KR102219870B1 - Boil-off gas compression installation - Google Patents

Abstract

The present invention relates to a boil-off gas compression facility. Specifically, according to an embodiment of the present invention, a rotation shaft member including a first locking portion and a second locking portion; A first compression unit including a first engagement portion driven by being engaged with the first engagement portion, and a first compression cylinder portion for compressing an internal boil-off gas by power transmitted from the first engagement portion; A second compression unit including a second engagement portion driven by being engaged with the second engagement portion, and a second compression cylinder portion for compressing an internal boil-off gas by power transmitted from the second engagement portion; At one end, a first supply passage connected to the first compression cylinder portion and providing a flow path of the boil-off gas supplied to the first compression cylinder portion; And a first connection passage providing a flow path through which the boil-off gas compressed by the first compression unit flows to the second compression unit.

Description

Boil-off gas compression facility {BOIL-OFF GAS COMPRESSION INSTALLATION}

The present invention relates to a boil-off gas compression facility.

LNG (Liquefied Natural Gas, hereinafter referred to as "LNG"), a type of gaseous fuel, is a colorless, transparent cryogenic temperature that reduces the volume to 1/600 by cooling natural gas containing methane as its main component to -163℃. Liquid, generally referred to as liquefied natural gas.

These LNGs are transported over a long distance to their destination by LNG carriers in a cryogenically liquefied state at the production site. LNG carriers are to load LNG and operate the sea to unload LNG to customers onshore, and for this purpose, LNG carriers include LNG storage tanks that can withstand the cryogenic temperatures of LNG. LNG transported by an LNG carrier is stored in an onshore LNG terminal and then supplied to a consumer, or a floating LNG terminal equipped with a natural gas supply function by remodeling an LNG carrier, or a fixed offshore LNG in which a liquefied natural gas storage tank is settled on the seabed. It is sent to the consumer through the terminal.

Boil off gas is generated at these LNG terminals, and the boil-off gas compression facility compresses the LNG to the extent that it can be recondensed (low pressure compression) or compresses it to the high pressure required by the customer (high pressure compression) and sends it out. do. Normally, LNG is compressed to the pressure required for recondensation through a low-pressure compressor, recondensed, and then pressurized and sent out, and the high-pressure compressor pressurizes LNG to the pressure required by the customer temporarily as needed, making a separate recondensation process worthwhile. It does not send it directly. However, when the low pressure compressor and the high pressure compressor are separately installed, there is a problem that a large site and high cost are required.

Embodiments of the present invention are invented in the background as described above, and are intended to be configured to treat boil-off gas by selectively applying low-pressure compression and high-pressure compression with a single compression facility with relatively little space and low cost.

According to an aspect of the present invention, a rotation shaft member including a first locking portion and a second locking portion; A first compression unit including a first engagement portion driven by being engaged with the first engagement portion, and a first compression cylinder portion for compressing an internal boil-off gas by power transmitted from the first engagement portion; A second compression unit including a second engagement portion driven by being engaged with the second engagement portion, and a second compression cylinder portion for compressing an internal boil-off gas by power transmitted from the second engagement portion; At one end, a first supply passage connected to the first compression cylinder portion and providing a flow path of the boil-off gas supplied to the first compression cylinder portion; And a boil-off gas compression facility may be provided including a first connection passage providing a flow path for the boil-off gas compressed in the first compression unit to flow to the second compression unit.

In addition, a second discharge passage for providing a flow path for the boil-off gas compressed by the first compression unit to be discharged to the outside before flowing into the second compression unit; And a control unit for controlling at least one flow path of the first connection path and the second discharge path, wherein the control unit includes: the boil-off gas compressed in the first compression unit is externally transmitted through the second discharge path. Among the first flow modes discharged into the flow mode and the second flow mode in which the boil-off gas compressed in the first compression unit flows to the second compression unit through the first connection passage and is compressed in the second compression unit and discharged to the outside. A boil-off gas compression facility may be provided that controls the flow of boil-off gas to flow in any one flow mode.

In addition, further comprising a first discharge passage and a first return passage, wherein the first discharge passage provides a passage for discharging the boil-off gas discharged from the lowest compression unit among the plurality of compression units to the outside, the The first return passage may be provided with a boil-off gas compression facility that provides a passage for returning the boil-off gas discharged from the lowest compression unit among the plurality of compression units to the second compression unit.

In addition, the control unit, when in the first flow mode, some of the boil-off gas compressed in the first compression unit flows toward the second compression unit, but is discharged from the lowest compression unit among the plurality of compression units. A boil-off gas compression facility may be provided for controlling the flow of boil-off gas in the first discharge passage and the first return passage so that boil-off gas is returned to the second compression unit through the first return passage.

In addition, in the second flow mode, the control unit includes the first discharge passage and the first return passage so that the boil-off gas discharged from the lowest compression unit among the plurality of compression units is discharged through the first discharge passage. A boil-off gas compression facility may be provided for controlling the flow of boil-off gas in the inside.

In addition, when in the first flow mode, the amount of the boil-off gas flowing into the second compression unit through the first connection passage is controlled to be less than the amount of the boil-off gas discharged through the second discharge passage. Compression equipment may be provided.

Further, a third compression unit, a fourth compression unit, a second connection passage, a third connection passage, and a fourth connection passage further include, and the rotation shaft member further includes a third locking portion and a fourth locking portion, and the first 3 The compression unit includes a third engagement portion driven by engagement with the third engagement portion of the rotation shaft member, and a third compression cylinder portion compressing the internal boil-off gas by power transmitted from the third engagement portion, the The fourth compression unit includes a fourth engagement portion driven by engagement with the fourth engagement portion of the rotation shaft member, and a fourth compression cylinder portion compressing internal boil-off gas by power transmitted from the fourth engagement portion, The second connection passage provides a flow path through which the boil-off gas compressed by the second compression unit flows to the third compression unit, and the third connection passage is the boil-off gas compressed by the third compression unit. 4 Provides a flow path for flowing to the compression unit, and the fourth connection path provides a flow path for flowing the boil-off gas compressed in the first compression unit to the third compression unit, I can.

In addition, the first connection passage, the second connection passage and the third connection passage further comprises a control unit for controlling at least one flow path, the control unit, the boil-off gas compressed in the first compression unit A third flow mode flowing in parallel to the second compression unit and the third compression unit through the first connection passage and the fourth connection passage, and the boil-off gas compressed in the second compression unit is transferred to the third compression unit. A boil-off gas compression facility may be provided for controlling the flow of boil-off gas to flow in any one of the fourth flow modes of flow to the fourth compression unit after being introduced.

In addition, a first discharge passage for providing a passage for discharging the boil-off gas compressed by the fourth compression unit to the outside; And a third discharge passage providing a passage for discharging the boil-off gas compressed by the second compression unit and the third compression unit to the outside before flowing into the fourth compression unit, wherein the control unit comprises: In the third flow mode, the boil-off gas compressed in parallel in the second compression unit and the third compression unit is discharged to the outside through the third discharge passage, and in the fourth flow mode, the first compression unit to A boil-off gas compression facility may be provided for controlling the flow of boil-off gas so that boil-off gas compressed through the fourth compression unit is sequentially discharged to the outside through the first discharge passage.

In addition, the second compression unit further comprises a fifth connection passage for providing a flow path for the boil-off gas compressed in the second compression unit to flow to the fourth compression unit, and in the third flow mode, the second compression unit and the second compression unit 3 The boil-off gas compressed by entering the compression unit in parallel may be discharged through the fifth connection passage and the fourth connection passage to flow to the fourth compression unit, and a boil-off gas compression facility may be provided.

In addition, further comprising a second return passage for providing a flow path for the boil-off gas compressed in the fourth compression unit to be supplied back to the fourth compression unit, the control unit, when in the third flow mode, the second Some of the boil-off gas compressed by the compression unit and the third compression unit flows toward the fourth compression unit, and the boil-off gas discharged from the fourth compression unit is transferred to the fourth compression unit through the second return passage. To return, a boil-off gas compression facility may be provided that controls the flow of boil-off gas in the first discharge passage and the second return passage.

In addition, in the third flow mode, the amount of the boil-off gas introduced into the fourth compression unit through the third connection passage and the fifth connection passage is an amount of the boil-off gas discharged through the third discharge passage. Fewer, boil-off gas compression installations may be provided.

In addition, the second supply passage further comprises a third compression unit, a second connection passage, and a control unit, the rotation shaft member further includes a third locking portion, and the second supply passage has one end of the second compression cylinder portion And providing a flow path of the boil-off gas supplied to the second compression cylinder unit, the third compression unit being driven by engaging the third locking portion of the rotation shaft member, and the third engaging portion It includes a third compression cylinder part for compressing the internal boil-off gas by the power transmitted from, and the second connection passage provides a flow path for the boil-off gas compressed in the second compression unit to flow to the third compression unit. And, the control unit, in a fifth flow mode in which the boil-off gas flows in parallel to the first compression unit and the second compression unit through the first supply passage and the second supply passage, and in the first compression unit A boil-off gas compression facility is provided to control the flow of boil-off gas so that the compressed boil-off gas flows into the second compression unit and then flows in any one of the sixth flow modes flowing to the third compression unit. I can.

In addition, further comprising a fourth connection passage for providing a flow path for the boil-off gas compressed in the first compression unit to flow to the third compression unit, and in the fifth flow mode, the first compression unit and the The boil-off gas compressed by flowing into the second compression unit in parallel may be discharged through the fourth connection passage and the second connection passage to flow to the third compression unit, and a boil-off gas compression facility may be provided.

In addition, a first discharge passage, a fourth discharge passage, and a fourth compression unit further comprises, the rotation shaft member further includes a fourth locking portion, the first discharge passage is the boil-off gas compressed in the fourth compression unit A flow path for discharging to the outside is provided, and the fourth discharge path is routed to the outside of the boil-off gas compression facility before the boil-off gas compressed in the first compression unit and the second compression unit flows into the third compression unit. Provides a flow path for discharge, and the fourth compression unit compresses the internal boil-off gas by a fourth engagement portion driven by engagement with the fourth engagement portion of the rotation shaft member, and power transmitted from the fourth engagement portion. And a fourth compression cylinder unit, wherein the control unit, when in the fifth flow mode, the boil-off gas compressed in parallel in the first compression unit and the second compression unit is discharged to the outside through the fourth discharge passage In the sixth flow mode, the first discharge passage and the fourth discharge passage so that the boil-off gas compressed through the first compression unit to the fourth compression unit is discharged to the outside through the first discharge passage. A boil-off gas compression facility may be provided to control the flow of boil-off gas in at least one of the inside.

In addition, the fourth compression unit further includes a third return passage for providing a flow path through which the boil-off gas compressed by the fourth compression unit is supplied back to the fourth compression unit, and the control unit comprises: the first Some of the boil-off gas compressed by the compression unit and the second compression unit flows toward the third compression unit, and the boil-off gas discharged from the third compression unit is transferred to the fourth compression unit through the third return passage. To return, a boil-off gas compression facility may be provided that controls the flow of boil-off gas in the first discharge passage and the third return passage.

In addition, in the fifth flow mode, the amount of the boil-off gas introduced into the third compression unit through the second connection passage and the fourth connection passage is greater than the discharge amount of the boil-off gas discharged through the fourth discharge passage. Less, boil-off gas compression equipment can be provided.

According to embodiments of the present invention, low pressure compression and high pressure compression are selectively applied to evaporate while reducing the installation space of a compression facility for recondensing boil-off gas and a compression facility for sending boil-off gas to a customer. It has the effect of being able to process gas.

1 is a conceptual diagram of a boil-off gas compression facility according to a first embodiment of the present invention.
2 is a conceptual diagram showing a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 1 is in a first flow mode.
3 is a conceptual diagram showing a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 1 is in a second flow mode.
4 is a conceptual diagram of a boil-off gas compression facility according to a second embodiment of the present invention.
5 is a conceptual diagram showing a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 4 is in a third flow mode.
6 is a conceptual diagram showing a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 4 is in a fourth flow mode.
7 is a conceptual diagram of a boil-off gas compression facility according to a third embodiment of the present invention.
8 is a conceptual diagram illustrating a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 7 is in a fifth flow mode.
9 is a conceptual diagram showing a path through which the boil-off gas flows when the boil-off gas compression facility of FIG. 7 is in a sixth flow mode.
In FIGS. 2, 3, 5, 6, 8, and 9, the passage through which the boil-off gas flows is indicated in bold, and the passage through which the boil-off gas does not flow is indicated by thin.

Hereinafter, specific embodiments for implementing the spirit of the present invention will be described in detail with reference to the drawings.

In addition, when it is determined that a detailed description of a known configuration or function related to the present invention may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, when it is mentioned that an element is'connected','connected','supplied','transmitted', or'contacted' to another element, it will be directly connected, connected, supplied, transmitted, or contacted It may be possible, but it should be understood that other components may exist in the middle.

The terms used in the present specification are used only to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In addition, in the present specification, expressions such as the upper side, the lower side, and the side are described with reference to the drawings in the drawings, and it should be noted in advance that if the direction of the object is changed, it may be expressed differently. For the same reason, some components in the accompanying drawings are exaggerated, omitted, or schematically illustrated, and the size of each component does not entirely reflect the actual size.

In addition, terms including ordinal numbers such as first and second may be used to describe various elements, but the corresponding elements are not limited by these terms. These terms are only used for the purpose of distinguishing one component from another.

The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

At least part of the LNG in the LNG terminal may be naturally vaporized to become a gaseous LNG (boil-off gas). The boil-off gas compression facility 10 according to an embodiment of the present invention may receive and compress the gaseous LNG generated from the LNG terminal. Here, the LNG terminal or the like supplies the boil-off gas to the boil-off gas compression facility 10 and thus may serve as the supply unit 20.

Hereinafter, a specific configuration of the boil-off gas compression facility 10 according to the first embodiment of the present invention will be described with reference to FIG. 1.

Referring to FIG. 1, the boil-off gas compression facility 10 according to the first embodiment of the present invention may include a rotating shaft member 100, a compression part 200, a passage part 300, and a control unit 400. .

The rotation shaft member 100 may be connected to a driver such as a motor, and may be rotated by a driver to provide power for compressing the boil-off gas to the compression unit 200. The rotation shaft member 100 may include at least one locking part that can be engaged with the compression part 200. For example, the rotation shaft member 100 may include a first locking portion 110, a second locking portion 120, a third locking portion 130, and a fourth locking portion 140. The first locking portion 110, the second locking portion 120, the third locking portion 130, and the fourth locking portion 140 may be, for example, a cam, a rocker arm, and the rotation shaft member 100 is described later. It can act as a crankshaft by interlocking with the engaging part of the compression part.

The compression unit 200 may receive and compress evaporation gas such as gaseous LNG. The compression unit 200 may include a first compression unit 210, a second compression unit 220, a third compression unit 230, and a fourth compression unit 240 capable of compressing the boil-off gas.

The first compression unit 210 may receive and compress the boil-off gas from the supply unit 20. The first compression unit 210 may include a first engagement portion 211 and a first compression cylinder portion 212. The first engaging portion 211 may be engaged with the first locking portion 110 to operate, and may be, for example, a cam or a rocker arm. The first compression cylinder part 212 may compress the internal boil-off gas by power transmitted from the first engaging part 211. The first compression cylinder part 212 may be configured to compress gas introduced into the cylinder with a piston driven by the first engaging part 211. In addition, the first compression cylinder portion 212 may be provided in plurality.

The second compression unit 220 may receive the gas compressed by the first compression unit 210 and compress it again. The second compression unit 220 may include a configuration similar to the first compression unit 210. The second compression unit 220 may include a second engaging portion 221 and a second compression cylinder portion 222. The second engagement portion 221 may be a cam or rocker arm that engages with the second engagement portion 221 and operates, and the second compression cylinder portion 222 is internally driven by power transmitted from the second engagement portion 221. Boil-off gas can be compressed. In addition, the second compression cylinder portion 222 may be provided in plurality.

The third compression unit 230 may receive the gas compressed by the second compression unit 220 and compress it again. The third compression unit 230 may include a configuration similar to the first compression unit 210. The third compression unit 230 may include a third engagement portion 231 and a third compression cylinder portion 232. The third engagement portion 231 may be a cam or rocker arm that engages with the third engagement portion 231 and operates, and the third compression cylinder portion 232 is internally driven by power transmitted from the third engagement portion 231. Boil-off gas can be compressed. In addition, the third compression cylinder unit 232 may be provided in plural.

The fourth compression unit 240 may receive the gas compressed by the third compression unit 230 and compress it again. The fourth compression unit 240 may include a configuration similar to the first compression unit 210. The fourth compression unit 240 may include a fourth engagement portion 241 and a fourth compression cylinder portion 242. The fourth engagement portion 241 may be a cam or rocker arm that engages with the fourth engagement portion 241 and operates, and the fourth compression cylinder portion 242 is internally driven by the power transmitted from the fourth engagement portion 241. Boil-off gas can be compressed. In addition, the fourth compression cylinder portion 242 may be provided in plurality.

The first to fourth compression units 210, 220, 230, and 240 may be compressed by driving a single rotating shaft member 100. Further, the first to fourth compression units 210, 220, 230, and 240 may be provided in plural. In the drawing according to the present embodiment, it is shown that two first to fourth compression units 210, 220, 230, and 240 are provided, respectively, but the first to fourth compression units 210, 220, 230, 240 It is also possible that each is provided in a single number, and it is not excluded that each compression unit is provided in a number of more than two.

The passage part 300 may provide a passage through which the boil-off gas is transmitted from the supply unit 20 or flows between compression units, and the boil-off gas is discharged from the compression units. Meanwhile, since the passages constituting the passage part 300 may be branched or laminated to each other, only a part of the passage for flowing the boil-off gas may be provided between the constituent elements. In addition, other components may be configured to exist in the middle of the passage. In addition, a valve capable of opening and closing the passage may be provided in at least a part of the individual passage included in the passage part 300, and the opening and closing of the valve may be controlled by the controller 400.

This passage part 300 is a supply path for transferring the boil-off gas from the supply part to the compression part 200, a connection path for transferring the boil-off gas between the compression units of the compression part 200, and evaporation from the compression part 200 A discharge passage for discharging the boil-off gas to the outside of the gas compression facility 10 and a return passage for returning the boil-off gas discharged from the compression unit 200 to the connection passage between the plurality of compression units of the compression unit 200 Can include.

In addition, in the present embodiment, the supply passage includes a first supply passage 311, and the connection passage includes a first connection passage 321, a second connection passage 322 and a third connection passage 323, The discharge passage may include a first discharge passage 331 and a second discharge passage 332, and the return passage may include a first return passage 341. The first discharge passage 331 may function as an auxiliary discharge passage, and the second discharge passage 332 may function as a main discharge passage.

The main discharge passage may selectively discharge the boil-off gas delivered to any one of the plurality of compression units (for example, the second compression unit), and the return passage may be any one of the plurality of compression units ( For example, the boil-off gas discharged from the compression unit disposed at the most downstream of the plurality of compression units may be returned so that the boil-off gas is transferred to the second compression unit).

The first supply passage 311 may provide a passage through which the boil-off gas flows from the supply unit 20 toward the first compression unit 210. The first supply passage 311 may have one end connected to the first compression cylinder part 212 and the other end connected to the supply part 20. The flow of the boil-off gas in the first supply passage 311 may be selectively blocked by the control of the controller 400. In the present specification and claims, the meaning of “selectively shutting off” does not necessarily mean that it is physically closed or opened by a valve provided on the pipe.

The first connection passage 321 may provide a passage through which the boil-off gas flows from the first compression unit 210 to the second compression unit 220. One end of the first connection passage 321 may be connected to the first compression cylinder part 212, and the other end may be connected to the second compression cylinder part 222. In the present specification and claims,'connection' is used to include not only direct connection as in FIG. 1, but also indirect connection through other passages. The flow of the boil-off gas in the first connection passage 321 may be selectively blocked by the control of the controller 400.

For example, the flow of the boil-off gas in the second discharge passage 332 may be directly controlled by a valve provided on the second discharge passage 332, but the spirit of the present invention is necessarily limited thereto. no.

The second connection passage 322 may provide a passage through which the boil-off gas flows from the second compression unit 220 toward the third compression unit 230. The second connection passage 322 may have one end connected to the second compression cylinder part 222, and the other end may be connected to the third compression cylinder part 232. The flow of the boil-off gas in the second connection passage 322 may be selectively blocked by the control of the controller 400.

The third connection passage 323 may provide a passage through which the boil-off gas flows from the third compression unit 230 toward the fourth compression unit 240. The third connection passage 323 may have one end connected to the third compression cylinder part 232, and the other end may be connected to the fourth compression cylinder part 242. The flow of the boil-off gas in the third connection passage 323 may be selectively blocked by the control of the controller 400.

The first discharge passage 331 may provide a passage for discharging the boil-off gas compressed and discharged from the compression unit arranged at the most downstream of the compression unit 200 to the outside of the boil-off gas compression facility 10. When four compression units are provided in the boil-off gas compression facility 10 as in this embodiment, the first discharge passage 331 is a fourth discharge path 331 to discharge the boil-off gas compressed by the fourth compression unit 240 and discharged. It may be connected to the compression unit 240. The flow of the boil-off gas in the first discharge passage 331 may be selectively blocked by the control of the controller 400. This first discharge passage 331 may function as an auxiliary discharge passage.

The second discharge passage 332 may provide a passage through which the boil-off gas compressed in the first compression unit 210 is not introduced into the second compression unit 220 but is discharged to the outside. The flow of the boil-off gas in the second discharge passage 332 may be selectively blocked by the control of the controller 400. In the drawings according to the present embodiment, it is shown that the second discharge passage 332 is branched from the first connection passage 321, but is not limited thereto. This second discharge passage 332 may function as a main discharge passage.

The first return passage 341 provides a passage for returning the boil-off gas discharged from the downstream compression unit to the second compression unit 220 without being discharged through the first discharge passage 331. For example, when including four compression units as shown in the drawing, the first return passage 341 may return the boil-off gas discharged from the fourth compression unit 240 to the second compression unit 220 . The first return passage 341 may include one end receiving the boil-off gas discharged from the fourth compression unit 240. One end of the first return passage 341 may be configured to be branched from the first discharge passage 331 as shown in FIG. 1 for example.

In addition, the other end of the first return passage 341 may include the other end for transmitting the boil-off gas returned toward the second compression unit 220. The other end of the first return passage 341 may be configured to be bonded to the second connection passage 322 as shown in FIG. 1 as an example, but as another example, it is configured to form a passage separate from the first connection passage 321 It could be. The flow of the boil-off gas in the first return passage 341 may be selectively blocked by the control of the controller 400.

The controller 400 may control the flow of the boil-off gas in at least one of the passages of the passage portion 300 so that the boil-off gas flows in a different flow mode in the passage portion 300. For example, the control unit 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the valve provided in the passage part 300. This control unit 400 may be implemented by a computing device including a microprocessor, and the implementation method is obvious to those skilled in the art, and thus further detailed description thereof will be omitted.

The boil-off gas in the boil-off gas compression facility 10 may flow in different flow modes by the control unit 400. For example, the boil-off gas in the boil-off gas compression facility 10 may be compressed by flowing in any one of the first flow mode and the second flow mode.

In the first flow mode and the second flow mode, the boil-off gas discharged from the supply unit 20 is delivered to the first compression unit 210 through the first supply passage 311. Hereinafter, the first flow mode and the second flow mode will be described with further reference to FIGS. 2 and 3.

Referring to FIG. 2, in the first flow mode, most of the boil-off gas compressed in the first compression unit 210 does not flow to the second compression unit 220, but compresses the boil-off gas through the second discharge passage 332. It may be discharged to the outside of the facility 10. The control unit 400 controls the opening and closing of a valve that may be provided on the passage and/or a valve that may be provided at the outlet side of the compression unit (210, 220, 230, 240) so that the boil-off gas flows in the first flow mode. Thus, the flow of the boil-off gas in the passage can be controlled. For example, the control unit 400 closes a valve (not shown) provided at the outlet side of the second to fourth compression units 220, 230, and 240, and closes the valve provided on the second discharge passage 332. By opening the boil-off gas compression facility 10 can be placed in the first flow mode. This first flow mode may be a low pressure compression flow mode.

On the other hand, in the first flow mode, the remaining part of the boil-off gas compressed in the first compression unit 210 is not discharged to the outside of the boil-off gas compression facility 10 through the second discharge passage 332 and is compressed for the second time. It can flow to the unit 220. In the first flow mode, the amount of gas flowing from the first compression unit 210 to the second compression unit 220 may be less than the amount of the boil-off gas discharged to the second discharge passage 332, and the amount is very small. Can be The boil-off gas introduced into the second compression unit 220 flows to the lowermost compression unit, and the boil-off gas discharged from the lowermost compression unit passes through the first return passage 341 to a second discharge passage corresponding to the main discharge passage. The returned boil-off gas can be delivered to the same connection path as the connection path to which the discharge path 332 is connected.

In this first flow mode, the second compression unit 220, the third compression unit 220 so that the second compression unit 220, the third compression unit 230, and the fourth compression unit 240 do not compress the boil-off gas. 230) and the unloader valve of the compression cylinder portion of the fourth compression unit 240 are opened. Accordingly, in the first flow mode, the second compression unit 220, the third compression unit 230, and the fourth compression unit 240 rotate by the rotation shaft member 100, but do not contribute to compression of the boil-off gas.

The first return passage 341 may return the boil-off gas discharged from the fourth compression unit 240 and deliver the boil-off gas to the second connection passage 322 to deliver the boil-off gas back to the second compression unit 220. By allowing a very small amount of boil-off gas to be returned to the compression unit provided downstream of the main discharge passage, even the compression unit not involved in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 by the rotary shaft member 100 Even if it is rotated, it is possible to prevent the mechanical wear from intensifying by operating in a dry state in a compression unit that is not involved in the compression process of the boil-off gas. In addition, a cooler (not shown) may be installed to prevent an increase in temperature that may occur due to infinite circulation in a closed state in compression units not involved in compression. Such a cooler may be installed in the connection passage. For example, the cooler may be an air cooler. Accordingly, the risk of damage or failure of the second compression unit 220 to the fourth compression unit 240, which are compression units not involved in the compression process of the boil-off gas, can be significantly reduced.

Referring to FIG. 3, in the second flow mode, the boil-off gas compressed in the first compression unit 210 does not flow through the second discharge passage 332 and passes through the second compression unit 220 and the downstream compression unit. It may be discharged through the first discharge passage 331. The controller 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the passage so that the boil-off gas flows in the second flow mode. For example, when a valve is provided in each of the second connection passage 322 and the second discharge passage 332, the controller 400 opens the valve provided in the second connection passage 322 and the second discharge passage By controlling the valve provided on 332 to close, the boil-off gas compression facility 10 can be placed in the second flow mode. In the second flow mode, the second discharge passage 332 may be completely closed. This second flow mode may be a high pressure compression flow mode.

On the other hand, in the second flow mode, the boil-off gas discharged from the fourth compression unit 240, which is the lowest compression unit, is not returned. Accordingly, the total amount of the boil-off gas discharged from the downstream compression unit may be supplied to the supply source through the first discharge passage 331 which is an auxiliary discharge passage. Even in the low-pressure compression flow mode, even the compression unit that does not participate in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 is rotated by the rotating shaft member 100, so there is no need to control the operation of the compression unit. By simply controlling the flow of the boil-off gas, it is possible to quickly switch between the low-pressure compression flow mode and the high-pressure compression flow mode.

Meanwhile, in the present embodiment, it has been described that the compression unit 200 includes four compression units, but the spirit of the present invention is not necessarily limited thereto. For example, in the compression unit, the fourth compression unit 240 and the third connection passage 323 may be omitted. In this case, the third compression unit 230 becomes a compression unit disposed at the most downstream, and the first return passage 341 is configured to return the boil-off gas compressed by the third compression unit 230, and the second discharge The passage 332 may be configured to discharge the boil-off gas compressed by the third compression unit 230 to the outside.

Meanwhile, in addition to this configuration, according to the second embodiment of the present invention, the connection passage, the discharge passage, and the return passage may be configured differently. Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 4 to 6. In the description of the second embodiment, differences compared to the above-described embodiment are mainly described, and the same description and reference numerals refer to the above-described embodiment.

First, referring to FIG. 4, the compression unit 200 may include a first compression unit 210 to a fourth compression unit 240, and the passage unit 300 includes a first supply passage 311 and a first A connection passage 321 to a third connection passage 323 may be included. The first compression unit 210 to the fourth compression unit 240 of the compression unit 200 and the first supply passage 311 of the passage unit 300, the first connection passage 321 to the third connection passage 323 ) Is the same as the description in the first embodiment, so the description in the above-described first embodiment is used.

According to this embodiment, compared to the first embodiment, the connection passage of the passage part 300 further includes a fourth connection passage 324 and a fifth connection passage 325, and the discharge passage of the passage part 300 A third discharge passage 333 is included instead of the second discharge passage 332, and the return passage of the passage portion 300 may include a second return passage 342 instead of the first return passage 341.

The fourth connection passage 324 may provide a passage through which the boil-off gas flows from the first compression unit 210 to the third compression unit 230. The third connection passage 323 may have one end indirectly connected to the first compression cylinder part 212 through the first connection passage 321, and the other end may be connected to the third compression cylinder part 232. The flow of the boil-off gas in the fourth connection passage 324 may be selectively blocked by the control of the controller 400. Meanwhile, in the drawings according to the present embodiment, it is shown that the fourth connection passage 324 is branched from the first connection passage 321, but the spirit of the present invention is not necessarily limited thereto.

The fifth connection passage 325 may provide a passage through which the boil-off gas flows from the second compression unit 220 toward the fourth compression unit 240. The fifth connection passage 325 may have one end connected to the second compression cylinder part 222, and the other end may be indirectly connected to the third compression cylinder part 232 through the third connection passage 323. The flow of the boil-off gas in the fifth connection passage 325 may be selectively blocked by the control of the controller 400.

The third discharge passage 333 may provide a passage through which boil-off gas before entering the lowermost compression unit is discharged to the outside without flowing into the fourth compression unit 240. For example, when four compression units are provided as shown in the drawing, the third discharge passage 333 may be externally provided before the boil-off gas compressed by the third compression unit 210 is introduced into the fourth compression unit 240. It can be configured to be able to discharge. The flow of the boil-off gas in the third discharge passage 333 may be selectively blocked by the control of the controller 400. In the drawing according to the present embodiment, it is shown that the third discharge passage 333 is branched from the passage in which the third connection passage 321 and the fifth connection passage 325 are joined, but is not limited thereto. It is also possible to configure the connection passage and the fifth connecting passage and a separate passage. This third discharge passage 333 may serve as a main discharge passage.

In this third flow mode, the unloader valve of the compression cylinder portion of the fourth compression unit 240 is opened so that the fourth compression unit 240 does not compress the boil-off gas. Therefore, the fourth compression unit 240 rotates by the rotation shaft member 100, but does not contribute to compression of the boil-off gas.

The second return passage 342 provides a passage for returning the boil-off gas compressed and discharged by the lowermost compression unit to the lowermost compression unit without being discharged through the first discharge passage 331. For example, when including four compression units as shown in the drawing, the second return passage 342 may return the boil-off gas discharged from the fourth compression unit 240 to the fourth compression unit 240 . The second return passage 342 may include one end receiving the boil-off gas discharged from the fourth compression unit 240. One end of the second return passage 342 may be configured to be branched from the first discharge passage 331 as shown in FIG. 4 as an example, but as another example, the first discharge passage 331 and a separate passage may be formed. May be.

In addition, the other end of the second return passage 342 may include the other end of transmitting the boil-off gas toward the fourth compression unit 240. The other end of the second return passage 342 may be configured to deliver the returned boil-off gas by being joined to the passage in which the third connecting passage 321 and the fifth connecting passage 325 are combined as shown in FIG. However, as another example, the third connection passage 321 and the fifth connection passage 325 may be configured to form a separate passage. The flow of the boil-off gas in the second return passage 342 may be selectively blocked by the control of the controller 400.

The boil-off gas in the boil-off gas compression facility 10 may flow in different flow modes by the control unit 400. For example, the boil-off gas in the boil-off gas compression facility 10 may be compressed by flowing in a third flow mode and a fourth flow mode.

In the third flow mode and the fourth flow mode, the boil-off gas discharged from the supply unit 20 is delivered to the first compression unit 210 through the first supply passage 311, and discharged from the first compression unit 210. The boil-off gas is delivered to the second compression unit 220 through the first connection passage 321. Hereinafter, a third flow mode and a fourth flow mode will be described with further reference to FIGS. 5 and 6.

Referring to FIG. 5, in the third flow mode, the boil-off gas compressed by the first compression unit 210 flows and is delivered to the second compression unit 220 and the third compression unit 230 in parallel. Approximately 50% of the boil-off gas discharged from the first compression unit 210 is supplied to the second compression unit 220, and the remaining approximately 50% of the boil-off gas discharged from the first compression unit 210 is a third compression unit. Supplied to 230.

In the third flow mode, since the boil-off gas does not flow in the second connection passage 322, the gas discharged from the second compression unit 220 does not flow to the third compression unit 230. The boil-off gas compressed in the second compression unit 220 and the third compression unit 230 flows in parallel through the second connection passage 322 and the fifth connection passage 325 to form the second compression unit 220 and It is discharged from each of the third compression units 230. The connection passage may be configured such that the boil-off gas discharged from the second compression unit 220 and the third compression unit 230 are combined.

The controller 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the passage so that the boil-off gas flows in the third flow mode. For example, when a valve is provided in each of the second connection passage 322 and the fourth connection passage 324, the control unit 400 closes the valve provided in the second connection passage 322 and the fourth connection passage By opening the valve provided on the 324, the boil-off gas compression facility 10 can be placed in the third flow mode. This third flow mode may be a low pressure compression flow mode.

In the third flow mode, most of the boil-off gas compressed in the first compression unit 210 to the third compression unit 230 does not flow to the fourth compression unit 240 and evaporates through the third discharge passage 333 It may be discharged to the outside of the gas compression facility (10).

Meanwhile, in the third flow mode, the boil-off gas compressed in the first compression unit 210 to the third compression unit 230 is discharged to the outside of the boil-off gas compression facility 10 through the third discharge passage 333 It is not possible to flow to the fourth compression unit 240. In the third flow mode, the amount of gas flowing from the second compression unit 220 and the third compression unit 230 to the fourth compression unit 240 is greater than the amount of the boil-off gas discharged through the third discharge passage 333 It can be less, and the amount can be very small. The boil-off gas introduced into the fourth compression unit 240 transmits the boil-off gas returned to the same connection passage as the connection passage to which the third discharge passage 333 corresponding to the main discharge passage is connected through the second return passage 342. I can.

The second return passage 342 may return the boil-off gas discharged from the fourth compression unit 240 and deliver it to the fourth connection passage 324 to deliver gaseous fuel back to the fourth compression unit 240. By allowing a very small amount of boil-off gas to be returned to the compression unit provided downstream of the main discharge passage, even the compression unit not involved in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 by the rotary shaft member 100 Even if it is rotated, it is possible to prevent the mechanical wear from intensifying by operating in a dry state in a compression unit that is not involved in the compression process of the boil-off gas. Accordingly, the risk of damage or failure of the fourth compression unit 240, which is a compression unit not involved in the compression process of the boil-off gas, can be significantly reduced.

Referring to FIG. 6, in the fourth flow mode, the boil-off gas compressed in the first compression unit 210 is sequentially flowed and delivered to the second compression unit 220 and the third compression unit 230. In other words, the boil-off gas compressed by the first compression unit 210 is delivered to the second compression unit 220 and compressed, and then delivered to the third compression unit 230 and compressed. In the fourth flow mode, since the boil-off gas does not flow in the fourth connection passage 324, the gas discharged from the first compression unit 210 does not flow directly to the third compression unit 230. The boil-off gas sequentially compressed in the second compression unit 220 and the third compression unit 230 is delivered to the fourth compression unit 240 through the third connection passage 323.

The controller 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the passage so that the boil-off gas flows in the fourth flow mode. For example, when a valve is provided on the second connection passage 322 and the fourth connection passage 324, the control unit 400 opens the valve provided in the second connection passage 322 and the fourth connection passage By closing the valve provided on the 324, the boil-off gas compression facility 10 can be placed in the fourth flow mode. This fourth flow mode may be a high pressure compression flow mode.

In the fourth flow mode, the boil-off gas compressed in the first compression unit 210 to the third compression unit 230 does not flow to the third discharge passage 333, but the second compression unit 220 and its downstream are compressed. It can be discharged to the outside through the unit. In the fourth flow mode, the third discharge passage 333 may be completely closed.

On the other hand, in the fourth flow mode, the boil-off gas discharged from the fourth compression unit 240, which is the lowest compression unit, is not returned. Accordingly, the total amount of the boil-off gas discharged from the downstream compression unit may be supplied to the supply source through the first discharge passage 331 which is an auxiliary discharge passage. Even in the low-pressure compression flow mode, even the compression unit that does not participate in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 is rotated by the rotating shaft member 100, so there is no need to control the operation of the compression unit. By simply controlling the flow of the boil-off gas, it is possible to quickly switch between the low-pressure compression flow mode and the high-pressure compression flow mode.

Meanwhile, in addition to this configuration, according to the third embodiment of the present invention, the connection passage, the discharge passage, and the return passage may be configured differently. Hereinafter, a third embodiment of the present invention will be described with reference to FIGS. 7 to 9. In the description of the third embodiment, differences compared to the above-described embodiments are mainly described, and the same description and reference numerals refer to the above-described embodiments.

First, referring to FIG. 7, the compression unit 200 may include a first compression unit 210 to a fourth compression unit 240, and the passage unit 300 includes a first supply passage 311 and a first A connection passage 321 to a third connection passage 323 may be included. The first compression unit 210 to the fourth compression unit 240 of the compression unit 200 and the first supply passage 311 of the passage unit 300, the first connection passage 321 to the third connection passage 323 ) Is the same as the description in the first embodiment, so the description in the above-described first embodiment is used.

According to the present embodiment, compared to the first embodiment, the supply passage of the passage portion 300 further includes a second supply passage 312, and the connection passage of the passage portion 300 includes a fourth connection passage 324. It further includes, and the discharge passage of the passage part 300 includes a fourth discharge passage 334 instead of the second discharge passage 332, and the return passage of the passage part 300 is provided instead of the first return passage 341 3 may include a return passage (343).

The second supply passage 312 may provide a passage through which the boil-off gas flows from the supply unit 20 toward the second compression unit 220. The second supply passage 312 may have one end connected to the second compression cylinder part 222 and the other end connected to the supply part 20. The flow of the boil-off gas in the second supply passage 312 may be selectively blocked by the control of the controller 400. In the drawing according to the present embodiment, the second supply passage 312 is shown to be branched from the first supply passage 311, but is not limited thereto, and may be provided separately from the first supply passage 311.

The fourth connection passage 324 may provide a passage through which the boil-off gas flows from the first compression unit 210 to the third compression unit 230. The third connection passage 323 may have one end indirectly connected to the first compression cylinder part 212 through the first connection passage 321, and the other end may be connected to the third compression cylinder part 232. The flow of the boil-off gas in the fourth connection passage 324 may be selectively blocked by the control of the controller 400. On the other hand, in the other drawings in the present embodiment, it is shown that the fourth connection passage 324 is branched from the first connection passage 321, but it is also possible to configure the first connection passage 321 and a separate passage.

The fourth discharge passage 334 may provide a passage through which the boil-off gas before entering the third compression unit 230 does not flow into the third compression unit 230 and is discharged to the outside. For example, as shown in the drawing, when four compression units are provided, the fourth discharge passage 334 is external before the boil-off gas compressed in the second compression unit 210 flows into the third compression unit 230. It can be configured to be able to discharge. The flow of the boil-off gas in the fourth discharge passage 334 may be selectively blocked by the control of the controller 400. In the drawing according to the present embodiment, it is shown that the fourth discharge passage 334 is branched from the passage in which the third connection passage 321 and the fifth connection passage 325 are joined, but is not necessarily limited thereto. It is also possible to configure the connection passage and the fifth connecting passage and a separate passage. This fourth discharge passage 334 may serve as a main discharge passage.

In this fifth flow mode, the third compression unit 230 and the fourth compression unit 240 do not compress the boil-off gas so that the unloader of the compression cylinder portion of the third compression unit 230 and the fourth compression unit 240 The valve is opened. Accordingly, in the fifth flow mode, the third compression unit 230 and the fourth compression unit 240 rotate by the rotation shaft member 100, but do not contribute to compression of the boil-off gas.

The third return passage 343 provides a passage for returning the boil-off gas compressed and discharged by the lowermost compression unit to the lowermost compression unit without being discharged through the first discharge passage 331. For example, in the case of including four compression units as shown in the drawing, the third return passage 343 may return the boil-off gas discharged from the fourth compression unit 240 to the fourth compression unit 240 . The third return passage 343 may include one end receiving the boil-off gas discharged from the fourth compression unit 240. One end of the third return passage 343 may be configured to be branched from the first discharge passage 331 as shown in FIG. 7 as an example, but as another example, the first discharge passage 331 and a separate passage may be formed. May be.

In addition, the other end of the third return passage 343 may include the other end of transmitting the boil-off gas toward the third compression unit 230. The other end of the third return passage 343 may be configured to deliver the returned boil-off gas by being joined to the passage in which the second connecting passage 322 and the fourth connecting passage 324 are combined as shown in FIG. However, as another example, the second connection passage 322 and the fourth connection passage 324 may be configured to form a separate passage. The flow of the boil-off gas in the third return passage 343 may be selectively blocked by the control of the controller 400.

The boil-off gas in the boil-off gas compression facility 10 may flow in different flow modes by the control unit 400. For example, the boil-off gas in the boil-off gas compression facility 10 may be compressed by flowing in a fifth flow mode and a sixth flow mode.

In the fifth flow mode and the sixth flow mode, at least a portion of the boil-off gas discharged from the supply unit 20 is delivered to the first compression unit 210 through the first supply passage 311. Hereinafter, the first flow mode and the second flow mode will be described with further reference to FIGS. 8 and 9.

Referring to FIG. 8, in the fifth flow mode, the boil-off gas delivered from the supply unit 20 flows and is delivered to the first compression unit 210 and the second compression unit 220 in parallel. Approximately 50% of the boil-off gas delivered from the supply unit 20 is supplied to the first compression unit 210, and the remaining approximately 50% of the boil-off gas delivered from the supply unit 20 is supplied to the second compression unit 220 . In the fifth flow mode, since the boil-off gas does not flow in the first connection passage 321, the gas discharged from the first compression unit 210 does not flow to the second compression unit 220. The boil-off gas compressed in the first compression unit 210 and the second compression unit 220 flows in parallel through the first connection passage 321 and the fourth connection passage 324 to form the first compression unit 210 and It is discharged from each of the second compression units 220.

The connection passage may be configured such that the boil-off gas discharged from the first compression unit 210 and the second compression unit 220 is combined. The controller 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the passage so that the boil-off gas flows in the fifth flow mode. For example, when a valve is provided in each of the second supply passage 312 and the first connection passage 331, the control unit 400 closes the valve provided in the first connection passage 331 and the second supply passage By opening the valve provided on 312, the boil-off gas compression facility 10 can be placed in the fifth flow mode. This fifth flow mode may be a low pressure compression flow mode.

In the fifth flow mode, most of the boil-off gas compressed in the first compression unit 210 to the second compression unit 220 does not flow to the third compression unit 230 and evaporates through the fourth discharge passage 334 It may be discharged to the outside of the gas compression facility (10).

On the other hand, in the fifth flow mode, the remaining part of the boil-off gas compressed in the first compression unit 210 to the second compression unit 220 is passed through the fourth discharge passage 334 through the boil-off gas compression facility 10 It may flow to the third compression unit 230 without being discharged to the outside. In the fifth flow mode, the amount of gas flowing from the first compression unit 210 and the second compression unit 220 to the third compression unit 230 is greater than the amount of the boil-off gas discharged through the fourth discharge passage 334 It can be less, and the amount can be very small.

The boil-off gas introduced into the fourth compression unit 240 flows to the fourth compression unit 240, which is the lowest compression unit, and the boil-off gas discharged from the fourth compression unit 240 is a third return passage 343 Through the fourth discharge passage 334 corresponding to the main discharge passage, it is possible to deliver the returned boil-off gas to the same connection passage as the connection passage. The third return passage 343 may return the boil-off gas discharged from the fourth compression unit 240 and transmit the boil-off gas to the third connection passage 323 to deliver the boil-off gas to the third compression unit 230.

By allowing a very small amount of boil-off gas to be returned to the compression unit provided downstream of the main discharge passage, even the compression unit not involved in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 by the rotary shaft member 100 Even if it is rotated, it is possible to prevent the mechanical wear from intensifying by operating in a dry state in a compression unit that is not involved in the compression process of the boiled gas. Accordingly, the risk of damage or failure of the third compression unit 230 to the fourth compression unit 240, which are compression units not involved in the compression process of the boil-off gas, can be significantly reduced.

Referring to FIG. 9, in the sixth flow mode, the boil-off gas delivered from the supply unit 20 is sequentially flowed and delivered to the first compression unit 210 and the second compression unit 220. In other words, the boil-off gas delivered from the supply unit 20 is delivered to the first compression unit 210 and compressed, and then delivered to the second compression unit 220 and compressed. In the sixth flow mode, since the boil-off gas does not flow in the second supply passage 312, the gas discharged from the supply unit 20 does not flow directly to the second compression unit 220.

The boil-off gas sequentially compressed in the first compression unit 210 and the second compression unit 220 is delivered to the third compression unit 230 through the second connection passage 322. In addition, the boil-off gas compressed and discharged by the third compression unit 230 is delivered to the fourth compression unit 240 and compressed. The controller 400 may control the flow of the boil-off gas in the passage by controlling the opening and closing of the passage so that the boil-off gas flows in the sixth flow mode.

For example, when a valve is provided on the second supply passage 312 and the first connection passage 321, the control unit 400 opens the valve provided in the second supply passage 312 and the first connection passage By closing the valve provided on 331, the boil-off gas compression facility 10 can be placed in the sixth flow mode. This sixth flow mode may be a high pressure compression flow mode.

In the sixth flow mode, the boil-off gas compressed in the first compression unit 210 to the third compression unit 230 does not flow to the fourth discharge passage 334 and the second compression unit 220 and its downstream are compressed. It can be discharged to the outside through the unit.

Meanwhile, in the sixth flow mode, the boil-off gas discharged from the fourth compression unit 240, which is the lowest compression unit, is not returned. Accordingly, the total amount of the boil-off gas discharged from the downstream compression unit may be supplied to the supply source through the first discharge passage 331 which is an auxiliary discharge passage. Even in the low pressure compression flow mode, even the compression unit that is not involved in the compression process of the boil-off gas discharged to the outside of the boil-off gas compression facility 10 is rotated by the rotating shaft member 100, so that the operation of the compression unit is not controlled, By simply controlling the flow of the boil-off gas, it is possible to quickly switch between the low-pressure compression flow mode and the high-pressure compression flow mode.

The embodiments of the present invention have been described above as specific embodiments, but these are only examples, and the present invention is not limited thereto, and should be construed as having the widest scope in accordance with the basic idea disclosed herein. A person skilled in the art may combine/substitute the disclosed embodiments to implement a pattern of a shape not indicated, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is clear that such changes or modifications also belong to the scope of the present invention.

10: boil-off gas compression facility 20: supply
100: rotation shaft member 200: compression unit
210: first compression unit 211: first engaging portion
212: first compression cylinder 220: second compression unit
221: second engaging portion 222: second compression cylinder portion
230: third compression unit 231: third engaging portion
232: third compression cylinder unit 240: fourth compression unit
241: second engaging portion 242: fourth compression cylinder portion
300: passage part 311: first supply passage
312: second supply passage 321: first connection passage
322: second connection passage 323: third connection passage
324: the fourth connecting passage 325: the fifth connecting passage
331: first discharge passage 332: second discharge passage
333: third discharge passage 334: fourth discharge passage
341: first return passage 342: second return passage
343: third return passage 400: control unit

Claims (17)

A rotation shaft member including a first locking portion and a second locking portion;
A first compression unit including a first engagement portion driven by being engaged with the first engagement portion, and a first compression cylinder portion for compressing an internal boil-off gas by power transmitted from the first engagement portion;
A second compression unit including a second engagement portion driven by being engaged with the second engagement portion, and a second compression cylinder portion for compressing an internal boil-off gas by power transmitted from the second engagement portion;
A first supply passage having one end connected to the first compression cylinder portion and providing a flow path of the boil-off gas supplied to the first compression cylinder portion;
A first connection passage providing a flow path through which the boil-off gas compressed by the first compression unit flows to the second compression unit;
A first discharge passage providing a passage through which the boil-off gas discharged from the second compression unit is discharged to the outside;
A second discharge passage for providing a flow path through which the boil-off gas compressed by the first compression unit is discharged to the outside before flowing into the second compression unit;
A first return passage providing a flow path for returning the boil-off gas discharged from the second compression unit to the second compression unit; And
A control unit for controlling at least one of the first supply passage, the first connection passage, the first discharge passage, the second discharge passage, and the first return passage,
The control unit,
The first flow mode in which the boil-off gas compressed in the first compression unit is discharged to the outside through the second discharge passage, and the boil-off gas compressed in the first compression unit is the second compression unit through the first connection passage. And controlling the flow of the boil-off gas to flow in any one of the flow modes of the second flow mode, which is compressed in the second compression unit and discharged to the outside,
In the first flow mode, some of the boil-off gas compressed in the first compression unit flows toward the second compression unit, and the boil-off gas discharged from the second compression unit flows toward the second compression unit. 2 configured to control the flow of the boil-off gas in the first discharge passage and the first return passage so as to be returned to the compression unit,
In the first flow mode, the amount of the boil-off gas introduced into the second compression unit through the first connection passage is controlled to be less than the amount of the boil-off gas discharged through the second discharge passage,
Boil-off gas compression facility. delete delete delete The method of claim 1,
The control unit,
In the second flow mode, controlling the flow of the boil-off gas in the first discharge passage and the first return passage so that the boil-off gas discharged from the second compression unit is discharged through the first discharge passage,
Boil-off gas compression facility. delete A rotation shaft member including a first locking portion, a second locking portion, a third locking portion, and a fourth locking portion;
A first compression unit including a first engagement portion driven by being engaged with the first engagement portion, and a first compression cylinder portion for compressing an internal boil-off gas by power transmitted from the first engagement portion;
A second compression unit including a second engagement portion driven by being engaged with the second engagement portion, and a second compression cylinder portion for compressing an internal boil-off gas by power transmitted from the second engagement portion;
A third compression unit including a third engagement portion driven by engagement with the third engagement portion of the rotation shaft member, and a third compression cylinder portion compressing the boil-off gas inside by power transmitted from the third engagement portion;
A fourth compression unit including a fourth engagement portion driven by engagement with the fourth locking portion of the rotation shaft member, and a fourth compression cylinder portion compressing the boil-off gas inside by power transmitted from the fourth engagement portion;
A first supply passage having one end connected to the first compression cylinder portion and providing a flow path of the boil-off gas supplied to the first compression cylinder portion;
A first connection passage providing a flow path through which the boil-off gas compressed by the first compression unit flows to the second compression unit;
A second connection passage providing a flow path through which the boil-off gas compressed by the second compression unit flows to the third compression unit;
A third connection passage providing a flow path through which the boil-off gas compressed by the third compression unit flows to the fourth compression unit;
A fourth connection passage for providing a flow path for the boil-off gas compressed in the first compression unit to flow to the third compression unit;:
A fifth connection passage providing a flow path through which the boil-off gas compressed by the second compression unit flows to the fourth compression unit;
A first discharge passage providing a passage through which the boil-off gas compressed by the fourth compression unit is discharged to the outside;
A third discharge passage providing a flow path for discharging the boil-off gas compressed by the second compression unit and the third compression unit to the outside before flowing into the fourth compression unit;
A second return passage for providing a flow path through which the boil-off gas compressed by the fourth compression unit is supplied back to the fourth compression unit; And
And a control unit for controlling at least one of the first to fifth connection passages, the first discharge passage, the third discharge passage, and the second return passage,
The control unit,
The third flow mode and the second compression unit in which the boil-off gas compressed in the first compression unit flows in parallel to the second compression unit and the third compression unit through the first connection passage and the fourth connection passage. Controls the flow of the boil-off gas so that the boil-off gas compressed in is introduced into the third compression unit and then flows in any one of the fourth flow modes flowing to the fourth compression unit,
In the third flow mode, the boil-off gas compressed in parallel in the second compression unit and the third compression unit is discharged to the outside through the third discharge passage, while the second compression unit and the third compression Some of the boil-off gas compressed by the unit flows toward the fourth compression unit through the third connection passage and the fifth connection passage, and the boil-off gas discharged from the fourth compression unit passes through the second return passage. Controlling the flow of boil-off gas in the first discharge passage and the second return passage so as to be returned to the fourth compression unit,
In the third flow mode, the amount of the boil-off gas introduced into the fourth compression unit is less than the amount of the boil-off gas discharged through the third discharge passage,
Boil-off gas compression facility. delete The method of claim 7,
The control unit,
In the fourth flow mode, controlling the flow of the boil-off gas so that the boil-off gas compressed through the first compression unit to the fourth compression unit is discharged to the outside through the first discharge passage,
Boil-off gas compression facility. delete delete delete A rotation shaft member including a first locking portion, a second locking portion, a third locking portion, and a fourth locking portion;
A first compression unit including a first engagement portion driven by being engaged with the first engagement portion, and a first compression cylinder portion for compressing an internal boil-off gas by power transmitted from the first engagement portion;
A second compression unit including a second engagement portion driven by being engaged with the second engagement portion, and a second compression cylinder portion for compressing an internal boil-off gas by power transmitted from the second engagement portion;
A third compression unit including a third engagement portion driven by engagement with the third engagement portion of the rotation shaft member, and a third compression cylinder portion compressing the boil-off gas inside by power transmitted from the third engagement portion;
A fourth compression unit including a fourth engagement portion driven by engagement with the fourth locking portion of the rotation shaft member, and a fourth compression cylinder portion compressing the boil-off gas inside by power transmitted from the fourth engagement portion;
A first supply passage having one end connected to the first compression cylinder portion and providing a flow path of the boil-off gas supplied to the first compression cylinder portion;
A second supply passage having one end connected to the second compression cylinder portion and providing a flow path of the boil-off gas supplied to the second compression cylinder portion;
A first connection passage providing a flow path through which the boil-off gas compressed by the first compression unit flows to the second compression unit;
A second connection passage providing a flow path through which the boil-off gas compressed by the second compression unit flows to the third compression unit;
A fourth connection passage providing a flow path for the boil-off gas compressed in the first compression unit to flow to the third compression unit
A first discharge passage providing a passage through which the boil-off gas compressed by the fourth compression unit is discharged to the outside;
A fourth discharge passage providing a flow path for discharging the boil-off gas compressed by the first compression unit and the second compression unit to the outside of the boil-off gas compression facility before flowing into the third compression unit:
A third return passage providing a flow path through which the boil-off gas compressed by the fourth compression unit is supplied back to the fourth compression unit; And
Further comprising a control unit,
The control unit,
A fifth flow mode in which boil-off gas flows in parallel to the first compression unit and the second compression unit through the first supply passage and the second supply passage, and the boil-off gas compressed in the first compression unit is the Controlling the flow of the boil-off gas so as to flow in any one of the sixth flow modes flowing to the third compression unit after flowing into the second compression unit,
In the fifth flow mode, the boil-off gas compressed in parallel in the first compression unit and the second compression unit is discharged to the outside through the fourth discharge passage, while the first compression unit and the second compression unit Some of the boil-off gas compressed by the unit is discharged through the fourth connection passage and the second connection passage and flows toward the third compression unit, and the boil-off gas discharged from the third compression unit is the third return passage. Controls the flow of the boil-off gas in the first discharge passage and the third return passage to return to the fourth compression unit through,
In the fifth flow mode, an inflow amount of the boil-off gas introduced into the third compression unit through the second connection passage and the fourth connection passage is less than the discharge amount of the boil-off gas discharged through the fourth discharge passage,
Boil-off gas compression facility. delete The method of claim 13,
The control unit,
In the sixth flow mode, one of the first discharge passage and the fourth discharge passage so that the boil-off gas compressed by sequentially passing through the first to fourth compression units is discharged to the outside through the first discharge passage. Controlling the flow of boil-off gas in at least one interior,
Boil-off gas compression facility. delete delete

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