KR20150007460A - LNG storage system for FLNG and method thereof - Google Patents

Abstract

The present invention relates to an LNG storage system and an LNG storage method of an FLNG and, more specifically, to an LNG storage system and an LNG storage method of an FLNG capable of storing a cryogenic LNG at regular levels in the LNG storage tanks such that the hull of the FLNG can have a stable restoring force, thereby contributing to a restoring force and a structural stability of the hull of the FLNG or the like to be installed in the sea for a long time. Provided are an LNG storage system of an FLNG and an LNG storage method of an FLNG using the same, wherein the LNG storage system of an FLNG comprises: an end flash drum receiving and storing an LNG; LNG supply lines connected to supply the LNG from the end flash drum to each plurality of LNG storage tanks installed in a hull; a plurality of flow rate control valves installed in the LNG supply lines controlling the supply of the LNG to the respective LNG storage tanks; a plurality of level transmitters installed to output detection signals by measuring the levels of the LNG in the respective LNG storage tanks; and a level master controller receiving the detection signals from the level transmitters, and controlling the degrees of opening of the flow rate control valves in order to allow the LNG supplied from the end flash drum to have regular levels in the LNG storage tanks.

Description

[0001] LNG storage system and method for FLNG [0002]

The present invention relates to an LNG storage system and method of FLNG, and more particularly, to a FLNG LNG storage system and method that are configured to store LNG liquefied in a FLNG at a cryogenic temperature in an LNG storage tank at a uniform level .

In general, natural gas is transported in the form of gas through land or sea gas pipelines, or stored in the LNG carrier in the form of Liquefied Natural Gas (LNG). Here, LNG is suitable for long distance transportation through the sea by reducing the volume of methane-based natural gas to approximately -163 ° C and reducing its volume to one-sixth.

Conventional liquefied LNG storage systems include a liquefied gas storage system for a liquefied natural gas liquefied gas liquefied gas storage system of Korean Patent Laid-Open No. 10-2007-0081882, Liquefied compressor and a liquefied natural gas carrier liquefied natural gas carrier which supplies the re-liquefied LNG to a plurality of storage tanks through the existing stripping / spray main header A liquefaction system comprising: a supply pipe having a plurality of split pipes connected to each of a plurality of storage tanks in a stripping / spray main header; a plurality of supply pipes arranged in the supply pipe; A first valve installed to control supply of the re-liquefied natural gas to the tank, and a second valve installed to control the supply of the re-liquefied natural gas A plurality of second valves installed on the divided pipes for supplying / blocking the respective liquefied natural gas to the storage tanks, and a second and third valves for detecting the presently chargeable amount of the plurality of storage tanks and sequentially supplying the liquefied natural gas to the storage tank. And a control unit for controlling the valve.

However, in the conventional liquefied LNG storage system, a relatively small amount of evaporation gas is re-liquefied in LNGC (LNG Carrier) and stored in the LNG storage tank, so that the produced natural gas is directly liquefied in the sea and stored in the LNG storage tank (Floating LNG). Particularly, FLNG is affected by waves more than LNGC due to the nature of the structure, and since it is installed on the sea for more than 20 years, the storage of liquefied LNG greatly affects the stability and structural stability of the ship. The conventional liquefied LNG storage system in which the LNG is simply stored sequentially in the LNG storage tank can not solve this problem.

Korean Patent Publication No. 10-2007-0081882

DISCLOSURE Technical Problem Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide an LNG storage tank in which LNG liquefied at a very low temperature is stored at a uniform level so that the FLNG hull has a stable restoring force, It is aimed to contribute to the restoration power and structural stability of installed FLNG.

According to an aspect of the present invention, there is provided a system for storing liquefied LNG in an LNG storage tank in an FLNG, the system comprising: an end flash drum for receiving and storing the liquefied LNG; An LNG supply line connected to supply LNG to each of the LNG storage tanks installed in the ship from the end flash drum; A plurality of flow regulating valves installed in the LNG supply line for regulating the supply of LNG to each of the LNG storage tanks; A plurality of level transmitters for measuring the level of each of the LNG storage tanks and outputting them as a sensing signal; And a level master controller for receiving the sensing signal from the level transmitter and adjusting the opening of the flow control valve so that the LNG can be maintained at a uniform level from the endflash drum to the plurality of LNG storage tanks LNG storage system of FLNG is provided.

The LNG supply line includes an LNG rundown header supplied with LNG from the end flash drum and installed along the longitudinal direction of the hull; And a branch line branched from the LNG rundown header and connected to each of the LNG storage tanks, wherein the flow control valve is installed.

Further comprising a level controller for measuring a level of the end flash drum and outputting the level of the end flash drum as a sensing signal, wherein when the level of the end flash drum is lower than a predetermined level by receiving the sensing signal output from the level controller, The flow control valve can be controlled to stop the supply of LNG to the LNG storage tank.

An LNG connection line connected to the LNG rundown header from the end flash drum; And a first safety valve installed in the LNG connection line.

And a second safety valve installed in each of the branch lines.

According to another aspect of the present invention, there is provided a system for allowing liquefied LNG in an FLNG to be stored in a plurality of LNG storage tanks,

An end flash drum for receiving and storing the liquefied LNG; And

Measuring the level of each of the plurality of LNG storage tanks so that a uniform level of LNG is stored in the plurality of LNG storage tanks from the end and flash drums and controlling the level of the LNG supplied to each of the plurality of LNG storage tanks There is provided an LNG storage system of an FLNG including a control unit for controlling a supply amount.

The control unit may include a level transmitter provided in each of the plurality of LNG storage tanks for measuring a level of the LNG storage tank and outputting a sensing signal; And a level master controller for receiving the sensing signal of the level transmitter and comparing the levels of the plurality of LNG storage tanks and controlling the LNG supply amount by adjusting an opening degree of a valve for supplying LNG to each of the LNG storage tanks have.

According to another aspect of the present invention, there is provided a method for allowing liquefied LNG in a FLNG to be stored in an LNG storage tank, comprising the steps of: 1) measuring the level of each of the plurality of LNG storage tanks; 2) comparing levels of each of the LNG storage tanks with each other; And 3) supplying LNG to the plurality of LNG storage tanks so as to maintain a uniform level from the end flash drum storing the liquefied LNG according to the result of the comparison.

In the step 3), the level master controller receiving the detection signals from the level transmitter installed in each of the LNG storage tanks is connected to the LNG storage tank, branched from the LNG rundown header connected to the end flash drum, The level of each of the LNG storage tanks can be adjusted by adjusting the opening degree of the flow control valve installed in the line.

According to the present invention, the FLNG's hull is kept at a uniform level in the LNG storage tank so that the liquefied LNG that has been liquefied at a cryogenic temperature can be stored at a stable level, thereby contributing to the restoration power of the FLNG and the structural stability .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of an LNG storage system of FLNG according to an embodiment of the present invention; FIG.
2 is a flowchart illustrating a method of storing LNG of FLNG according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

1 is a block diagram showing an LNG storage system of FLNG according to an embodiment of the present invention.

1, an FLNG LNG storage system 100 according to an exemplary embodiment of the present invention includes an end flash drum 110, an end flash drum 110, An LNG supply line 120 and 130 connecting the LNG storage tank 10 and a flow rate control valve 140 installed in the LNG supply line 120 and 130 and a level transmitter A level transmitter 150 for controlling the flow rate control valve 140, and a level master controller 160 for controlling the flow rate control valve 140.

The end flash drum 110 can receive and store liquefied LNG from a sub cooling heat exchanger (not shown). In addition, the end flash drum 110 receives and stores liquefied LNG in the liquefaction process of the natural gas which is formed on the top side of the FLNG (Floating LNG). The FLNG directly liquefies the produced natural gas from the sea, (LNG-Floating, Production, Storage and Offloading), which is a floating offshore structure that is stored in a storage tank and used to transport LNGC (LNG Carrier) when necessary.

LNG supply lines 120 and 130 are connected to supply LNG from each end flash drum 110 to each of the LNG storage tanks 10 installed in a plurality of hulls. Here, the LNG storage tanks 10 may be symmetrically arranged at the port and starboard sides of the ship so as to be arranged in plural along the longitudinal direction of the ship. In the present embodiment, four LNG storage tanks 10 are installed in the port and the starboard, respectively. However, the present invention is not limited thereto and the LNG storage tanks 10 may be installed in various numbers and arrangements.

The LNG supply lines 120 and 130 may include an LNG rundown header 120 and a branch line 130, for example. The LNG rundown header 120 is supplied with LNG from the end flash drum 110 and installed along the longitudinal direction of the hull to serve as a main path through which the LNG is supplied from the end flash drum 110. The branch line 130 is branched from the LNG rundown header 120 and connected to each of the LNG storage tanks 10 so that the branch lines 130 can be provided in a number corresponding to the number of the LNG storage tanks 10, A flow control valve 140 is installed in the branch line 130.

The LNG connection line 181 may be connected from the end flash drum 110 to the LNG rundown header 120 and the first safety valve 182 may be connected to the LNG connection line 181 to block the flow of LNG in an emergency . In addition, each branch line 130 may be provided with a second safety valve 131 to block the flow of LNG in an emergency.

A plurality of flow control valves 140 are provided in the LNG supply lines 120 and 130 to control the LNG supply to each of the LNG storage tanks 10 and to control the flow rate of the LNG as well as to open and close the LNG supply. May be provided in each of the branch lines 130 among the LNG supply lines 120 and 130 as in the embodiment, and may be a control valve controlled by the level master controller 160 and capable of adjusting the opening degree.

The level transmitter 150 is installed in each of the LNG storage tanks 10 in a plurality of levels to measure the level of each LNG storage tank 10 and output it as a sensing signal.

The level master controller 160 receives the sensing signal from the level transmitter 150 and controls the flow rate of the LNG storage tank 10 so that the LNG is supplied at a uniform level from the end flash drum 110 to the plurality of LNG storage tanks 10. [ Thereby adjusting the opening degree of the valve 140. Here, the uniform level does not mean that the levels of the LNG storage tanks 10 are 100% identical but also includes a level of a slight difference. This is due to the viscosity of the LNG, the difference in the path length between each LNG storage tank 10 from the end flash drum 110, and the like, even though the LNG storage tanks 10 are very precisely adjusted to distribute the LNG uniformly. Since a minute difference between levels of the tanks 10 can not be avoided, this difference must be taken into consideration.

A level controller 170 may be installed in the end flash drum 110 to measure the level and output the result as a sensing signal. At this time, the level master controller 160 stops the supply of the LNG to the LNG storage tank 10 when the level of the end flash drum 110 is lower than the predetermined level by receiving the detection signal outputted from the level controller 170 The flow rate control valve 140 can be controlled.

FIG. 2 is a flowchart illustrating a method of storing LNG of FLNG according to another embodiment of the present invention. This will be described by taking as an example the FLNG LNG storage system 100 according to an embodiment of the present invention.

As shown in FIG. 2, the method for storing LNG of FLNG according to another embodiment of the present invention is a method for storing liquefied LNG in FLNG in LNG storage tank 10, which comprises 1) a plurality of LNG storage tanks 10) measuring the level of each of the LNG storage tanks 10, 2) comparing the levels of the LNG storage tanks 10 to each other (S12), 3) And a step (S13) of supplying LNG to the plurality of LNG storage tanks 10 from the drum 110 so as to maintain a uniform level.

In the level measuring step S11, the level transmitter 150 installed in each of the LNG storage tanks 10 can measure the level of each LNG storage tank 10.

In step S12, the level master controller 160 receives the sensing signals for the level measured from the level transmitter 150, calculates the level for each of the LNG storage tanks 10, And compares the calculated levels so that leveling can be uniformly performed between the LNG storage tanks 10.

The level master controller 160 receiving the detection signal from the level transmitter 150 is branched from the LNG rundown header 120 connected to the end flash drum 10 in step S13 to uniformly supply the LNG The level of each of the LNG storage tanks 10 is adjusted by adjusting the opening degree of the flow control valve 140 installed in the branch line 130 connected to the LNG storage tank 10, So that the LNG is stored so that a uniform level can be achieved.

According to the FLNG LNG storage system and method of the present invention, since the LNG that has been liquefied at extremely low temperatures is stored in a plurality of LNG storage tanks 10 at a uniform level, FLNG's hull is balanced, So that it contributes to the resilience and structural stability of the hull such as FLNG installed in the sea for a long period of time.

In particular, structures such as FLNG float in the ocean for a long period of time, typically 20 years or more, and problems may occur in these LNG storage tanks for a long period of time. The present invention can ignore signals of the level transmitter 150 of the storage tank being checked through the level master controller 160 and check only the level values of the remaining storage tanks to store the LNG at a uniform level, It is possible to maintain the hull stability even during the operation.

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. It is.

10: LNG storage tank 110: end flash drum
120: LNG rundown header 130: branch line
131: Second safety valve 140: Flow control valve
150: Level transmitter 160: Level master controller
170: Level controller 181: LNG connection line
182: First safety valve

Claims (9)

A system for allowing liquefied LNG in FLNG to be stored in an LNG storage tank,
An end flash drum for receiving and storing the liquefied LNG;
An LNG supply line connected to supply LNG to each of the LNG storage tanks installed in the ship from the end flash drum;
A plurality of flow regulating valves installed in the LNG supply line for regulating the supply of LNG to each of the LNG storage tanks;
A plurality of level transmitters for measuring the level of each of the LNG storage tanks and outputting them as a sensing signal; And
And a level master controller for receiving the sensing signal from the level transmitter and adjusting the opening of the flow control valve so that the LNG can be maintained at a uniform level from the endflash drum to the plurality of LNG storage tanks LNG storage system of FLNG. The method according to claim 1,
Wherein the LNG supply line includes:
An LNG run down header supplied with LNG from the end flash drum and installed along the longitudinal direction of the hull; And
And a branch line branched from the LNG rundown header and connected to each of the LNG storage tanks, wherein the flow control valve is installed. The method according to claim 1 or 2,
Further comprising a level controller for measuring a level of the end flash drum and outputting the measured level as a sensing signal,
The level master controller includes:
And controlling the flow rate regulating valve to stop supplying the LNG to the LNG storage tank when the level of the end flash drum is lower than a predetermined level by receiving the sensing signal output from the level controller. system. The method of claim 2,
An LNG connection line connected to the LNG rundown header from the end flash drum; And
Further comprising a first safety valve installed in the LNG connection line. The method of claim 2,
And a second safety valve installed in each of the branch lines. A system for allowing LNG liquefied in FLNG to be stored in a plurality of LNG storage tanks,
An end flash drum for receiving and storing the liquefied LNG; And
Measuring the level of each of the plurality of LNG storage tanks so that a uniform level of LNG is stored in the plurality of LNG storage tanks from the end and flash drums and controlling the level of the LNG supplied to each of the plurality of LNG storage tanks The LNG storage system of the FLNG including a control unit for controlling the supply amount. 7. The apparatus of claim 6,
A level transmitter provided in each of the plurality of LNG storage tanks for measuring a level of the LNG storage tank and outputting a detection signal; And
And a level master controller for receiving the sensing signal of the level transmitter and comparing the levels of the plurality of LNG storage tanks and controlling the LNG supply amount by adjusting an opening degree of a valve for supplying LNG to each of the LNG storage tanks LNG storage system. A method for causing liquefied LNG in FLNG to be stored in an LNG storage tank,
1) measuring the level of each of the plurality of LNG storage tanks;
2) comparing levels of each of the LNG storage tanks with each other; And
3) supplying LNG to the plurality of LNG storage tanks so as to maintain a uniform level from the endflash drum storing the liquefied LNG according to the comparison result. The method of claim 8, wherein in step 3)
A level master controller for receiving a sensing signal from a level transmitter installed in each of the LNG storage tanks includes a flow rate adjusting valve installed in a branch line branched from an LNG rundown header connected to the end flash drum and connected to the LNG storage tank, Wherein the level of each of the LNG storage tanks is adjusted by controlling the opening degree of the LNG storage tank.

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