KR101368795B1 - Liquefied cargo regasification system and method - Google Patents

Abstract

Liquefaction regasification systems and methods are disclosed. Liquefaction regasification system according to an embodiment of the present invention, a liquefaction storage tank for storing liquefied; A regasification apparatus supplied with liquefaction to regasification; And a recondenser combined suction drum supplied with liquefied and evaporated gas from the liquefied storage tank to recondense the evaporated gas and temporarily store the liquefied liquid, and supplying the liquefied liquid to the regasification apparatus by internal pressure.

Description

LIQUIFIED CARGO REGASIFICATION SYSTEM AND METHOD}

The present invention relates to a liquefaction regasification system and method, and more particularly, to a liquefaction regasification system and method for receiving liquefaction and evaporation gas to recondensate the evaporation gas and then re-liquefying and supplying the liquefaction gas. It is about.

In general, liquefied (Liquefied Cargo) refers to a weight that is reduced by liquefying the weight of the gaseous state. For example, a typical liquefied liquid is liquefied natural gas, a colorless, transparent cryogenic liquid whose natural gas (NG) containing methane as its main component is cooled to -163 ° C and reduced in volume to 1/600. . Such liquefaction may be carried in the vaporized state as needed. The case where such liquefaction is transported in a vaporized state will be described below using liquefied natural gas (LNG) as an example.

Liquefied natural gas (LNG) is transported by LNG carriers in the mountains to be stored in onshore LNG terminals and supplied to consumers, or floating offshore liquefied natural gas terminals equipped with natural gas supply functions by modifying LNG carriers, or liquefied natural gas storage From the fixed offshore liquefied natural gas terminal with the tank part seated on the sea floor, it is sent directly to the consumer. LNG is vaporized in the liquid state by the regeneration facility and supplied to the customer.

1 is a schematic configuration diagram of a conventional liquefied natural gas regasification system.

1, the liquefied natural gas is supplied from the LNG cargo hold 20 to the suction drum 10, and the liquefied natural gas is supplied from the suction drum 10 to the high pressure booster pump 30 And the natural gas vaporized by the vaporizer 40 is sent to the land. At this time, the suction drum 10 performs a function of keeping the suction pressure (net suction lift) of the high-pressure booster pump 30 constant.

The suction drum 10 generally maintains a pressure of 2 to 8 bar and an inert gas such as nitrogen or some NG vapor in the discharge pipe of the carburetor 40 is supplied to the suction drum 10 for maintaining the pressure, And the pressure is applied to the inside of the suction drum 10 to control the internal level of the suction drum 10. A separate valve is provided at the inlet of the suction drum 10 to control the suction level.

Korean Patent No. 10-0678851 (2007.01.29)

The technical problem to be achieved by the present invention is to provide a liquefaction regasification system for recondensing the evaporated gas generated in the liquefaction storage tank and at the same time supplying the liquefaction to the vaporization device.

In addition, it is to provide a liquefaction regasification method for re-condensing the evaporated gas generated in the liquefaction storage tank and at the same time supplying the liquefaction to the vaporization device.

According to one aspect of the invention, a liquefaction storage tank for storing a liquefied; A regasification apparatus supplied with liquefaction to regasification; And a recondenser combined suction drum receiving liquid liquefied gas and a boil-off gas (BOG) from the liquefied storage tank, recondensing the evaporated gas, temporarily storing the liquefied liquid, and supplying the liquefied liquid to the regasification apparatus. A regasification system may be provided.

The recondenser combined suction drum may include: a suction drum configured to temporarily receive a liquefied liquid and an evaporated gas from the liquefied storage tank, and supply the liquefied liquid to the regasification apparatus; And a recondensation unit provided at an inner upper portion of the suction drum, and the supplied liquefaction is in contact with the evaporating gas to recondensate the evaporating gas.

The recondensation unit may include a recondensation unit provided at an inner upper portion of the suction drum; And a liquefaction distributor provided at an upper portion of the recondensation unit to receive liquefaction from the liquefaction storage tank and to distribute the liquefaction unit to the recondensation unit.

The apparatus may further include a supply flow rate control unit configured to receive an amount of the evaporated gas supplied to the recondenser combined suction drum and adjust a supply amount of the liquefied liquid supplied to the recondensing unit of the recondenser combined suction drum based on the amount of the evaporated gas.

The supply flow rate control unit may be provided in a first liquefaction input pipe connecting the liquefied storage tank and the recondenser combined suction drum to adjust a flow rate of the liquefied liquid flowing into the recondensed unit of the recondenser combined suction drum. Flow control valves; A flow rate meter provided in a first gas input pipe connecting the liquefied storage tank and the suction drum for re-condenser to measure the flow rate of the evaporated gas flowing into the suction tank for the re-condenser; And it may include a flow rate control unit for controlling the opening and closing of the flow control valve on the basis of receiving the flow rate of the evaporated gas measured from the flow rate meter.

The apparatus may further include a pressure control unit for measuring an outlet pressure of the combined recondenser suction drum and controlling an outlet pressure of the combined recondenser suction drum based on the measured pressure.

The pressure control unit may include: a pressure control valve provided at a second liquefaction input pipe connecting the liquefied storage tank and the recondenser combined suction drum to adjust the amount of liquefied liquid introduced into the recondenser combined suction drum; A pressure measuring device provided in an output pipe connecting the recondenser combined suction drum and the regasification device to measure the pressure in the output pipe; And a pressure controller configured to receive the pressure measured by the pressure gauge and to control the opening and closing of the pressure control valve based on the received pressure.

The level control unit may further include a level control unit configured to measure the liquid level inside the recondenser combined suction drum and to control the level of the liquid inside the recondenser combined suction drum based on the measured liquid level.

The level control unit may include: a liquid level meter for measuring a liquid level inside the suction drum for the recondenser; A level control valve provided at a second gas input pipe connected to an upper portion of the recondenser combined suction drum from an outlet of the regasifying apparatus to adjust an amount of natural gas introduced into the recondenser combined suction drum; And a level controller for receiving the measured liquid level from the liquid level measuring device and controlling the opening and closing of the level control valve based on the received liquid level.

The gas supply compressor may further include a gas supply compressor provided on the first gas input tube for supplying the evaporation gas from the liquefied storage tank to the recondenser combined suction drum to compress and supply the evaporated gas to the recondenser combined suction drum.

In order to adjust the amount of evaporated gas supplied to the recondenser combined suction drum by the gas supply compressor based on the input of the pressure and the temperature of the outlet side of the suction drum combined with the gas supply compressor, It may further include a compressor flow rate controller for controlling the gas supply compressor.

According to another aspect of the invention, the step of supplying liquefied and evaporated gas from the liquefied storage tank to the re-condenser combined suction drum; Recondensing boil-off gas in the recondenser combined suction drum; Supplying liquefaction from the recondenser combined suction drum to a regasification apparatus; And regasifying the liquefied liquid in the regasification apparatus and supplying the liquefied liquid to a demand destination.

Recondensing the boil-off gas, the step of receiving the amount of the boil-off gas supplied to the re-condenser combined suction drum based on the calculated amount of the liquefaction supplied to the recondensation unit of the re-condenser combined suction drum; And supplying the liquefaction amount of the calculated supply amount to the recondensation unit of the recondenser combined suction drum.

Embodiments of the present invention can provide a liquefaction regasification system for recondensing the evaporated gas generated in the liquefaction storage tank and at the same time supplying the liquefaction to the vaporization device.

In addition, it is possible to provide a liquefaction regasification method for re-condensing the evaporated gas generated in the liquefaction storage tank and at the same time supplying the liquefaction to the vaporization device.

1 is a schematic configuration diagram of a conventional liquefaction regasification system.
2 is a schematic diagram of a liquefaction regasification system according to an embodiment of the present invention.
Figure 3 is a schematic diagram showing the inside of the re-condenser combined suction drum of FIG.
4 is an operational flowchart illustrating the operation of the liquefaction regasification system of FIG.
5 is a flowchart of a liquefaction regasification method according to an embodiment of the present invention.
6 is a flowchart in which a pressure control step is added to the liquefaction regasification method of FIG. 5.
FIG. 7 is a flowchart in which a level control step is added to the liquefaction regasification method of FIG. 5.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

2 is a schematic configuration diagram of a liquefaction regasification system according to an embodiment of the present invention, Figure 3 is a schematic diagram showing the inside of the re-condenser combined suction drum of Figure 2, Figure 4 is a liquefaction regasification of Figure 2 An operational flowchart describing the operation of the system. Hereinafter, for the convenience of description, the case where the liquefaction is liquefied natural gas, but the liquefaction is not limited thereto.

As shown in these figures, the liquefaction regasification system 1 according to an embodiment of the present invention, the liquefied storage tank 100 for storing the liquefied natural gas (LNG) and the liquefied natural gas supplied Regasification apparatus 200 for regasification and liquefied natural gas and evaporated gas (BOG) supplied from the liquefied storage tank 100 to condense the evaporated gas, temporarily storing the liquefied natural gas and regasified liquefied natural gas It includes a recondenser combined suction drum 300 to supply to (200).

First, the regasification apparatus 200 receives the liquefied natural gas from the recondenser combined suction drum 300 at a constant pressure to regasify the liquefied natural gas, and supplies the regasified natural gas to the demand destination.

The regasification apparatus 200 receives the liquefied natural gas from the suction drum 300 combined with the recondenser and vaporizes the liquefied natural gas boosted by the high pressure pump 210 and the high pressure pump 210 to boost the pressure to high pressure. And a vaporizer 220.

Next, the recondenser combined suction drum 300 of the present invention simultaneously performs the role of the recondenser and the suction drum.

Referring to Figures 2 and 3, the re-condenser combined suction drum 300 is supplied with the liquefied natural gas and evaporated gas from the liquefied storage tank 100 temporarily stored and re-liquefied liquefied natural gas 200 Suction drum 310 to be supplied to, and the liquefied natural gas is provided on the inner upper portion of the suction drum 310 and the recondensation unit 320 for contacting the evaporation gas to recondensate the evaporation gas.

The suction drum 310 is supplied with boil off gas (BOG) generated from the liquefied storage tank 100 through the first gas input pipe 61 and through the second liquefied input pipe 52. The liquefied natural gas is supplied from the liquefied storage tank 100 to be temporarily stored, and the temporarily stored liquefied natural gas is supplied to the regasification apparatus 200 through the output pipe 53.

The recondensation unit 320 is provided in the upper portion of the suction drum 310 to contact the liquefied natural gas (LNG) with the boil-off gas (BOG) present in the upper portion of the suction drum 310, the liquefied natural gas has Cool heat to condense the evaporated gas.

Referring to FIG. 3, the recondensation unit 320 is liquefied from the liquefaction storage tank 100 provided at the upper portion of the recondensation unit 321 and the upper portion of the recondensation unit 321 provided inside the suction drum 310. It includes a liquefied distributor 322 for distributing natural gas supplied to the recondensation unit 321.

In the present embodiment, the recondensation unit 321 is provided in a lattice structure, but the scope of the present invention is not limited thereto, and may be any structure that can increase the contact area of the liquid and the gas.

As such, the recondensing unit 321 is provided as a structure for widening the area in which the liquefied natural gas is in contact with the evaporating gas, whereby liquefied natural gas is distributed to the recondensing unit 321 by the liquefied distributor 322. As the gas bubble descends through the recondensation unit 321, heat is transferred by contacting the evaporated gas.

The amount of liquefied natural gas supplied to the liquefaction distributor 322 is sufficient to liquefy the entire amount of the evaporated gas supplied based on the amount of the evaporated gas supplied from the liquefied storage tank 100 to the upper portion of the suction drum 310. To supply liquefied natural gas. The ratio of liquefied natural gas that can liquefy the total amount of evaporated gas varies depending on temperature or pressure, but the ratio of evaporated gas to liquefied natural gas is generally about 1 to 9 to 20.

In this ratio, the supply flow rate control unit 500 controls the supply amount of the liquefied natural gas supplied to the liquefaction distributor 322.

Liquefaction regasification system 1 according to an embodiment of the present invention, receives the amount of evaporated gas supplied to the re-condenser combined suction drum 300 based on the recondensation of the re-condenser combined suction drum 300 based on this It further includes a supply flow rate control unit 500 for adjusting the supply amount of the liquefied natural gas supplied to the unit 320.

The supply flow rate control unit 500 is provided in the first liquefaction input pipe 51 connecting the liquefied storage tank 100 and the suction drum 300 for a recondenser to recondensate the suction drum 300 for a combined condenser. The first gas input pipe 61 connecting the flow control valve 510 for adjusting the flow rate of the liquefied natural gas flowing into the unit 320 and the liquid storage tank 100 and the suction drum 300 for a recondenser. Flow rate control valve (520) for measuring the flow rate of the evaporated gas flows into the suction drum 300 combined with the recondenser, and the flow rate of the evaporated gas measured from the flow rate meter (520) based on the flow control valve ( It includes a flow control unit 530 for controlling the opening and closing of the 510.

The liquefied natural gas is supplied to the liquefied distributor 322 of the recondensing unit 320 through the first liquefied input tube 51, and the amount of the liquefied natural gas supplied is on the first liquefied input tube 51. It is controlled by the flow control valve 510 is provided.

The first gas input tube 61 is provided with a flow rate measuring instrument 520 for measuring the flow rate of the evaporated gas flowing into the suction drum 310 to transmit the measured flow rate to the flow rate control unit 530, the flow rate control unit 530 Based on this, the flow control valve to supply liquefied natural gas corresponding to about 9 to 20 times the evaporated gas to the liquefied distributor 322 so that the entire amount of the evaporated gas flowing into the suction drum 310 can be liquefied. Open and close the 510.

On the other hand, the liquefaction regasification system 1 of the present embodiment, for measuring the outlet pressure of the re-condenser combined suction drum 300 and for controlling the outlet pressure of the re-condenser combined suction drum 300 based on the measured pressure Further, the pressure control unit 600 and the level control unit 700 for measuring the liquid level inside the recondenser combined suction drum 300 and controlling the liquid level in the recondenser combined suction drum 300 based on the measured liquid level are further included. Include.

First, the pressure control unit 600 is provided in the second liquefaction input pipe 52 connecting the liquefied storage tank 100 and the recondenser combined suction drum 300 to flow into the recondenser combined suction drum 300. A pressure control valve 610 for adjusting the amount of liquefied natural gas to be provided, and an output pipe 53 for connecting the recondenser combined suction drum 300 and the regasification apparatus 200 to measure the pressure in the output pipe 53. And a pressure controller 630 which receives the pressure measured from the pressure gauge 620 and controls the opening and closing of the pressure control valve 610 based on the pressure measurer 620.

A pressure control valve 610 is provided on the second liquefaction input pipe 52 for supplying the liquefied natural gas from the liquefaction storage tank 100 to the suction drum 300 for the recondenser. The amount of liquefied natural gas supplied to the recondenser combined suction drum 300 is controlled.

The output pipe 53 for supplying liquefied natural gas to the regasification apparatus 200 from the lower portion of the recombination suction drum 300 is provided with a pressure measuring device 620 for measuring the pressure from the outlet side of the recondenser combined suction drum 300. Pressure is measured, and the measured pressure is input to the pressure controller 630.

2 and 4, the pressure control unit 630 opens the pressure control valve 610 when the measured pressure at the outlet side of the recondenser combined suction drum 300 is low, and when the measured pressure is high, The pressure control valve 610 is controlled to close. Since the outlet pressure of the recondenser combined suction drum 300 is determined by the pressure and the liquid level inside the recondenser combined suction drum 300, the outlet of the recondenser combined suction drum 300 is controlled by the pressure control unit 600. That is, the inlet pressure of the regasification apparatus 200 is always kept constant.

Next, the level control unit 700 includes a liquid level measuring instrument 710 for measuring the liquid level inside the recondenser combined suction drum 300 and a recondenser combined suction drum 300 from the outlet of the regasification apparatus 200. The liquid level measured from the level control valve 720 and the liquid level gauge 710 is provided in the second gas input pipe 62 connected to the upper part to adjust the amount of natural gas flowing into the recondenser combined suction drum 300. It receives the input includes a level control unit 730 for controlling the opening and closing of the level control valve 720 on the basis.

In the recondenser combined suction drum 300, a liquid level measuring device 710 is provided to measure the liquid level of the liquefied natural gas in the suction drum 310 to measure the liquid level of the liquefied natural gas.

In order to control the liquid level measured by the liquid level gauge 710, a second gas input tube 62 is provided to be connected to the upper portion of the recondenser combined suction drum 300 from the regasification apparatus 200. Through the second gas input tube 62, the high pressure natural gas vaporized through the regasification apparatus 200 is supplied to the upper portion of the suction drum 300 for a condenser. The second gas input pipe 62 is provided with a level control valve 720 for adjusting the amount of natural gas supplied from the regasification apparatus 200.

Referring to FIGS. 2 and 4, the level control unit 730 controls the level control valve 720 to be opened when the liquid level reaches a specific value, based on the liquid level measured from the liquid level measuring unit 710. Accordingly, when the liquid level reaches a certain height, the regasified high pressure natural gas is supplied to the upper end of the recondenser combined suction drum 300 to increase the internal pressure of the recondenser combined suction drum 300. The outlet pressure of the recondenser combined suction drum 300 is also increased, so that the pressure control valve 610 is locked by the pressure controller 630, and the internal liquid level of the recondenser combined suction drum 300 is naturally reduced.

On the other hand, in order to supply the boil-off gas from the liquefied storage tank 100 to the re-condenser combined suction drum 300, since the pressure inside the re-condenser combined suction drum 300 is high, the gas to compress and supply the evaporated gas to a high pressure Supply compressor 800 is required. The gas supply compressor 800 may be provided separately from the existing compressor used for supplying fuel or protecting the liquefied storage tank 100.

Accordingly, the liquefaction regasification system 1 of the present embodiment is provided on the first gas input pipe 61 for compressing and supplying the evaporated gas to a high pressure from the liquefaction storage tank 100 to the recondenser combined suction drum 300. It is provided in the gas supply compressor 800 and the gas supply compressor 800 for supplying the evaporation gas to the recondenser combined suction drum 300, and receives the pressure and temperature of the outlet side of the recondenser combined suction drum 300 The compressor further includes a compressor flow controller 900 for controlling the gas supply compressor 800 to adjust the amount of evaporated gas supplied to the recondenser combined suction drum 300 by the gas supply compressor 800. do.

The compressor flow rate controller 900 controls the flow rate of the evaporated gas supplied to the recondenser combined suction drum 300 through the gas supply compressor 800 to adjust the amount of evaporated gas in the recondenser combined suction drum 300.

More specifically, when the evaporation gas is large and the regeneration flow rate is low, the pressure control valve 610 is almost locked, and only the re-condensation of the evaporated gas by the supply flow rate control unit 500 and the recondensing unit 320 . In this case, the temperature inside the recondenser combined suction drum 300 is increased by a large amount of evaporating gas, and the high temperature liquefied natural gas may not be supplied to the regasification apparatus 200 as a total amount of liquid, thereby regasifying. Damage to the high pressure pump 210 of the device 200. Therefore, the compressor flow rate controller 900 measures the outlet pressure and temperature of the recondenser combined suction drum 300 and controls the gas supply compressor 800 when the liquefied natural gas reaches the saturation state. 300) to reduce the amount of evaporated gas supplied. If the regeneration flow is reduced, the recondensation flow rate must also be reduced, which is an essential control method.

Meanwhile, in the present embodiment, the evaporated gas compressed to a high pressure by the gas supply compressor 800 is connected to supply the engine 70 using natural gas as a fuel, in addition to the suction condenser drum 300. As a result, as described above, when there is a large amount of boil-off gas, the compressed boil-off gas supplied by the gas supply compressor 800 may be supplied to the engine 70.

The operation of the liquefaction regasification system 1 having such a configuration will be described below.

First, as shown in Figure 4, while operating the liquefaction regasification system 1, the outlet pressure of the re-condenser combined suction drum 300 is measured, and the pressure control valve by the pressure control unit 630 according to the measured pressure 610 is controlled. As a result, the pressure of the outlet of the recondenser combined suction drum 300, that is, the inlet of the high pressure pump 210 is always kept constant.

On the other hand, when the amount of liquefied natural gas supplied to the regasification apparatus 200 decreases because the regasification flow rate is small, there is a possibility that the liquid level inside the recondenser combined suction drum 300 becomes high and overflows.

In this case, the liquid level in the recondenser combined suction drum 300 is adjusted by the liquid level control unit. That is, the liquid level in the suction drum 310 is measured from the liquid level meter 710, and if the measured liquid level is higher than or equal to a predetermined height, the level controller 730 opens the level control valve 720 to measure the upper portion of the suction drum 310. Supply natural gas of high pressure. Accordingly, the pressure inside the suction drum 310 increases and the outlet pressure of the suction drum 300 for the recondenser combines to increase, so that the pressure control valve 610 is closed by the pressure controller 630 to close the suction drum 310. ) The level inside is reduced.

When there is a large amount of evaporated gas and the flow rate is small in the recondenser combined suction drum 300, the amount of the evaporated gas supplied to the recondenser combined suction drum 300 through the gas supply compressor 800 by the compressor flow controller 900. Reduce the amount.

In addition, when the pressure in the suction drum 310 is maintained at a predetermined level or more and the pressure in the suction drum 310 is combined, the recondensation unit 320 is provided on the suction drum 310. Since the area in which the shaft portion 321 is in contact with the boil-off gas increases, the amount of the boil-off gas condensed by the recondensation unit 320 increases. As a result, the pressure in the recondenser combined suction drum 300 may be lowered, and as a result, the pressure control valve 610 may be opened to prevent the liquid level in the recondenser combined suction drum 300 from being lowered.

As described above, according to the liquefaction regasification system 1 of the present invention, the pressure of the liquefied natural gas supplied to the regasification apparatus 200 is controlled in consideration of only the pressure of the outlet side of the suction drum 300 for the recondenser. The control logic is simpler than the conventional system, and the condition of the inlet stage of the high pressure pump 210 is always constant regardless of the variation of the liquid level in the recondenser combined suction drum 300. I can keep it. In addition, by using the condensation effect can be treated with the boil-off gas (BOG) generated in the liquefaction storage tank 100 when operating the liquefaction regasification system (1) there is an economical effect.

On the other hand, below, with reference to the accompanying drawings will be described a liquefaction regasification method according to an embodiment of the present invention. However, the same description as that described in the liquefaction regasification system 1 according to an embodiment of the present invention will be omitted.

5 is a flowchart of a liquefaction regasification method according to an embodiment of the present invention, FIG. 6 is a flowchart in which a pressure control step is added to the liquefaction regasification method of FIG. 5, and FIG. 7 is a liquefaction recovery method of FIG. 5. This is a flowchart that adds a level control step to the conversion method.

Referring to these drawings and FIGS. 2 to 4, the liquefaction regasification method according to an embodiment of the present invention includes liquefied natural gas and evaporation from the liquefaction storage tank 100 to a recondenser combined suction drum 300. Supplying the gas (S100), the step of recondensing the evaporated gas in the re-condenser combined suction drum 300 (S200), and liquefied natural from the re-condenser combined suction drum 300 to the regasification apparatus 200 Supplying a gas (S300), and regasification of the liquefied natural gas in the regasification apparatus 200 and supplying to the demand destination (S400).

Recondensing the boil-off gas (S200), the amount of the boil-off gas supplied to the re-condenser combined suction drum 300 is received and supplied to the recondensing unit 320 of the re-condenser combined suction drum 300 based on this amount Computing the supply amount of the liquefied natural gas (S210) and the step of supplying the liquefied natural gas as the calculated supply amount to the recondensation unit 320 of the recombination suction drum 300 (S220).

On the other hand, the liquefaction regasification method of the present embodiment, measuring the outlet pressure of the re-condenser combined suction drum 300 and controlling the inlet flow rate of the re-condenser combined suction drum 300 based on the measured pressure (S500) And, further comprising the step of measuring the liquid level in the re-condenser combined suction drum 300 and controlling the liquid level in the re-condenser combined suction drum 300 based on the measured liquid level (S600).

Controlling the inlet flow rate of the re-condenser combined suction drum 300 (S500) and controlling the level of the liquid inside the re-condenser combined suction drum 300 (S600) may occur in a situation occurring during the regasification operation of liquefied natural gas. Accordingly.

First, the step (S500) of controlling the inlet flow rate of the recondenser combined suction drum 300 includes measuring the outlet pressure of the recondenser combined suction drum 300 (S510) and the measured recondenser combined suction drum ( And controlling the amount of liquefied natural gas flowing into the recondenser combined suction drum 300 from the liquefied storage tank 100 based on the outlet pressure of 300.

Next, the step (S600) of controlling the level of the liquid inside the re-condenser combined suction drum 300 includes measuring the level of the liquid inside the re-condenser combined suction drum 300 (S610) and the measured re-condenser combined suction drum. On the basis of the liquid level inside the 300, controlling the amount of regasified natural gas flowing into the upper portion of the re-condenser combined suction drum (300) (S620).

The operation of the liquefaction regasification method having such a configuration is the same as that of the above-described liquefaction regasification system 1, and thus is omitted.

As described above, according to the liquefaction regasification method of the present invention, the pressure of the liquefied natural gas supplied to the regasification apparatus 200 is controlled in consideration of the outlet pressure of the recondenser combined suction drum 300. The control logic becomes simpler and the conditions of the outlet of the recondenser combined suction drum 300, that is, the inlet stage of the regasification apparatus 200, are kept constant at all times regardless of the change of the liquid level in the recondenser combined suction drum 300. Can be. In addition, by using the condensation effect can be treated with the boil-off gas (BOG) generated in the liquefied storage tank 100 during the regasification operation of the liquefied natural gas has an economic effect.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1: liquefaction regasification system
51: first liquefaction input tube 52: second liquefaction input tube
53: output tube 61: first gas input tube
62: second gas input tube
100: liquid storage tank 200: regasification device
210: high pressure pump 220: vaporizer
300: suction drum for recondenser 310: suction drum
320: Re-condensing unit 321: Re-
322: liquid cargo distributor 500: supply flow control unit
510: Flow control valve 520: Flow meter
530: Flow control unit 600: Pressure control unit
610: pressure control valve 620: pressure meter
630: pressure control unit 700: level control unit
710: Level meter 720: Level control valve
730: Level control unit 800: Gas supply compressor
900: Compressor flow controller

Claims (13)

A liquefaction storage tank for storing a liquefaction;
A regasification apparatus supplied with liquefaction to regasification; And
And a recondenser combined suction drum receiving the liquefied gas and the evaporated gas from the liquefied storage tank, recondensing the evaporated gas, temporarily storing the liquefied liquid, and supplying the liquefied liquid to the regasification apparatus.
The recondenser combined suction drum,
A suction drum receiving the liquefied liquid and the evaporated gas from the liquefied storage tank and temporarily storing the liquefied liquid, and supplying the liquefied liquid to the regasification apparatus; And
And a recondensation unit provided at an inner upper portion of the suction drum, wherein the supplied liquefaction is in contact with the evaporating gas to recondense the evaporating gas. delete The method of claim 1,
The recondensation unit,
A recondensation unit provided at an inner upper portion of the suction drum; And
And a liquefaction distributor provided at an upper portion of the recondensation unit to receive liquefaction from the liquefaction storage tank and to distribute the liquefaction unit to the recondensation unit. The method of claim 1,
Liquefaction recovery unit further comprises a supply flow rate control unit for receiving the amount of the evaporated gas supplied to the re-condenser combined suction drum and adjusts the supply amount of the liquefied liquid supplied to the recondensing unit of the re-condenser combined suction drum System. 5. The method of claim 4,
The supply flow rate control unit,
A flow control valve provided in a first liquefaction input tube connecting the liquefied storage tank and the recondenser combined suction drum to adjust a flow rate of the liquefied liquid flowing into the recondensing unit of the recondenser combined suction drum;
A flow rate meter provided in a first gas input pipe connecting the liquefied storage tank and the suction drum for re-condenser to measure the flow rate of the evaporated gas flowing into the suction tank for the re-condenser; And
And a flow controller controlling the opening and closing of the flow control valve based on the received flow rate of the evaporated gas measured by the flow meter. The method of claim 1,
And a pressure control unit for measuring the outlet pressure of the recondenser combined suction drum and controlling the outlet pressure of the recondenser combined suction drum based on the measured pressure. The method according to claim 6,
The pressure control unit,
A pressure control valve provided in a second liquefaction input pipe connecting the liquefied storage tank and the recondenser combined suction drum to adjust the amount of liquefied liquid flowing into the recondenser combined suction drum;
A pressure measuring device provided in an output pipe connecting the recondenser combined suction drum and the regasification device to measure the pressure in the output pipe; And
And a pressure control unit for receiving the measured pressure from the pressure gauge and controlling opening and closing of the pressure control valve based on the received pressure. The method of claim 1,
And a level control unit for measuring the liquid level in the recondenser combined suction drum and controlling the liquid level in the recondenser combined suction drum based on the measured liquid level. 9. The method of claim 8,
The level control unit,
A liquid level measuring device for measuring a liquid level inside the suction drum of the recondenser;
A level control valve provided at a second gas input pipe connected to an upper portion of the recondenser combined suction drum from an outlet of the regasifying apparatus to adjust an amount of natural gas introduced into the recondenser combined suction drum; And
And a level controller configured to receive the measured liquid level from the level gauge and to control the opening and closing of the level control valve based on the level. The method of claim 1,
Liquefaction recovery further comprises a gas supply compressor provided on the first gas input pipe for supplying the boil-off gas from the liquefied storage tank to the re-condenser combined suction drum to compress and supply the boil-off gas to the re-condenser combined suction drum System. The method of claim 10,
It is connected to the gas supply compressor, and receives the pressure and the temperature of the outlet side of the re-condenser combined suction drum, based on this to adjust the amount of evaporated gas supplied to the re-condenser combined suction drum by the gas supply compressor And a compressor flow rate controller for controlling the gas supply compressor. Supplying liquefied and evaporated gas from the liquefied storage tank to the recondenser combined suction drum;
Recondensing boil-off gas in the recondenser combined suction drum;
Supplying liquefaction from the recondenser combined suction drum to a regasification apparatus; And
Regasifying the liquefied liquid in the regasification apparatus and supplying it to the demand source,
Recondensing the boil off gas,
Calculating an amount of liquefaction supplied to the recondensation unit of the recondenser combined suction drum based on the amount of the evaporated gas supplied to the recondenser combined suction drum; And
And supplying the calculated amount of liquefaction to the recondensation unit of the recondenser combined suction drum. delete

Images