination, the rate at which the internal pressure of the bunkering tank 10 increases may be faster than in the previous step S210.

In step S221, the boil-off gas stored in the target liquefied gas storage tank while the bunkering ship is connected to the second bunkering target ship may be supplied to the buffer tank 40 and condensed, or may be used as fuel for the bunkering ship. In the buffer tank 40, the boil-off gas is additionally supplied with the liquid level reaching 80%, so that the increase in the internal pressure may be greater than the width of the condensation performance improvement.

In step S222, the liquefied gas of the bunkering tank 10 is loaded into the liquefied gas storage tank of the second bunkering target vessel. Accordingly, the liquid level and the internal pressure of the bunkering tank 10 are lowered, but the liquid level of the buffer tank 40 reaches the limit and is maintained almost constant, and the internal pressure may be slightly lowered as the condensation of the boil-off gas proceeds.

Thereafter, the bunkering ship may additionally perform bunkering for the third and fourth bunkering target ships. In the 3rd and 4th bunkering stages, for the same reason as described above, the internal pressure of the bunkering tank 10 can increase at a faster rate compared to each of the preceding stages, and the buffer tank 40 has a liquid level of 80% or more. As it stays almost constant, the internal pressure fluctuations can appear at a modest level. The buffer tank 40 has a high liquid level of the liquefied gas stored therein, which means that it is absolutely storing more cold heat, but the buffer tank 40 stores both liquefied gas and boil-off gas in a limited space. Since it must be able to withstand their pressure in the state, it can be seen that the practical condensation efficiency is maximized when the liquid level is maintained below about 80% level. Therefore, after the completion of each bunkering process (S2N2), when the process of adjusting the liquid level of the buffer tank 40 by discharging the liquid liquefied gas stored in the buffer tank 40 is accompanied, the condensation performance for the subsequent bunkering process is also It will be able to improve or maintain.

In step S300, the bunkering ship completes all bunkering processes and operates to the terminal, and only a trace amount of liquefied gas remains in the bunkering tank 10, so the boil-off gas generated in the buffer tank 40 and the liquid phase stored in the buffer tank 40 At least one of the liquefied gases of may be used as fuel for the power generation engine (A). Preferably, the boil-off gas generated in the buffer tank 40 may be preferentially used as fuel. The liquid level of the bunkering tank 10 can be lowered to a level that cannot be withdrawn by the first pump 11, and the liquid level of the buffer tank 40 is lowered according to the generation of boil-off gas, and the boil-off gas is used as fuel. The internal pressure decreases.

The bunkering vessel according to the present embodiment has a buffer tank 40 to provide a decompression operation service for the target vessel before bunkering, thereby reducing the overall working time, and condensing the boil-off gas in the buffer tank 40 for reuse. It is possible to minimize the waste of boil-off gas by making it possible. Hereinafter, individual processes of loading and unloading using a bunkering vessel according to an embodiment of the present invention will be described in more detail with reference to FIGS. 4 to 14.

4 is a conceptual diagram showing a process of loading liquefied gas into the bunkering tank 10 of a bunkering ship according to an embodiment of the present invention. The bunkering ship may include a bunkering tank 10, a manifold 20, a buffer tank 40, and the like, and the same contents as described with reference to FIG. 1 will be replaced with the contents of the previous embodiment.

The bunkering ship may be in a state for loading liquefied gas for initial bunkering, or may be in a state for loading liquefied gas into the bunkering tank 10 again by completing bunkering for a target and returning to the terminal. The manifold 20 of the bunkering ship is connected to the terminal so that liquid and gaseous liquefied gases can communicate.

The bunkering ship may be supplied with liquid liquefied gas through one or more liquid manifolds 21. The liquid liquefied gas introduced through the liquid manifold 21 flows along the liquid transfer line L10 and is supplied to the bunkering tank 11 through the liquid return line L11.

The bunkering ship according to the present embodiment may also load liquefied gas into the buffer tank 40 when liquefied gas is loaded into the bunkering tank 10. At least some of the liquid liquefied gas flowing along the liquid transfer line L10 may branch along the fuel withdrawal line L41 to be supplied to the buffer tank 40.

For the bunkering tank 10, the liquid liquefied gas is loaded until the level of the liquid liquefied gas reaches about 98% based on the height of the internal storage space, and for the buffer tank 40, the liquid liquefied gas is based on the height of the internal storage space. It may be desirable to load until the level is approximately 70%.

In the bunkering vessel, the boil-off gas generated by loading the liquefied gas into the bunkering tank 10 and the buffer tank 40 may be returned to the terminal again. The boil-off gas generated from the bunkering tank 10 may be withdrawn through the vapor phase transfer line L20 and returned to the terminal through the vapor phase manifold 22. The boil-off gas generated from the buffer tank 40 may be withdrawn through the boil-off gas supply line L42 and then returned to the terminal through the gas-phase manifold 22 through the gas-phase transfer line L20.

Specifically, the boil-off gas generated from the bunkering tank 10 may be withdrawn through the gas phase transfer line L20 and supplied to the second fuel supply line L31. At this time, the boil-off gas generated from the buffer tank 40 is withdrawn through the boil-off gas supply line (L42) and supplied to the gas phase transfer line (L20) to join the boil-off gas generated in the bunkering tank (10). It may be supplied to the second fuel supply line L31. The HD compressor 33 of the second fuel supply line L31 may pressurize the boil-off gas to have a sufficient pressure to be transferred to the terminal through the gas phase manifold 22. The boil-off gas pressurized by the HD compressor 33 may be transferred to the gas phase manifold 22 through the second gas treatment line L50.

The bunkering ship according to this embodiment can receive liquefied gas from the terminal and store it in the bunkering tank 10, and the boil-off gas generated in the process of loading the liquefied gas is pressurized and returned to the terminal to prepare for operation for bunkering. have. At this time, the liquefied gas is loaded into the buffer tank 40 as well as the bunkering tank 10 at a predetermined level, so that the buffer tank 40 can be used for the operation of the bunkering vessel and decompression operation of the bunkering target, which will be described later.

FIG. 5 is a conceptual diagram illustrating a process of treating boil-off gas generated from the bunkering tank 10 and the buffer tank 40 and a fuel supply process when a bunkering vessel according to an embodiment of the present invention operates.

The bunkering ship operates to the target bunkering with the liquefied gas stored in the bunkering tank 10 and the buffer tank 40, and can drive the onboard facilities including the power generation engine (A). The bunkering ship operates to the target of bunkering and may use liquefied gas stored in at least one of the bunkering tank 10 and the buffer tank 40 as fuel. In addition, even when the bunkering ship completes loading into the target liquefied gas storage tank and operates to another target location or terminal, the liquefied gas stored in at least one of the bunkering tank 10 and the buffer tank 40 is used as fuel. Can be used.

Specifically, the bunkering ship may withdraw the boil-off gas generated from any one of the bunkering tank 10 and the buffer tank 40 and supply it to the power generation engine (A). The boil-off gas generated in the bunkering tank 90 and the buffer tank 40 may vary depending on the environment in which the bunkering vessel is located or operating conditions of the vessel.

The boil-off gas generated in the buffer tank 40 may be withdrawn through the boil-off gas supply line L42 and supplied to the power generation engine A through the first gas processing line L40. In the boil-off gas drawn from the buffer tank 40, a trace amount of liquid liquefied gas may be mixed in a droplet state, and a relatively heavy heavy carbon such as ethane and propane may be further included in addition to methane. The boil-off gas is supplied to the gas-liquid separator 42 of the first gas treatment line (L40), so that only gaseous liquefied gas is separated and supplied to the LD compressor 43, and at least part of the liquid liquefied gas and heavy carbon is condensed. The condensate may be formed and transferred to the bunkering tank 10 through the liquid return line L11. The gaseous liquefied gas supplied from the Ginggae separator 42 may be supplied by being pressurized by the LD compressor 43 at a pressure required by the power generation engine A.

Although not shown, a plurality of LD compressors 43 may be provided in series or in parallel. The gaseous liquefied gas pressurized by the LD compressor 43 may be heated to a temperature required by the power generation engine A, but may be in a relatively high temperature state compared to the required temperature. The LD compressor 43 may be provided with a cooler for cooling the pressurized liquefied gas at its rear end. The cooler can cool the liquefied gas to the temperature required by the power generation engine (G/E) and supply it to the power generation engine (G/E).

The boil-off gas generated in the bunkering tank 10 may be withdrawn through the gas phase transfer line L20 and supplied to the first gas treatment line L40. The boil-off gas of the bunkering tank 10 merges with the boil-off gas of the buffer tank 40 described above in the first gas treatment line L40 and is supplied to the power generation engine A through the gas-liquid separator 42 and the LD compressor 43. Can be.

In the bunkering vessel, when the flow rate of the boil-off gas generated in the bunkering tank 10 and the buffer tank 40 is less than a predetermined flow rate, the liquid liquefied gas may be withdrawn from the bunkering tank 10 and supplied as fuel. When the liquid liquefied gas stored in the bunkering tank 10 is supplied as fuel, a relatively small flow rate can be used compared to the bunkering process. 1 Can be supplied to the fuel supply line (L30). The liquid liquefied gas may be supplied to the forced vaporizer 30 of the first fuel supply line L30 so that at least part of it may be vaporized, and the liquid liquefied gas not vaporized by being supplied to the gas-liquid separator 31 may be separated. . Although not shown, the separated liquid liquefied gas may be returned to the bunkering tank 10 through the liquid return line L11. The gaseous liquefied gas separated by the gas-liquid separator 31 may be further heated by the heater 32 to be heated to a temperature required by the power generation engine A and supplied to the power generation engine A. The gaseous liquefied gas supplied from the bunkering tank 10 and the buffer tank 40 may merge at the lower end of the heater 32 and be supplied to the power generation engine A.

The bunkering ship according to the present embodiment may adjust the flow rates of the boil-off gas supplied from the bunkering tank 10 and the buffer tank 40 according to operating conditions, respectively. For example, the operating conditions may be determined according to at least one of the amount of boil-off gas generated in the bunkering tank 10, whether the bunkering vessel is operating, and whether liquefied gas is loaded on the bunkering target, and the power generation engine of the bunkering vessel (A ) May require the minimum liquefied gas flow required to produce the required power in the ship.

When the bunkering ship operates with the liquefied gas supplied from the terminal, the flow rate of the boil-off gas generated from the bunkering tank 10 may be the highest, and when the bunkering tank is operated to the terminal after all bunkering is completed on the target. The flow rate of the boil-off gas generated in (10) may be the lowest.

For example, when a bunkering ship operates with liquefied gas loaded in the bunkering tank 10, that is, before the bunkering ship loads liquefied gas into the bunkering target, the power generation engine A ) The flow rate of the boil-off gas supplied to the bunkering tank 10 can be adjusted to be less than the flow rate of the boil-off gas supplied to the power generation engine (A). When the bunkering ship finishes bunkering and operates to the terminal, that is, after the bunkering ship loads liquefied gas into the bunkering target, the flow rate of the boil-off gas supplied from the buffer tank 40 to the power generation engine A is the bunkering tank 10 ) Can be adjusted to be greater than the flow rate of the boil-off gas supplied to the power generation engine (A).

Since the buffer tank 40 is provided to withstand a relatively high internal pressure compared to the bunkering tank 10, the boil-off gas of the buffer tank 40 is matched to the flow rate of boil-off gas generated in the bunkering tank 10 according to the operating conditions of the bunkering vessel. By controlling the supply amount, it is possible to efficiently consume the boil-off gas generated in the bunkering tank 10, through which the internal pressure of the bunkering tank 10 can be maintained in a safe range.

The bunkering ship according to this embodiment supplies and consumes the boil-off gas generated from the bunkering tank 10 and the buffer tank 40 as fuel for the power generation engine A of the bunkering ship, and energy required for driving the power generation engine A And it is possible to reduce the internal pressure of the bunkering tank 10 and the buffer tank 40 according to the treatment of the boil-off gas. In addition, even when the amount of boil-off gas generated in the bunkering tank 10 fluctuates according to the operating conditions of the bunkering ship, the amount of boil-off gas supplied from the buffer tank 40 is controlled to supply a constant flow of liquefied gas to the power generation engine (A). It can be controlled as much as possible.

6 is a conceptual diagram illustrating a process of receiving and processing boil-off gas from a target when a bunkering ship according to an embodiment of the present invention is connected to a target.

The bunkering ship according to the present embodiment may receive and process boil-off gas that was present in the liquefied gas storage tank of the target while the bunkering ship is connected to the target or generated in the process of connecting with the target. This treatment can be a process of removing the relatively hot gaseous liquefied gas filled in the liquefied gas storage tank to be bunkered, and depressurizing the liquefied gas storage tank to create a state suitable for injecting the liquid liquefied gas during the bunkering process. have.

The bunkering ship may receive boil-off gas through the gas phase manifold 22 of the manifold 20. The bunkering ship may deliver the boil-off gas supplied through the vapor phase manifold 22 to the first gas treatment line L40 through the vapor phase transfer line L20.

The boil-off gas supplied to the first gas treatment line L40 may be supplied to the buffer tank 40 through the condensation line L43 through the gas-liquid separator 42 and the LD compressor 43. At least a part of the gaseous liquefied gas separated while passing through the gas-liquid separator 42 may be injected into the lower end of the buffer tank 40 through the condensation line L43, and the gaseous liquefied gas pressurized by the LD compressor 43 As it is introduced into the relatively bulky buffer tank 40, it expands and may be liquefied at least, and is liquefied by receiving cold heat from the liquid liquefied gas while being injected into the liquid liquefied gas filled in the buffer tank 40. I can.

The remaining gaseous liquefied gas may be supplied to the power generation engine A through the first gas treatment line L40, and the supply flow rate of the gaseous liquefied gas through the first gas treatment line L40 is the power generation engine A If it is more than the required amount of liquefied gas, gaseous liquefied gas can be supplied to the auxiliary boiler for treatment.

In the process of treating the boil-off gas according to the present embodiment as described above, the target may be a liquefied gas carrier or a liquefied gas propulsion ship, and the liquefied gas storage tank may be a pressure vessel, but is not limited thereto. The bunkering ship according to the present embodiment uses the power generation engine (A) and the buffer tank 40 provided in the bunkering ship to be able to process the boil-off gas generated in the liquefied gas storage tank of the target, so that the boil-off gas is treated by the target. The bunkering process can be carried out smoothly and safely by simplifying the equipment for and controlling the pressure inside the target liquefied gas storage tank before bunkering.

7 is a conceptual diagram showing a gassing up process prior to bunkering in a target liquefied gas storage tank using a bunkering vessel according to an embodiment of the present invention.

The bunkering ship can supply the liquefied gas with a relatively small flow rate to the target liquefied gas storage tank before loading the liquefied gas into the target liquefied gas storage tank. In this embodiment, a target receiving liquefied gas may be a ship equipped with a carburetor, and the bunkering ship may withdraw some of the liquid liquefied gas stored in the bunkering tank 10 and supply it to the target liquefied gas storage tank.

The bunkering ship according to the present embodiment may supply liquefied gas to the liquefied gas storage tank of the target while the bunkering ship is connected to the target, and receive gaseous exhaust gas discharged from the target.

In the opening-up process, before loading the liquefied gas into the target liquefied gas storage tank, at least a part of the liquefied gas is supplied to the target liquefied gas storage tank through the liquid manifold 21 and stored inside the liquefied gas storage tank. It may be to remove gas. The target liquefied gas storage tank may be filled with a trace amount of liquefied gas after the boil-off gas is removed, or may be filled with nitrogen gas or inert gas. In this case, carbon dioxide may be introduced into the target liquefied gas storage tank, and the carbon dioxide is sublimated as the cryogenic liquefied gas is loaded, and the pump or pipe provided inside the target liquefied gas storage tank or the target liquefied gas storage tank It can damage the configuration, such as. Therefore, by discharging and removing gas including carbon dioxide in the target liquefied gas storage tank through the gassing-up process, it is possible to protect the target liquefied gas storage tank and internal facilities. To this end, the liquefied gas having a relatively small flow rate compared to the full-fledged loading of the liquefied gas may be injected into the target liquefied gas storage tank to discharge the internal gas.

The bunkering ship may withdraw the liquid liquefied gas stored in the bunkering tank 10 and supply it to the target liquefied gas storage tank. Specifically, the bunkering ship may withdraw the liquid liquefied gas using the third pump 13 and transmit it to the liquid manifold 21 through the spray line L13. Although not shown, the liquid liquefied gas supplied through the liquid manifold 21 may be supplied to a target vaporizer to be vaporized and then injected into the target liquefied gas storage tank. As the gaseous liquefied gas is injected into the target liquefied gas storage tank, the gas stored in the target liquefied gas storage tank may be discharged. Such exhaust gas may be an inert gas or the like, and may be supplied to the bunkering ship through the gas phase manifold 22 of the bunkering ship. The bunkering ship may receive and process the exhaust gas discharged from the target through the gas phase transfer line (L20).

Since the liquefied gas is contained in a low concentration in the exhaust gas discharged from the object, it may not be suitable for combustion in the power generation engine A or for condensation by supplying it to the buffer tank 40. Therefore, the bunkering ship can vent (not shown) the exhaust gas to the outside at the beginning of the gassing business, and after the liquefied gas starts to be included in the exhaust gas, the exhaust gas is supplied through the gas phase transfer line L20 to receive the second It can be processed by transferring to the gas combustion unit (B) through the gas processing line (L50). Although not shown, the bunkering ship receives exhaust gas through the gaseous phase transfer line (L20), delivers it to the second fuel supply line (L31), and discharges it from the HD compressor (33) according to the pressure required by the gas combustion unit (B). After pressurizing the gas, it can be supplied to the gas combustion unit (B).

The bunkering ship according to the present embodiment may supply liquid liquefied gas to a target equipped with a liquefied gas vaporizer to remove inert gas in the target liquefied gas storage tank and make the inside of the liquefied gas atmosphere. In the case of gassing business of liquefied natural gas, the concentration of methane in the target liquefied gas storage tank after gassing may be 90 vol% or more, and preferably 99 vol% or more. The bunkering ship may receive and process the gas discharged from the target liquefied gas storage tank, and may be vented according to the liquefied gas content in the discharged gas or processed in the gas combustion unit (B). Accordingly, it is possible to simplify or omit the facility for inert gas treatment in the target, and at the same time, it is possible to prepare the bunkering process by filling the inside of the liquefied gas storage tank of the target with liquefied gas before bunkering.

8 and 9 are conceptual diagrams illustrating a process of performing a cool down on a target liquefied gas storage tank using a bunkering vessel according to an embodiment of the present invention.

The bunkering ship can supply the liquefied gas with a relatively small flow rate to the target liquefied gas storage tank before loading the liquefied gas into the target liquefied gas storage tank. In this case, compared to the above-described gassing-up process, the internal temperature of the target liquefied gas storage tank may be lowered by supplying a relatively large amount of liquefied gas.

The bunkering ship according to the present embodiment may supply a small amount of liquefied gas to the target liquefied gas storage tank and receive exhaust gas discharged from the target while the bunkering ship is connected to the target. The exhaust gas may include liquefied gas, and may further include a trace amount of inert gas other than liquefied gas.

In the cooldown process, before loading the liquefied gas into the target liquefied gas storage tank, a small amount of cryogenic liquefied gas is supplied to the target liquefied gas storage tank to remove the gas stored in the target liquefied gas storage tank, It may be to cool the inside of the target liquefied gas storage tank. Specifically, the bunkering ship may supply liquefied gas to a target liquefied gas storage tank after the gas opening process, and receive a relatively high temperature gaseous liquefied gas discharged from the target liquefied gas storage tank. More specifically, the bunkering ship may receive a relatively high-temperature gaseous liquefied gas from a target liquefied gas storage tank at the beginning of the cooldown, and then receive a relatively low-temperature gaseous liquefied gas.

Referring to FIG. 8, the liquefied gas storage tank of a target before liquefied gas loading may be filled with gaseous liquefied gas that is relatively hotter than the liquefied gas stored in the bunkering tank 10. The bunkering ship supplies liquid liquefied gas to the target liquefied gas storage tank and extracts the gaseous liquefied gas to reduce the amount of liquefied gas evaporated by the relatively hot gaseous liquefied gas when the liquefied gas is loaded later. have. In addition, when the cryogenic liquid liquefied gas is suddenly injected into the target liquefied gas storage tank when the liquefied gas is loaded, the barrier structure inside the target liquefied gas storage tank or a configuration such as a pump may be damaged. Through the cool-down process, the temperature inside the target liquefied gas storage tank can be lowered to a temperature similar to that of the liquid liquefied gas, thereby protecting the target liquefied gas storage tank and other facilities.

The bunkering ship may withdraw the liquid liquefied gas stored in the bunkering tank 10 and supply it to the target liquefied gas storage tank. Specifically, the bunkering ship may withdraw the liquid liquefied gas using the third pump 13 and transmit it to the liquid manifold 21 through the spray line L13.

The bunkering ship may receive exhaust gas discharged from the liquefied gas storage tank to be bunkered through the gas phase manifold 22. In the bunkering vessel, when the content of the liquefied gas contained in the exhaust gas discharged from the liquefied gas storage tank is greater than or equal to a predetermined value, the exhaust gas is transferred to the buffer tank 40 through the first gas processing line L40. ), and when the content of the liquefied gas contained in the exhaust gas discharged from the liquefied gas storage tank is less than a predetermined value, the exhaust gas is supplied to the gas combustion unit ( B) can be supplied.

Specifically, since the gaseous liquefied gas discharged at the start of the cooldown may still contain inert gas, etc., the bunkering ship is the gaseous liquefied gas supplied from the target liquefied gas storage tank through the gaseous transfer line (L20). At least some of them may be supplied to the gas combustion unit B through the second gas processing line L50 to be processed. Thereafter, the bunkering ship may supply at least a part of the gaseous liquefied gas supplied from the target liquefied gas storage tank through the gaseous phase transfer line L20 to the buffer tank 40 through the first gas treatment line L40. Since the gaseous liquefied gas is injected to the bottom of the buffer tank 40 through the condensation line (L43) and condensed, the liquefied gas supplied during the gassing process can be recovered back to the bunkering vessel and stored as liquid liquefied gas. Can be reused. Although not shown, the liquid liquefied gas separated by the gas-liquid separator 42 of the first gas treatment line L40 may be supplied to and stored in the bunkering tank 10 through the liquid return line L11.

Referring to FIG. 9, as the bunkering ship supplies liquid liquefied gas and supplies gaseous liquefied gas to the buffer tank 40 and condenses, the liquid level and internal pressure of the buffer tank 40 may increase.

When the liquid level or internal pressure of the buffer tank 40 exceeds a predetermined value, the bunkering ship may withdraw the liquid liquefied gas stored in the buffer tank 40 and use it as fuel for the bunkering ship. Specifically, in the bunkering vessel, when the liquid level of the buffer tank 40 is higher than 80%, the bunkering vessel may withdraw the liquid liquefied gas stored in the buffer tank 40 using the fourth pump 41. When the liquid level of the buffer tank 40 exceeds 80%, the boil-off gas condensation performance in the buffer tank 40 may be deteriorated. The fuel withdrawal line L41 may deliver a liquid liquefied gas to the first fuel supply line L30. The liquid liquefied gas may be supplied as fuel to the power generation engine A through the forced vaporizer 30, the gas-liquid separator 31, and the heater 32 of the first fuel supply line L30.

The bunkering ship according to this embodiment supplies liquid liquefied gas to the target liquefied gas storage tank, and liquefies the liquid until the average temperature inside the target liquefied gas storage tank reaches -130°C or falls below -130°C. Gas can be supplied. Bunkering ships supply liquid liquefied gas to the target liquefied gas storage tank and inject gaseous liquefied gas discharged into the buffer tank 40 to condense and store it, or supply it as fuel for the power generation engine (A) for processing. can do. In this process, when the flow rate of the gaseous liquefied gas supplied from the target and condensed in the buffer tank 40 is greater than a predetermined amount, the liquid liquefied gas is withdrawn from the buffer tank 40 and consumed as fuel for the bunkering ship. , It is possible to prepare the bunkering process while maintaining the condensation performance in the buffer tank 40.

10 and 11 are conceptual diagrams illustrating a bunkering process of supplying liquefied gas to a target liquefied gas storage tank using a bunkering vessel according to an embodiment of the present invention.

The bunkering ship according to the present embodiment may supply liquefied gas to the liquefied gas storage tank of the target while the bunkering ship is connected to the target. According to the above-described process, the inside of the target liquefied gas storage tank may be a condition suitable for loading cryogenic liquefied gas through gassing-up and cooling-down processes.

The bunkering ship may supply liquid liquefied gas to a target liquefied gas storage tank through the liquid transfer line L10 and the liquid manifold 21. Specifically, the bunkering ship may withdraw the liquefied gas from the bunkering tank 10 using the first pump 11 and supply the liquefied gas storage tank of the target through the liquid manifold 21.

Referring to FIG. 10, the inside of the target liquefied gas storage tank may be filled with a relatively low temperature gaseous liquefied gas supplied during a cooling down process. The bunkering ship may receive gaseous liquefied gas discharged from the target liquefied gas storage tank through the gaseous manifold 22. The bunkering ship may supply the gaseous liquefied gas supplied from the target liquefied gas storage tank through the gaseous phase transfer line L20 to the buffer tank 40 to condense it. The gaseous liquefied gas may be supplied from the gaseous phase transfer line L20 to the condensation line L43 through the first gas treatment line L40, and evaporation occurring inside the bunkering tank 10 in the process of supplying the liquid liquefied gas The gas may also be supplied to the buffer tank 40 by merging with gaseous liquefied gas supplied from the target in the first gas treatment line L40 via the gaseous phase transfer line L20.

Referring to FIG. 11, as the bunkering vessel supplies liquid liquefied gas and supplies gaseous liquefied gas to the buffer tank 40 and condenses, the liquid level and internal pressure of the buffer tank 40 may increase. As liquefied gas having a relatively large flow rate compared to the cooldown is loaded and the gaseous liquefied gas is injected into the buffer tank 40, some of the gaseous liquefied gas is not condensed and may be stored in the buffer tank 40. In the bunkering vessel, when the internal pressure of the buffer tank 40 is higher than a predetermined value, the gaseous liquefied gas in the buffer tank 40 is withdrawn and the power generation engine A and the gas combustion unit ( It can be processed by supplying at least one of B).

The boil-off gas generated in the buffer tank 40 and the boil-off gas that is not condensed and is discharged from the buffer tank 40 are delivered to the first gas processing line L40 through the boil-off gas supply line L42. The boil-off gas supplied from the buffer tank 40, the boil-off gas supplied from the bunkering tank 10, and the gas-phase liquefied gas supplied from the target liquefied gas storage tank merge in the first gas processing line L40, Through the separator 42 and the LD compressor 43, it is injected into the buffer tank 40 through a condensation line (L43) branching from the bottom of the LD compressor 43, or the power generation engine (A) and gas combustion of a bunkering ship It may be supplied to at least one of the units (B).

The bunkering ship according to the present embodiment supplies liquid liquefied gas to a target liquefied gas storage tank, and injects gaseous liquefied gas discharged from the target liquefied gas storage tank into the buffer tank 40 to condense it, or It can be processed by supplying it as fuel for the power generation engine (A). In this process, boil-off gas is extracted from the buffer tank 40 and consumed as fuel for the bunkering vessel, or recondensed by injecting it to the bottom of the buffer tank 40 to minimize waste of liquefied gas during the bunkering process. , It is possible to reuse the liquefied gas stored in the bunper tank 40.

12 is a conceptual diagram showing a process of treating liquefied gas condensed in the buffer tank 40 after bunkering using a bunkering vessel according to an embodiment of the present invention.

The bunkering ship may return at least a portion of the liquid liquefied gas stored in the buffer tank 40 to the bunkering tank 10 when the loading of the liquefied gas storage tank to be bunkered is completed or when preparing bunkering for the next target. . The buffer tank 40 may store liquid liquefied gas within a range of a maximum liquid level of 98% or may return at least some of the stored liquid liquefied gas to the bunkering tank 10.

For example, when the liquid level of the buffer tank 40 is approximately 70 to 80%, the condensation performance of the buffer tank 40 can be maximized, and the liquid level of the buffer tank 40 is less than 80% during the bunkering process. If it is high, the liquid liquefied gas stored in the buffer tank 40 is returned to the bunkering tank 10, so that the liquid level of the buffer tank 40 can be adjusted to the above range until the sailing process to the next target or connection with the bunkering target. have.

The liquid liquefied gas of the buffer tank 40 may be withdrawn through the fuel withdrawal line L41 and supplied to the gas-liquid separator 42 of the first gas treatment line L40. The liquid liquefied gas may be separated from the gas-liquid separator 42 and supplied to the bunkering tank 10 through the liquid return line L11 through the liquid transfer line L10. The gaseous liquefied gas separated by the gas-liquid separator 42 may be pressurized by the LD compressor 43 of the first gas treatment line L40 and supplied to the power generation engine A to be used as fuel. When only the gaseous liquefied gas separated by the gas-liquid separator 42 does not meet the required flow rate of the power generation engine A, the liquefied gas of the bunkering tank 10 is transferred to the second pump 12 as described above in FIG. 5. It can be withdrawn and supplied to the power generation engine A through the first fuel supply line L30.

In the bunkering vessel according to the present embodiment, when the amount of liquid liquefied gas stored in the buffer tank 40 is greater than a predetermined value, it is used as fuel for the bunkering vessel or returned to the bunkering tank 10 and stored, thereby storing the buffer tank ( It is possible to prevent the deterioration of the boil-off gas condensation performance in 40), and the liquefied gas returned to the bunkering tank 10 can be reused in the subsequent bunkering process.

13 is a conceptual diagram illustrating a fuel supply process when a bunkering ship according to an embodiment of the present invention operates to a terminal after completing bunkering.

When the bunkering vessel completes all bunkering processes, only a trace amount of liquefied gas remains in the bunkering tank 10, and a relatively large amount of liquefied gas may be stored in the buffer tank 40. When the bunkering ship operates to the terminal, the liquefied gas stored in the buffer tank 40 may be used as fuel.

The liquid liquefied gas stored in the buffer tank 40 may be withdrawn using the fourth pump 41 and supplied to the first fuel supply line L30 through the fuel withdrawal line L41. The liquid liquefied gas may be supplied to the power generation engine A through the forced vaporizer 30, the gas-liquid separator 31, and the heater 32. The boil-off gas generated in the buffer tank 40 may be withdrawn through the boil-off gas supply line L42 and supplied to the power generation engine A through the first gas processing line L40.

When the liquefied gas remains in the bunkering tank 10, the liquid liquefied gas is withdrawn through the fuel withdrawal line L12 and supplied to the first fuel supply line L30, and the liquid liquefied supplied from the buffer tank 40 Can merge with gas. The boil-off gas generated in the bunkering tank 10 is withdrawn through the gas phase transfer line (L20) and supplied to the first gas treatment line (L40) to merge with the boil-off gas supplied from the boil-off gas supply line (L42), It can be supplied as (A).

The bunkering vessel according to the present embodiment can operate to the terminal by preferentially consuming the liquefied gas stored in the buffer tank 40 after the bunkering process.

14 is a conceptual diagram showing a process of unloading liquefied gas stored in a bunkering vessel according to an embodiment of the present invention.

The bunkering vessel may unload liquid liquefied gas stored in the bunkering tank 10 and the buffer tank 40 to the terminal through the manifold 20. The liquefied gas stored in the bunkering tank 10 is first withdrawn using the first pump 11 and supplied to the liquid manifold 21 through the liquid transfer line L10, and the liquid level of the bunkering tank 10 is low. It can be supplied to the liquid manifold 21 through the spray line L13 by drawing with the ground third pump 13. The liquefied gas stored in the buffer tank 40 may be withdrawn using the fourth pump 41 and supplied to the liquid manifold 21 through the fuel withdrawal line L41 and the liquid transfer line L10.

Inside the bunkering tank 10, a large amount of boil-off gas is generated during the unloading process of the liquefied gas, which is taken out through the gas phase transfer line (L20) and supplied to the power generation engine (A) through the third fuel supply line (L32). Can be handled.

Bunkering tank 10 and buffer tank 40 of a bunkering vessel in which liquefied gas is unloaded may be filled with inert gas or dry gas, or liquefied gas may be loaded again according to FIG. 4 to prepare bunkering.

It goes without saying that the present invention is not limited to the above-described embodiments, and may include a combination of the above embodiments or a combination of at least one of the above embodiments and a known technology as another embodiment.

In the above, the present invention has been described based on the embodiments of the present invention, but this is only an example and does not limit the present invention, and those of ordinary skill in the field to which the present invention pertains will not depart from the essential technical content of the present embodiment. It will be appreciated that various combinations or modifications and applications not illustrated in the embodiments are possible in the range. Accordingly, technical contents related to modifications and applications that can be easily derived from the embodiments of the present invention should be interpreted as being included in the present invention.

10: bunkering tank 11: first pump
12: second pump 13: third pump
20: manifold 21: liquid manifold
22: vapor manifold 30: forced carburetor
31: gas-liquid separator 32: heater
33: HD compressor 40: buffer tank
41: fourth pump 42: gas-liquid separator
43: LD compressor
L10: liquid transfer line L11: liquid return line
L12: fuel withdrawal line L13: spray line
L14: spray return line L20: gas phase transfer line
L30: first fuel supply line L31: second fuel supply line
L32: 3rd fuel supply line L40: 1st gas treatment line
L41: fuel withdrawal line L42: boil-off gas supply line
L43: condensation line L50: second gas treatment line
A: Power generation engine B: Gas combustion unit

Claims (10)

As a bunkering vessel for loading and unloading liquefied gas into the liquefied gas storage tank to be bunkered,
A bunkering tank for storing liquefied gas;
A manifold for flowing liquefied gas by communicating the bunkering ship and the bunkering target; And
And a buffer tank receiving and storing liquefied gas from the bunkering tank and the manifold,
The buffer tank,
When the liquefied gas stored in the bunkering tank is loaded into the liquefied gas storage tank, boil-off gas generated in the bunkering tank and the liquefied gas discharged from the liquefied gas storage tank are supplied and at least partially condensed and stored. , Bunkering ships. The method of claim 1,
The bunkering ship,
A power generation engine that uses liquefied gas as fuel to produce electric power;
A liquid transfer line connecting the bunkering tank and the manifold to flow a liquid liquefied gas;
A gas phase transfer line connecting the bunkering tank and the manifold to flow gaseous liquefied gas;
A gas processing line branching from the gas phase transfer line and supplying liquefied gas to the power generation engine; And
The bunkering vessel further comprises a condensation line branching from the gas treatment line and supplying liquefied gas to the buffer tank. The method of claim 2,
The gas treatment line,
A gas-liquid separator for separating the liquefied gas into a gas phase and a liquid phase and returning the liquid liquefied gas to the bunkering tank; And
It includes an LD compressor that receives gaseous liquefied gas from the gas-liquid separator, pressurizes it, and supplies it to the power generation engine,
The condensation line,
In the gas treatment line, the bunkering vessel branching from the lower end of the LD compressor. The method of claim 3,
The buffer tank,
In a state in which the liquid liquefied gas is stored in an internal space, the boil-off gas generated in the bunkering tank and the liquefied gas discharged from the liquefied gas storage tank are supplied and stored. The method of claim 4,
The buffer tank,
A liquid liquefied gas is stored at a water level of 40 to 80% with respect to the height of the inner space of the buffer tank,
The condensation line,
To inject liquefied gas into the liquid liquefied gas stored in the buffer tank, a bunkering vessel. The method of claim 5,
The bunkering ship,
The bunkering vessel further comprising a boil-off gas supply line for supplying boil-off gas generated in the buffer tank to the gas-liquid separator. The method of claim 6,
The bunkering ship,
When the internal pressure of the buffer tank is higher than a predetermined value, gaseous liquefied gas is supplied to at least one of a power generation engine and a gas combustion unit through the boil-off gas supply line. The method of claim 6,
The bunkering ship,
When the loading of the liquefied gas storage tank is completed, the liquid liquefied gas stored in the buffer tank is returned to the bunkering tank. The method of claim 8,
The bunkering ship,
When the liquid liquefied gas level with respect to the height of the internal space of the buffer tank is higher than 80%, the liquid liquefied gas stored in the buffer tank is returned to the bunkering tank. The method of claim 8,
The bunkering ship,
The liquid liquefied gas stored in the buffer tank is supplied to the gas-liquid separator, and the separated liquid liquefied gas is returned to the bunkering tank, and the separated gaseous liquefied gas is pressurized by the LD compressor and supplied to the power generation engine. It is a bunkering ship.

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