KR102334731B1 - Reliquefaction system - Google Patents

Abstract

A reliquefaction system is disclosed. Reliquefaction system according to an embodiment of the present invention comprises: one or more storage tanks for storing liquefied gas and boil-off gas of the liquefied gas; a compressor and a first cooler are alternately disposed on a supply line connected to the storage tank, and a compression unit for receiving a gaseous fluid including boil-off gas and compressing it to a first pressure; a heat exchange unit connected to the front end of the compression unit by a supply line and connected to the rear end of the compression unit by a reliquefaction line to perform heat exchange between the gaseous fluid and the fluid compressed by the compression unit; a first branch line branched from a set point of the compression unit of the supply line and connected to the reliquefaction line, and configured to send the fluid compressed to a second pressure lower than the first pressure through the compressor of the compression unit to the heat exchange unit of the reliquefaction line; a first refrigerant supply line for supplying a portion of the fluid compressed to the first pressure to the first gas-liquid separator by reducing a portion of the fluid by the pressure reducing valve; and a second refrigerant supply line branched from the first branch line and supplying the first gas-liquid separator by reducing some of the fluid compressed to the second pressure by the pressure reducing valve; When is at least one of propane, propylene, and LPG, the fluid compressed to the second pressure is selectively transferred to the first gas-liquid through the first branch line and the second refrigerant supply line according to the temperature value of the sensor provided at the front end of the heat exchange unit of the supply line. supplied to the separator.

Description

reliquefaction system {RELIQUEFACTION SYSTEM}

The present invention relates to a reliquefaction system.

As the International Maritime Organization (IMO)'s regulations on the emission of greenhouse gases and various air pollutants have been strengthened, the shipbuilding and shipping industry has replaced natural gas as a clean energy source instead of using heavy oil and diesel oil, which are the existing fuels. It is increasingly used as fuel gas for ships.

Natural gas, which is widely used among fuel gas, has methane as its main component, and is stored and transported by converting it into liquefied gas, which is usually reduced in volume by 1/600.

This liquefied gas is stored and transported by being accommodated in a storage tank installed in the hull with insulation treatment, and the engine of the ship is driven by receiving liquefied gas or Boiled Off Gas as fuel gas. Here, for propulsion of ships or power generation of ships, low pressure (about 5 to 8 bar) injection engines such as DFDE (Dual Fuel Disel Electric) engines and high pressure (about 150-400 bar) injection engines are widely used. In addition, a medium pressure gas injection engine capable of combustion with fuel gas of medium pressure (about 16 to 18 bar) has been developed and used.

Meanwhile, the ship stores various types of liquefied gas such as ethane, propane, propylene, butane, and LPG (Liquefied Petroleum Gas) containing propane and butane as main components in storage tanks. can be transported Here, ethane (boiling point -89 ℃), propane (boiling point -42.07 ℃), propylene (boiling point -47.6 ℃), butane (boiling point -1 ℃) is different, respectively.

In addition, the vessel is provided with a re-liquefaction facility for re-liquefying boil-off gas of liquefied gas and re-storing it in a storage tank. For example, Korean Patent Application Laid-Open No. 10-2012-0103421 (published on September 19, 2012) proposes a system in which boil-off gas generated in a storage tank is compressed in a compressor and then liquefied in a re-liquefaction apparatus.

At this time, when liquefied gas having a different boiling point from the existing liquefied gas stored in the storage tank is stored in the storage tank, there is a problem in that a re-liquefaction system suitable for the liquefied gas must be installed again.

Korean Patent Publication No. 10-2012-0103421 (published on September 19, 2012)

An embodiment of the present invention is to provide a reliquefaction system in which a reliquefaction process is performed by equipment on each corresponding line provided in one integrated system according to the type of liquefied gas stored in a storage tank of a ship.

According to an aspect of the present invention, one or more storage tanks for storing liquefied gas and boil-off gas of the liquefied gas; a compressor and a first cooler are alternately disposed on a supply line connected to the storage tank, and a compression unit for receiving a gaseous fluid containing the boil-off gas and compressing it to a first pressure; a heat exchange unit connected to the front end of the compression unit by the supply line and connected to the rear end of the compression unit by a reliquefaction line to perform heat exchange between the gaseous fluid and the fluid compressed by the compression unit; Branched from the set point of the compression unit of the supply line and connected to the re-liquefaction line, the fluid compressed to a second pressure lower than the first pressure through the compressor of the compression unit is sent to the heat exchange unit of the re-liquefaction line. 1st branch line; a first refrigerant supply line for supplying a portion of the fluid compressed to the first pressure by a pressure reducing valve to the first gas-liquid separator; and a second refrigerant supply line branching from the first branch line and supplying a portion of the fluid compressed to the second pressure to the first gas-liquid separator by reducing a portion of the fluid compressed by the second pressure by a pressure reducing valve. When the type of liquefied gas is one or more of propane, propylene, and LPG, the fluid compressed to the second pressure is selectively transferred to the first branch line and the second A reliquefaction system for supplying the first gas-liquid separator to the first gas-liquid separator through the second refrigerant supply line may be provided.

A second cooler is disposed in the first branch line, the fluid compressed by the second pressure is sent to the heat exchange unit of the reliquefaction line through the second cooler, and the second refrigerant supply line is connected to the second cooler Branched from the rear end, when the type of liquefied gas stored in the storage tank is ethane, some of the fluid compressed to the first pressure according to the temperature value of the sensor provided at the front end of the heat exchange unit of the supply line is selectively It may be supplied to the first gas-liquid separator through the first refrigerant supply line.

Further comprising a connection line bypassing the first cooler, connecting only a set number of compressors among the compression units in parallel with each other, and allowing the fluid to be compressed by the compressor to a third pressure lower than the second pressure, the storage When the type of the liquefied gas stored in the tank is butane, the gaseous fluid including the boil-off gas of the liquefied gas is selectively supplied to the third pressure through the connection line among the supply line, the connection line, and the first branch line. may be supplied to the heat exchange unit of the reliquefaction line through the first branch line in a compressed state.

a first gas-liquid separator disposed between the storage tank of the supply line and the heat exchange unit and separating the fluid containing boil-off gas supplied from the storage tank into a gas phase and a liquid phase; A pressure reducing valve for reducing pressure, a second gas-liquid separator for separating the pressure-reduced fluid into a gas phase and a liquid phase, and a flash gas line for supplying the separated gas phase component to the first gas-liquid separator, wherein the first gas-liquid separator The gaseous fluid separated by the may be supplied to the compression unit through the heat exchange unit.

The reliquefaction system according to an embodiment of the present invention may allow the reliquefaction process to be performed by equipment on each corresponding line provided in one integrated system according to the type of liquefied gas stored in the storage tank of the ship.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 shows a reliquefaction system according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following examples are presented to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains. The present invention is not limited to the embodiments presented herein, and may be embodied in other forms. The drawings may omit the illustration of parts not related to the description in order to clarify the present invention, and slightly exaggerate the size of the components to help understanding.

Referring to FIG. 1 , the reliquefaction system 100 according to an embodiment of the present invention may be installed in a ship transporting liquefied gas. For example, the ship may include various liquefied fuel carriers, liquefied fuel regasification vessels (RVs), container ships, general merchant ships, floating, production, storage and off-loading (FPSOs), floating storage and regasification units (FSRUs), and the like.

Specifically, the re-liquefaction system 100 is connected to the storage tank 10 for storing liquefied gas and boil-off gas of the liquefied gas, and is connected to the storage tank 10, and the fluid containing the boil-off gas supplied from the storage tank 10 . A first gas-liquid separator 20 for separating the gas phase and liquid phase, compressors 31a to 31d and first coolers 32a to 32d are alternately arranged, and the gas phase separated by the first gas-liquid separator 20 is The compression unit 30 for compressing the fluid to the first pressure, and the fluid compressed to a predetermined pressure by one or more compressors of the compression unit 30 is liquefied by heat exchange with the gaseous fluid supplied from the first gas-liquid separator 20 . It includes a heat exchange unit (40).

In addition, the reliquefaction system 100 includes a storage tank 10 , a first gas-liquid separator 20 , a heat exchange unit 40 , a supply line L1 connecting the compression unit 30 , and a compression unit 30 . Branched from the set point of the reliquefaction line (L11) for sending the fluid compressed to the first pressure to the heat exchange unit (40) by the, and the compression unit (30) of the supply line (L1), the above-described compression unit (30) Compresses the fluid to a second pressure lower than the first pressure through a set number of compressors and first coolers among the compressors 31a to 31d and the first coolers 32a to 32d, The first branch line L2, which joins to the front end of the heat exchange unit 40 of the reliquefaction line L11 through the The fluid compressed to a third pressure lower than the second pressure by the connecting line L3a that connects and the compressor branched from the set point of the compression unit 30 of the supply line L1 and connected by the connecting line L3a. It includes a second branch line (L3) joined to the front end of the second cooler (33) of the first branch line (L2).

Specifically, for example, when the type of liquefied gas stored in the storage tank 10 is ethane, the boil-off gas of ethane passes through all of the compressors 31a to 31d and the first coolers 32a to 32d of the compression unit 30 to be removed. compressed to 1 pressure.

In addition, for example, when the type of liquefied gas stored in the storage tank 10 is any one of propane, propylene and LPG, the boil-off gas of the liquefied gas is a set number of compressors and After being compressed to a second pressure lower than the first pressure through the first cooler, it flows through the first branch line L2.

And, for example, when the type of liquefied gas stored in the storage tank 10 is butane, the boil-off gas of butane passes through only a set number of compressors among the compression units 30 of the supply line L1 to a third pressure lower than the second pressure. After being compressed into the , it flows through at least one of the first branch line L2 and the second branch line L3. The second branch line L3 is connected to the front end of the second cooler 33 of the first branch line L2.

The above-described reliquefaction system 100 includes a first pressure reducing valve V1 that depressurizes the fluid that has passed through the heat exchange unit 40 of the reliquefaction line L11, and vaporizes the fluid decompressed by the first pressure reducing valve V1. A second gas-liquid separator 50 for separating the liquid and the liquid phase, a first recovery line L4 for storing the liquid component separated by the second gas-liquid separator 50 in the storage tank 10, and a second gas-liquid separator ( 50) may include a flash gas line (L5) for supplying the gaseous component separated by the first gas-liquid separator (20). The reliquefaction line L11 connects the compression unit 30, the heat exchange unit 40, the first pressure reducing valve V1, and the second gas-liquid separator 50, and the first pressure reducing valve V1 is, for example, Joule-Thomson. (Joule Thomson) valve may be included.

In addition, the reliquefaction system 100 is branched from the rear end of the compression unit 30 of the supply line L1, and the fluid compressed to the first pressure through the compression unit 30 of the supply line L1 is transferred to the second pressure reducing valve. The first refrigerant supply line L21 for supplying the first gas-liquid separator 20 by reducing the pressure by (V2), and the first branch line L2 branch from the rear end of the second cooler 33, and the second A second refrigerant supply line L22 may be provided for supplying the first gas-liquid separator 20 by depressurizing the fluid compressed to the pressure or the third pressure by the third pressure reducing valve V3.

Hereinafter, each component of the reliquefaction system 100 will be described in detail.

One or more storage tanks 10 may be provided, for example, any one of ethane, propane, propylene, butane, and LPG (Liquefied Petroleum Gas) containing propane and butane as main components. of liquefied gas can be stored. All of the storage tanks 10 may store the same type of liquefied gas, or some of the storage tanks 10 may store different types of liquefied gas. 1 shows one storage tank 10 for convenience of description.

The first gas-liquid separator 20 separates the fluid containing the boil-off gas supplied from the storage tank 10 into a gaseous phase and a liquid phase. For example, the first gas-liquid separator 20 may separate the high-carbon component in the form of droplets included in the boil-off gas supplied from the storage tank 10 from flowing toward the heat exchange unit 40 .

The gas-phase fluid separated from the second gas-liquid separator 50 may be introduced into the first gas-liquid separator 20 through the flash gas line L5 and mixed therein. The liquid fluid separated by the first gas-liquid separator 20 joins the first recovery line L4 through the second recovery line L6 and is stored in the storage tank 10 . The gaseous fluid separated by the first gas-liquid separator 20 is supplied to the compression unit 30 through the heat exchange unit 40 through the supply line L1 .

The heat exchange unit 40 heats the fluid compressed to the above-described first pressure, second pressure or third pressure with the gas-phase fluid supplied from the first gas-liquid separator 20 to liquefy it. The corresponding fluid liquefied by the heat exchange unit 40 flows into the second gas-liquid separator 50 through the first pressure reducing valve V1.

On the other hand, if the reliquefaction process is described according to the type of liquefied gas stored in the above-described storage tank 10 , when the type of liquefied gas stored in the storage tank 10 is ethane, it is separated through the first gas-liquid separator 20 . The gaseous fluid containing the boil-off gas of ethane is compressed to a first pressure through the compressors 31a to 31d and the first coolers 32a to 32d of the compression unit 30 of the supply line L1 and then reliquefied. It is supplied to the heat exchange unit 40 through the line L11. At this time, some of the fluid compressed by the compression unit 30 may be supplied to the consumer E and used.

Here, the pressure of the fluid flowing into the heat exchange unit 40 of the reliquefaction line L11 through the compression unit 30 of the supply line L1 may be 140 to 160 barA.

And, in order to lower the gas-phase fluid temperature in the first gas-liquid separator 20, the fluid compressed to the first pressure through the compression unit 30 of the supply line L1 is transferred through the first refrigerant supply line L21. It may be supplied to the first gas-liquid separator 20 through the second pressure reducing valve V2.

At this time, a sensor T for measuring a temperature may be provided at the front end of the heat exchange unit 40 of the supply line L1, and the first refrigerant is controlled by the controller 60 according to the temperature value measured by the sensor T. The degree of opening and closing of the second pressure reducing valve V2 of the supply line L21 may be controlled. Through this, the reliquefaction efficiency of the heat exchange unit 40 may be increased.

The control unit 60 includes a supply line (L1), a first branch line (L2), a second branch line (L3), a first refrigerant supply line (L21), By controlling the opening/closing valve on each line, such as the second refrigerant supply line (L22), it is possible to control the flow of the fluid.

In addition, as described above, the control unit 60 controls the second pressure reduction of the first refrigerant supply line L21 according to the temperature value measured by the sensor T provided at the front end of the heat exchange unit 40 of the supply line L1. The degree of opening/closing of the valve V2 may be controlled, or the degree of opening/closing of the third pressure reducing valve V3 of the second refrigerant supply line L22, which will be described later, may be controlled. As a result, the reliquefaction efficiency of the heat exchange unit 40 may be increased.

Specifically, when the temperature value measured by the sensor T is higher than the set value, the control unit 60 increases the degree of opening and closing of the second pressure reducing valve V2 of the first refrigerant supply line L21 to increase the first The temperature of the gas-phase fluid in the first gas-liquid separator 20 may be lowered by the fluid supplied to the first gas-liquid separator 20 through the second pressure reducing valve V2 through the refrigerant supply line L21 .

As another example, when the type of liquefied gas stored in the storage tank 10 is propane, propylene, or LPG, the gaseous fluid including boil-off gas of the liquefied gas that has passed through the first gas-liquid separator 20 is supplied to the supply line L1 ) through a set number of compressors 31a to 31c and the first coolers 32a and 32b, after being compressed to a second pressure lower than the first pressure described above, the second cooler 33 of the first branch line L2 ) through the reliquefaction line (L11) and is supplied to the heat exchange unit (40).

Since the set number of the first coolers 32a and 32b of the supply line L1 do not sufficiently provide the heat quantity change according to the phase change, the second cooler 33 is separately disposed in the first branch line L2, The fluid compressed by the second pressure can be sufficiently cooled.

Here, the pressure of the fluid flowing into the second cooler 33 may be 15 to 50 barA. The fluid that has passed through the second cooler 33 may have a partial liquid phase, and is supplied to the heat exchange unit 40 after being merged into the reliquefaction line L11, and through the heat exchange unit 40, the first pressure reducing valve V1 ) and then introduced into the second gas-liquid separator 50 after the pressure is reduced to a level of about 3 to 5 barA.

And, in order to lower the gas-phase fluid temperature in the first gas-liquid separator 20, the second cooler 33 according to the temperature value measured by the sensor T provided at the front end of the heat exchange unit 40 of the supply line L1. The fluid passing through may be supplied to the first gas-liquid separator 20 through the third pressure reducing valve V3 through the second refrigerant supply line L22. The control unit 60 controls the degree of opening and closing of the third pressure reducing valve V3 of the second refrigerant supply line L22 according to the temperature value measured by the sensor T provided at the front end of the heat exchange unit 40 of the supply line L1. can control

Specifically, when the temperature value measured by the sensor T is higher than the set value, the control unit 60 increases the degree of opening and closing of the third pressure reducing valve V3 of the second refrigerant supply line L22 to increase the second The gas-liquid temperature in the first gas-liquid separator 20 may be lowered by the fluid supplied to the first gas-liquid separator 20 through the third pressure reducing valve V3 through the refrigerant supply line L22 .

As another example, when the type of liquefied gas stored in the storage tank 10 is butane, the fluid containing the boil-off gas of butane that has passed through the first gas-liquid separator 20 is the first stage compressor 31a of the connection line L3a. After being compressed through the second branch line (L3) may be joined to the front end of the second cooler (33) of the first branch line (L2) (L2). Thereafter, the fluid is supplied to the heat exchange unit 40 through the second cooler 33 .

Here, as shown in FIG. 1, when the second and third stage compressors 31b and 31c of the rear stage of the first stage compressor 31a are connected in parallel with each other by a connection line L3a, a larger flow rate can be effectively compressed. can In this case, the fluid passing through the compressors 31a to 31c on the corresponding connection line L3a may be joined at the front end of the second cooler 33 through the first branch line L2 and the second branch line L3. The pressure of this fluid introduced into the second cooler 33 may be 2.5 to 3.5 barA.

Specifically, in the case of butane, if it passes through the first stage compressor 31a and the first cooler 32a according to its characteristics, it has a liquid phase, and when the liquid having a liquid phase flows into the second stage compressor 31b Problems can arise. Therefore, in the embodiment of the present invention, the first coolers 32a to 32d are bypassed, so that only a set number of compressors is introduced to the fluid.

Butane needs to have a pressure of less than 10 barA for reliquefaction, and since two-stage compression is sufficient, the first-stage compressor (31a), the second-stage compressor (31b) and the third-stage compressor (31c) of the rear stage are connected in parallel to each other. More flow can be compressed.

In the case of the above-described parallel connection, the fluid flows through the first branch line (L2) and the second branch line (L3) at the rear end of the second-stage compressor (31b) and the third-stage compressor (31c), and the second cooler (33) After the temperature drops through the , it is supplied to the heat exchange unit 40 .

In addition, in the case of the re-liquefaction of butane, the amount of flash gas may be small or absent because the temperature in the second gas-liquid separator 50 is sufficiently low. Therefore, in the case of pure butane reliquefaction, the frequency of use of the flash gas line L5 may be reduced. However, if there is a small amount of propane or ethane having a lower boiling point than butane in the above-described storage tank 10, they are evaporated into flash gas and supplied to the first gas-liquid separator 20 through the flash gas line L5. have.

And, as described above, in order to increase the reliquefaction efficiency according to the temperature measurement value of the sensor T, the second refrigerant supply line L22 passes through the third pressure reducing valve V3 to the first gas-liquid separator 20. The fluid that has passed through the second cooler 33 may be supplied.

In this way, through one integrated reliquefaction system 100, compression and cooling are performed by equipment on a line corresponding to each type according to the type of liquefied gas stored in the storage tank 10 of the ship, so that the reliquefaction process is effectively performed can be

In the above, specific embodiments have been shown and described. However, the present invention is not limited to the above embodiments, and those of ordinary skill in the art to which the invention pertains can make various changes without departing from the spirit of the invention described in the claims below. will be able

10: storage tank 20, 50: gas-liquid separator
30: compression unit 40: heat exchange unit
60: control unit
L1: Supply line L2: First branch line
L3: 2nd branch line L4, L6: recovery line
L5: Flash gas line L11: Reliquefaction line
L21: first refrigerant supply line L22: second refrigerant supply line

Claims (4)

one or more storage tanks for storing liquefied gas and boil-off gas of the liquefied gas;
a compressor and a first cooler are alternately disposed on a supply line connected to the storage tank, and a compression unit for receiving a gaseous fluid containing the boil-off gas and compressing it to a first pressure;
a heat exchange unit connected to the front end of the compression unit by the supply line and connected to the rear end of the compression unit by a reliquefaction line to perform heat exchange between the gaseous fluid and the fluid compressed by the compression unit;
Branched from the set point of the compression unit of the supply line and connected to the re-liquefaction line, the fluid compressed to a second pressure lower than the first pressure through the compressor of the compression unit is sent to the heat exchange unit of the re-liquefaction line. 1st branch line;
a first gas-liquid separator disposed between the storage tank of the supply line and the heat exchange unit, the first gas-liquid separator separating the fluid containing the boil-off gas supplied from the storage tank into a gaseous phase and a liquid phase;
a first refrigerant supply line for supplying a portion of the fluid compressed to the first pressure to the first gas-liquid separator by reducing a portion of the fluid by a second pressure reducing valve; and
A second refrigerant supply line branching from the first branch line and supplying a portion of the fluid compressed to the second pressure to the first gas-liquid separator by reducing a portion of the fluid compressed by the second pressure by a third pressure reducing valve;
When the type of the liquefied gas stored in the storage tank is at least one of propane, propylene, and LPG, the fluid compressed to the second pressure is selectively used in the first A reliquefaction system for supplying to the first gas-liquid separator through a branch line and the second refrigerant supply line. According to claim 1,
A second cooler is disposed in the first branch line, and the fluid compressed to the second pressure is sent to the heat exchange unit of the reliquefaction line through the second cooler,
The second refrigerant supply line is branched from the rear end of the second cooler,
When the type of liquefied gas stored in the storage tank is ethane, some of the fluid compressed to the first pressure according to a temperature value of a sensor provided at the front end of the heat exchange unit of the supply line is selectively connected to the first refrigerant supply line A reliquefaction system supplied to the first gas-liquid separator through According to claim 1,
Further comprising a connection line bypassing the first cooler, connecting only a set number of compressors among the compression units in parallel with each other, and allowing the fluid to be compressed by the compressor to a third pressure lower than the second pressure,
When the type of the liquefied gas stored in the storage tank is butane, the gaseous fluid including the boil-off gas of the liquefied gas is selectively passed through the connection line among the supply line, the connection line and the first branch line. The reliquefaction system is supplied to the heat exchange unit of the reliquefaction line through the first branch line in a compressed state to 3 pressure. According to claim 1,
a first pressure reducing valve for reducing the pressure of the fluid passing through the heat exchange unit of the reliquefaction line;
a second gas-liquid separator for separating the depressurized fluid into a gas phase and a liquid phase;
Further comprising a flash gas line for supplying the separated gaseous component to the first gas-liquid separator,
The gas-phase fluid separated by the first gas-liquid separator is supplied to the compression unit through the heat exchange unit.

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