KR101258932B1 - LNG regasification plant - Google Patents

Abstract

The present invention relates to an LNG regasification plant.
According to an aspect of the present invention, a suction drum for storing LNG supplied from the LNG storage tank, a pump for pumping the LNG supplied from the suction drum at a high pressure, a vaporizer for vaporizing the LNG boosted by the pump, It is possible to provide an LNG regasification facility including a housing cooling line for supplying LNG from the suction drum to the housing of the pump, and an LNG discharge line for discharging the LNG of the pump.

Description

LG regasification plant

The present invention relates to an LNG regasification plant.

Liquefied natural gas (hereinafter referred to as "LNG") is a colorless transparent liquid obtained by cooling methane-based natural gas to about -162 ° C. and liquefying it. / 600. ≪ / RTI > Therefore, it is very efficient to transport liquefied LNG when transporting natural gas. For example, an LNG carrier that can transport (transport) LNG is used.

Recently, LNG carriers that can supply natural gas from the sea to consumers by installing a separate regasification facility have emerged, and are configured to perform the same role as a land LNG terminal by mounting a regasification facility on an offshore structure. There is also.

The LNG regasification facility for offshore structures including such vessels is provided by suction drums that temporarily store and supply LNG to facilitate and stabilize the control of LNG to be regasified, and pumps and pumps capable of boosting the LNG to high pressure. It may include a regasification unit consisting of a vaporizer for vaporizing the boosted LNG.

The pump must be supplied with LNG that has been sufficiently cooled in the suction drum, and some of the LNG can be evaporated by the heat generated by the pump to become boil-off gas. Evaporated gas generated from the pump may be discharged to the suction drum or the LNG storage tank.

However, the above-described conventional techniques have the following problems.

If the regasification unit is filled with LNG and maintains the standby state for a considerable time without regasification operation, the LNG temperature in the pump naturally rises and thus the supercooled state cannot be maintained. At this time, when driving the pump of the regasification unit in the atmosphere, excessive evaporation gas is generated and excessively generated evaporation gas is not properly discharged, so the level in the pump is drastically lowered, so that the operation of the regasification facility is stopped due to a level trip. .

In addition, when additional cool down should be performed to the pump without filling LNG, excessive boil-off gas is generated and the suction drum pressure increases as it flows into the suction drum, and the LNG level in the suction drum is sharply lowered. There was also a problem that the operation is stopped by the suction drum level trip.

Embodiments of the present invention are to provide an LNG regasification plant that allows the LNG inside the pump to maintain a supercooled state.

According to an aspect of the present invention, a suction drum for storing LNG supplied from the LNG storage tank, a pump for pumping the LNG supplied from the suction drum at a high pressure, a vaporizer for vaporizing the LNG boosted by the pump, It is possible to provide an LNG regasification facility including a housing cooling line for supplying LNG from the suction drum to the housing of the pump, and an LNG discharge line for discharging the LNG of the pump housing.

In addition, the housing cooling line may provide an LNG regasification plant, characterized in that connected to the lower end of the housing of the pump.

In addition, the LNG discharge line may provide an LNG regasification plant, characterized in that connected to the upper side of the housing of the pump.

In addition, the LNG discharge line may provide an LNG regasification facility, characterized in that a temperature sensor for sensing the temperature of the LNG is provided.

In addition, it is possible to provide an LNG regasification plant further comprises a first gas line for returning the boil-off gas generated in the pump to the suction drum.

In addition, it may provide an LNG regasification facility further comprises an LNG circulation line for recovering a portion of the LNG supplied from the pump to the vaporizer to the suction drum.

In addition, it may provide a LNG regasification plant further comprises a second gas line for recovering the vaporized gas generated in the vaporizer to the suction drum.

In addition, it is possible to provide an LNG regasification plant further comprises a main line of the boil-off gas to recover the boil-off gas generated in the suction drum to the storage tank.

Embodiments of the present invention can continuously supply the supercooled LNG into the pump, and by recovering the LNG temperature rise inside the pump to maintain the LNG in the pump supercooled state to drive the pump of the regasification unit waiting In this case, excessive generation of boil-off gas can be blocked.

In addition, the excessive generation of the boil-off gas in the pump is not properly discharged to lower the level in the pump can also eliminate the risk that the regasification plant is stopped.

1 is a block diagram showing an LNG regasification plant according to an embodiment of the present invention.

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

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a block diagram showing an LNG regasification plant according to an embodiment of the present invention.

As shown in FIG. 1, the LNG regasification plant 100 according to an embodiment of the present invention includes a suction drum 110 for storing LNG supplied from the LNG storage tank 1, and a suction drum 110. A pump 120 for pumping the LNG supplied from the high pressure and a vaporizer 130 for vaporizing the LNG boosted by the pump 120, and may be included in the regasification equipment installed in the offshore structure as well as ships All can be applied.

The suction drum 110 temporarily stores LNG supplied through the LNG supply line 170 from the LNG storage tank 1 to be supplied to the pump 120. Here, the LNG supply line 170 provides a path for LNG to be vaporized from the LNG storage tank 1 through the suction drum 110, the pump 120, the vaporizer 130.

The pump 120 increases the pressure of the LNG supplied from the suction drum 110. That is, the LNG is pumped at a high pressure to be supplied to the vaporizer 130.

The carburetor 130 receives the LNG boosted by the pump 120 through the LNG supply line 170, and vaporizes it and supplies the gas to the required destination 2. The fourth valve 131 and the fifth valve 132 may be installed on each side.

The LNG regasification plant 100 according to an embodiment of the present invention may be provided with one or more regasification units 240 including a pump 120 and a vaporizer 130, in this embodiment two in parallel. The connection will be described as an example.

The LNG supply line 170 is a main line 171 for supplying LNG from the suction drum 110 to the pump 120, and branches from the main line 171 to supply LNG to the housing 121 of the pump 120. A housing cooling line 173. A first valve 172 may be installed at the front end of the pump 120 of the main line 171, and the flow rate of LNG may be adjusted at the front end of the pump 120 of the housing cooling line 173. A second valve 174 can be installed.

The housing cooling line 173 may be connected to the lower end of the housing 121 of the pump 120, thereby preventing the overall temperature rise of the housing 121 of the pump 120, thereby causing excessive evaporation in the pump 120. Gas generation can be prevented. A flow path through which the LNG supplied through the housing cooling line 173 may flow may be formed in the housing 121 of the pump 120.

In this case, the housing cooling line 173 may be an LNG supply line for cooling down the pump 120.

In addition, in this embodiment, the housing cooling line 173 has been described as branching from the LNG supply line 170, but this is only an example, and the housing 121 of the pump 120 directly from the LNG storage tank 1 It may also be configured to supply LNG.

Meanwhile, an LNG discharge line 180 for discharging LNG having a relatively high temperature adjacent to the boil-off gas is connected to an upper side of the housing 121 of the pump 120. The LNG discharge line 180 may discharge LNG to at least one or more places of the LNG storage tank 1 and the suction drum 110. In this embodiment, the LNG discharge line 180 will be discharged to the LNG storage tank 1.

In detail, since the boil-off gas generated inside the pump 120 is located above the internal storage space of the pump 120, the temperature of the LNG located at the upper side of the housing 121 of the pump 120 is high. Since the high temperature LNG is discharged to the outside of the pump 120 through the LNG discharge line 180, it is possible to prevent the temperature of the housing 120 of the pump 120 to be prevented, so that the LNG inside the pump 120 is It can better maintain the supercooled state. The LNG discharge line 180 may be provided with a discharge valve 181 to adjust the flow rate of the LNG returned to the LNG storage tank (1).

In addition, the LNG discharge line 180 may be provided with a temperature sensor 190 that can detect the state of the LNG to return to the LNG storage tank (1). Based on the temperature value detected by the temperature sensor 190, it is possible to determine whether the inside of the pump 120 is maintained in a supercooled state, and accordingly, the opening amount of the second valve 174 and the discharge valve 181 is adjusted. Can be.

The first gas line 210 provides a path for the boil-off gas generated from the pump 120 side to move to the suction drum 110, and a third valve 211 for controlling the flow of the boil-off gas is provided. Can be installed.

The LNG regasification plant 100 according to the present invention is further connected to the rear end of the pump 120 on the main line 171 to further provide an LNG circulation line 220 for providing a path for the LNG to move to the suction drum 110. The LNG circulation line 220 may include a sixth valve 221 for controlling the flow of LNG.

In addition, the boil-off gas main line 250 is provided to provide a path for the boil-off gas generated in the suction drum 110 to move to the LNG storage tank (1) side. In addition, a second gas line 230 may be installed to provide a path for the vaporized gas between the vaporizer 130 and the required destination 2 to move toward the suction drum 110 for adjusting the suction drum pressure. The seventh valve 231 is installed on the line 230 to open and close the flow of the boil-off gas.

Referring to the operation of the LNG regasification plant according to the present invention having such a configuration as an example.

In the present invention, when the regasification unit 240 including the pump 120 and the vaporizer 130 is made of a single, it is possible to immediately resume the regasification operation in the standby state, when made of a plurality of regasification unit 240 The housing cooling line 173 and the LNG discharge line 180 may be operated to drive the standby regasification unit 240 without affecting the operating regasification unit 240.

That is, when LNG is filled in a single regasification unit 240 and the standby state is maintained for a considerable time without regasification operation, or LNG is filled in some of the regasification units 240 of the plurality of regasification units 240. In the case where the operation standby state is maintained for a long time, the LNG temperature in the pump 120 naturally rises, and thus the supercooled state cannot be maintained. At this time, when the pump 120 of the regasification unit 240 in the atmosphere is generated excessive evaporated gas.

In order to prevent this, by supplying the LNG to the housing cooling line 173 of the pump 120 of the regasification unit of the standby to the housing cooling line 173 to keep the pump 120 in a low temperature state, the LNG is high temperature discharged LNG Through the line 180 may be returned to the LNG storage tank (1). As a result, the LNG inside the standby pump 120 can maintain the supercooled state continuously, thereby suppressing generation of excessive boil-off gas.

In addition, by installing the temperature sensor 190 in the LNG discharge line 180 to properly control the second valve 174 and the discharge valve 181, it is possible to operate the regasification unit 240 at the optimum efficiency.

As described above as a specific embodiment of the LNG regasification plant according to an embodiment of the present invention, but this is only an example, the present invention is not limited to this, it is interpreted to have the broadest range in accordance with the basic idea disclosed herein Should be. Skilled artisans may implement a pattern of features that are not described in a combinatorial and / or permutational manner with the disclosed embodiments, but this is not to depart from the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

1: LNG storage tank 2: required
110: suction drum 120: pump
130: carburetor 170: LNG supply line
171 main line 173 housing cooling line
180: LNG discharge line 190: temperature sensor
210: first gas line 220: LNG circulation line
230: second gas line 240: regasification unit
250: main line of boil-off gas

Claims (9)

In LNG regasification plant,
A suction drum for storing LNG supplied from the LNG storage tank,
Pump to increase the pressure of the LNG supplied from the suction drum,
A vaporizer for vaporizing LNG boosted by the pump,
An LNG supply line for supplying LNG from the LNG storage tank to the pump,
The LNG supply line,
A main line for supplying LNG from the suction drum to the pump;
LNG regasification plant comprising a housing cooling line branching from the main line and connected to the housing bottom of the pump. The method of claim 1,
An LNG discharge line for discharging the LNG of the pump housing,
The LNG discharge line is an LNG regasification plant connected to at least one or more of the LNG storage tank or the suction drum. The method of claim 1,
The LNG discharge line is a LNG regasification plant, characterized in that connected to the upper side of the housing of the pump. The method according to any one of claims 1 to 3,
LNG regasification facility, characterized in that the LNG discharge line is provided with a temperature sensor for detecting the temperature of the LNG. The method according to any one of claims 1 to 3,
The LNG regasification plant further comprises a first gas line for returning the boil-off gas generated in the pump to the suction drum. The method according to any one of claims 1 to 3,
The LNG regasification plant further comprises a LNG circulation line for recovering a portion of the LNG supplied from the pump to the vaporizer to the suction drum. The method according to any one of claims 1 to 3,
And a second gas line for recovering the vaporized gas generated in the vaporizer to the suction drum. The method according to any one of claims 1 to 3,
LNG regasification plant further comprises a main line of the boil-off gas to recover the boil-off gas generated in the suction drum to the storage tank. The method of claim 1,
The LNG discharge line is LNG regasification facility, characterized in that for discharging the LNG to at least one of the storage tank and the suction drum.

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