KR20150000596A - Gasification Equipment Using Seawater For Liquefaction Process Test Of Ship - Google Patents

Abstract

Disclosed is a gasification equipment for a liquefaction process test of a ship using seawater. The gasification equipment for the liquefaction process test of a ship using seawater of the present invention supplies a gas to test the liquefaction process of the ship performing LNG liquefaction process, and comprises: a module body; a re-evaporator provided in the module body to re-evaporate LNG by receiving the LNG from an LNG storage tank of the ship; and a seawater circulation unit to supply seawater to the re-evaporator in order to re-evaporate the LNG as a heat source.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gasification equipment for seawater,

The present invention relates to a vaporizing device for a liquefaction process test of a ship using seawater, and more particularly, to a vaporizing device for a liquefaction process test of a ship using seawater, and more particularly, to a regeneration device and a seawater circulation device for supplying LNG from a LNG storage tank of a ship, The present invention relates to a vaporizing device for a liquefaction process test of a ship using seawater, which supplies sea water to a regenerator as a heat source for a ship.

Liquefied natural gas (LNG) is a colorless, odorless transparent liquid obtained by cooling methane-based natural gas to about -162 ° C and liquefying it. Compared to natural gas, And has a volume of about 1/600.

Such LNG was conventionally produced in a plant built onshore and supplied to the consumer through a carrier. However, as the development of offshore gas fields has recently increased, it is difficult to transfer natural gas from a land-based gas field to a land-based plant. In case of transporting natural gas through a pipeline, There is a problem of ensuring that LNG is produced by liquefying natural gas at sea, and the development of offshore structures equipped with production plants is becoming more active.

Floating Liquefied Natural Gas (FLNG) is an offshore structure that floats on the sea and treats LNG. Typically, LNG-FPSO (Floating Production, Storage and Offloading) ) And LNG-FSRU (Floating Storage and Regasification Unit). In particular, LNG-FPSO is a special ship capable of producing LNG, storing and liquefying LNG, and storing and storing LNG with natural gas drilled from offshore gas fields.

Since LNG-FPSO processes the production, liquefaction and storage stages at once, it can reduce the time and cost of LNG production and supply more than the conventional method, and when production is completed in one gas field, it moves to another sea gas field It can be used, so it can be economical.

Application No. 10-2010-0122050

FLNG, such as LNG-FPSO, is up to several hundreds of meters in size, and has a plant facility capable of producing and storing LNG by drilling natural gas into structures that can float on the sea, which is expensive from several hundred billion to several trillion . In addition, since it operates in the offshore gas field, if an abnormality occurs in various facilities, repairing can be difficult and limited compared with the land.

Therefore, it is necessary to verify the normal operation of the equipment through sufficient performance test before delivery to the owner, such as the drying and test operation phase.

In order to test the performance of liquefying process equipment such as FLNG, it is possible to test the liquefaction process of natural gas by supplying LNG to the FLNG for trial operation and regenerating it.

In order to test the performance of the liquefaction process equipment mainly on the coast, a device capable of regenerating the LNG stored in the FLNG is appropriately provided on the deck of the FLNG, and when the test is completed, the device for regenerating the LNG must be removed to obtain a wider usable space .

The present invention relates to a method for regenerating LNG using seawater which is easy to obtain from a ship as a heat source for regeneration so as to carry out liquefaction process test of a ship such as FLNG, To provide a modularized vaporization device that can be utilized in a variety of applications.

According to an aspect of the present invention, there is provided a vaporizer for supplying a gas for testing a liquefaction process of a ship on which a natural gas liquefaction process is performed,

Module body;

A regenerator provided inside the module body for supplying LNG from the LNG storage tank of the ship and regenerating the LNG; And

And a seawater circulation unit for supplying seawater to the regenerator as a heat source for regeneration of the LNG. The present invention also provides a vaporizing apparatus for a liquefaction process of a ship using seawater.

Preferably, the seawater circulation unit includes a seawater supply pipe for supplying the seawater to the regeneration unit, a flow switch provided in the seawater supply pipe, and a first shutoff unit provided in the seawater supply pipe for opening and closing the seawater supply pipe, valve; And a heat exchange unit in which seawater introduced from the seawater supply pipe exchanges heat with the LNG in the regenerator.

Preferably, the seawater circulation unit includes: a seawater discharge pipe for discharging seawater heat-exchanged through the heat exchange unit; a second shutoff valve provided in the seawater discharge pipe for opening and closing the seawater discharge pipe; And a temperature measuring instrument for measuring the temperature of the seawater discharged from the regenerator.

Preferably, the seawater circulation unit further includes a bypass pipe connecting the seawater supply pipe and the seawater discharge pipe, and a third isolation valve for opening and closing the bypass pipe. When the first isolation valve is shut off, The seawater can be discharged to the seawater discharge pipe through the bypass piping.

Preferably, the seawater supply pipe is connected to the pipeline to receive seawater.

Preferably, the vessel may be a FLNG comprising LNG-FPSO.

A vaporizing device for a liquefaction process test of a ship using seawater according to the present invention is a gas supply module including a regenerator for receiving and regenerating LNG from an LNG storage tank of a ship inside a module body, It is modularized and can be attached to and detached from the ship.

The vaporizer of the present invention is easy to operate by using seawater which can be relatively easily obtained from a ship as a heat source. In addition, it is possible to verify the performance of the vessel by testing the performance of the apparatus before it is applied to the field by supplying the LNG for the performance test of the liquefaction process apparatus through the modular vaporizer, The supply module can be detached, allowing a wider available space on the topside of the vessel. In addition, desorbed vaporizers are economical because they can be reused for testing of other vessels or offshore structures.

FIG. 1 schematically shows a vaporizer for testing a liquefaction process of a ship using seawater according to an embodiment of the present invention.
Fig. 2 schematically shows the flow of a liquefaction process test in which the vaporizer of Fig. 1 is connected to a ship.
Fig. 3 schematically shows the vaporizer of Fig. 1 being arranged on the vessel for the liquefaction process test.

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.

FIG. 1 schematically shows a vaporizer for testing a liquefaction process of a ship using seawater according to an embodiment of the present invention. FIG. 2 schematically shows a flow of a liquefaction process test in which a vaporizer of the present embodiment is connected to a vessel Respectively.

1 and 2, a vaporizer for testing a liquefaction process of a ship using seawater according to an embodiment of the present invention includes a vaporizer for supplying a gas for testing a liquefaction process of a ship on which a natural gas liquefaction process is performed, The apparatus includes a module body 100, a regenerator 200 provided inside the module body 100 for supplying LNG from the LNG storage tank T of the vessel and regenerating the LNG, And a seawater circulation unit 300 for supplying seawater as a heat source for regasification.

The ship of this embodiment means a maritime structure which is operated by sea or floating on the sea, and it means a ship requiring liquefaction process of LNG, especially FLNG such as LNG-FPSO and LNG-FSRU, LNG carrier, LNG-RV, or the like may be the vessel of this embodiment.

It is advisable that these ships constructed in the shipyard should be checked for their normal operation at the coast near the shipyard and subjected to a performance test before they are installed in the gas field or delivered to the shipowner. In order to test the performance of ships, especially liquefaction process, LNG should be produced through liquefaction process by supplying natural gas. The present embodiment modularizes the gas supply device for supplying LNG to the liquefaction processing apparatus 400 of the ship by vaporizing the LNG so that the liquefaction process can be tested, and is detachably attachable to the ship.

That is, in a ship such as a floating structure capable of performing the production, liquefaction and storage processes of natural gas, all facilities capable of performing these processes must be mounted in a limited space. In this embodiment, The re-ignition device is modularized so that it can be detached when the performance test of normal operation of the plant facility including the liquefaction process device 400 is completed. Particularly, the present embodiment makes it possible to more easily apply the present invention to a ship by using seawater which is easy to obtain from a ship as a heat source for LNG vaporization of the regenerator 200 through the seawater circulation unit 300.

The temperature of the seawater varies depending on the season and latitude at about 10 to 30 ° C for surface water and the constant temperature for 1 to 2 ° C for deep seawater. Therefore, a heat source for regenerating LNG at about -160 ° C .

In this embodiment, the seawater circulation unit 300 includes a seawater supply pipe 305 for supplying seawater to the regenerator 200, a flow switch 310 provided for the seawater supply pipe 305, A first shut-off valve 320 provided in the first regenerator 305 for opening and closing the seawater supply pipe 305 and a heat exchanger (not shown) for exchanging the seawater introduced from the seawater supply pipe 305 with the LNG in the regenerator 200, . ≪ / RTI >

The seawater is supplied to the regenerator 200 along the seawater supply pipe 305 by the signal of the flow switch 310. The seawater supplied to the regenerator 200 is heat exchanged with the LNG in the heat exchanger 200 to regenerate the LNG Generate natural gas.

The seawater circulation unit 300 is provided with a seawater discharge pipe 330 through which heat-exchanged seawater is discharged through the heat exchange unit. The cooled seawater is discharged through the seawater discharge pipe 330 through heat exchange. The seawater discharge pipe 330 is provided with a second shutoff valve 340 for opening and closing the seawater discharge pipe 330 and a temperature measuring system 350 for measuring the temperature of the seawater discharged from the regenerator 200.

The seawater circulation unit 300 includes a bypass pipe 360 for connecting the seawater supply pipe 305 and the seawater discharge pipe 330 and a third shutoff valve 370 for opening and closing the bypass pipe 360 When the first shutoff valve 320 is shut off, the seawater can be discharged to the seawater discharge pipe 330 through the bypass pipeline 360.

Preferably, the seawater supply pipe 305 is connected to the pipeline to receive the seawater. The seawater supply pipe 305 is connected to a seawater pump SP for supplying seawater to the ship through an evacuation pipe and about 6 to 8 bar of seawater is supplied to the seawater supply pipe 305 through a seawater pump SP .

The flow of the liquefaction process test in which the vaporizer of this embodiment is connected to the ship will be described with reference to the schematic diagram shown in FIG.

The LNG pumped from the LNG storage tank T is supplied to the suction drum 500 through the pump P of the pump tower provided for loading and unloading the LNG into the LNG storage tank T of the ship. A globe valve (not shown) and a check valve (not shown) are provided in the pipe connecting the LNG storage tank T and the suction drum 500 to adjust the supply of LNG, and the suction pressure of the suction drum 500 is measured A pressure gauge (not shown) and a safety valve (not shown) may be provided.

The LNG is introduced into the suction drum 500 through a high-pressure pump 510 provided at the front end of the vaporizer, compressed and supplied to the vaporizer.

The liquefied process apparatus 400 to be tested by the modularized vaporizer of the present embodiment may be a device in which a liquefaction process of natural gas is performed using nitrogen (N ₂ ) in a Niche dual expander method (Niche process). When the Niche process liquefaction process unit 400 is applied, the natural gas produced in the gas well is removed from the topside of the ship F by acid gas removal, dehydration, desulfurization, removal of heavy hydrocarbons Is introduced into the liquefying process apparatus 400 through a series of gas treatment processes in a natural gas state at a temperature of about 50 to 80 DEG C and a pressure of about 40 to 80 bar. Therefore, in the vaporizer, regenerated LNG must be supplied to correspond to the temperature and pressure conditions of the natural gas, so that the performance test of the liquefying and processing apparatus 400 can be performed properly. For this purpose, a high pressure pump 510 is provided and the high pressure pump 510 compresses the LNG at 40 to 80 bar, preferably 50 to 70 bar, more preferably 60 to 65 bar.

The suction drum 500 and the high-pressure pump 510 may be provided on the ship separately from the vaporizer, or may be provided on the upstream side of the regenerator 200 inside the module by including it in the vaporizer.

A flow control valve (not shown) and a safety valve (not shown) may be provided between the regenerator 200 and the high pressure pump 510 to regulate the flow rate of the LNG introduced into the regenerator 200, (Not shown) for returning the LNG exceeding the flow rate introduced into the high-pressure pump 200 to the suction side of the high-pressure pump 510 may be provided.

The LNG that has passed through the high pressure pump 510 is supplied to the vaporizer and regenerated through heat exchange with the seawater in the regenerator 200 and is introduced into the liquefaction process unit 400 after the phase change to natural gas. The gaseous section 522 is provided in the vaporization apparatus so that the temperature and pressure of the regenerated LNG through the regenerator 200 can be measured to satisfy the temperature and pressure conditions required for the liquefaction process apparatus 400. If the temperature of the natural gas introduced into the liquefying and processing apparatus 400 should be high, the seawater to be heat-exchanged with the LNG is heated before the heat exchange, or before the LNG regenerated by the seawater is supplied to the liquefaction apparatus 400 It can be heated. And is connected to the liquefying and processing apparatus 400 through the connection unit 600 at the rear end of the gauge unit.

An expansion joint 521 is provided at the front end and the rear end of the evaporator 200 so as to absorb the displacement due to the expansion when the LNG is regenerated from the seawater and the heat exchange in the regenerator 200 can do.

The liquefaction process test using the vaporizer of the present embodiment may be carried out by mooring a vessel to an LNG terminal and loading the LNG. In the case of a ship whose length over all is 300 to 700 m and is difficult to moor to a conventional LNG terminal, LNG carrier can be chartered and liquefied process test can be carried out by loading LNG from ship to ship from LNG carrier with point mooring (SPM), turret mooring, spread mooring or tug boat mooring .

For the liquefaction process test, the vaporizer can be placed at intervals necessary to maintain safety between the plant facilities for LNG production placed on the topside of the vessel, for example in the safety gap. In Fig. 3, the vaporizer 100 of this embodiment schematically shows a state where it is placed in the safety gap (SG) above the deck D of the vessel F for the liquefaction process test.

As described above, according to the present invention, there is provided a vaporizer for testing a liquefaction process of a ship using seawater, comprising: a regenerator (200) for supplying LNG from the LNG storage tank (T) The circulation unit 300 is provided to supply seawater to the regenerator 200 as a heat source for regeneration of the LNG.

As described above, the vaporization apparatus of the present invention can easily operate the module by using seawater which can be easily obtained from the ship as a heat source, and does not require a separate energy source for supplying the heat source, thereby realizing a compact module. Also, by supplying the LNG for the performance test of the liquefaction process unit 400 through the vaporizer, the performance of the device before being applied to the field is tested to fully verify the performance of the ship, To secure competitiveness, and to secure the reliability of ship owners.

Once the test is completed, the modularized vaporizer can be removed from the vessel, allowing a wider space available on the topside of the vessel, and the desorbed vaporizer is economical because it can be reused for testing other vessels or offshore structures.

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.

T: LNG storage tank
P: Pump tower pump
SP: Seawater pumps
100: Module body
200: regenerator
300: Seawater circulation part
305: Seawater supply piping
310: Flow switch
320: first shut-off valve
330: Sea water discharge piping
340: Second shut-off valve
350: Temperature meter
360: Bypass piping
370: Third shut-off valve
400: Liquefaction process unit
500: Suction drum
510: High pressure pump
521:
522: Gage Branch
600: connection

Claims (6)

A gasification apparatus for supplying a gas for testing a liquefaction process of a ship on which a natural gas liquefaction process is performed,
Module body;
A regenerator provided inside the module body for supplying LNG from the LNG storage tank of the ship and regenerating the LNG; And
And a seawater circulation unit for supplying seawater to the regenerator as a heat source for regeneration of the LNG. The method according to claim 1, wherein the seawater circulation unit
A seawater supply pipe for supplying the seawater to the regenerator;
A flow switch provided in the seawater supply pipe;
A first shut-off valve provided in the seawater supply pipe for opening and closing the seawater supply pipe; And
Wherein the seawater introduced from the seawater supply pipe is heat-exchanged with the LNG in the regenerator. The method according to claim 2, wherein the seawater circulation unit
A seawater discharge pipe through which the heat-exchanged seawater is discharged through the heat exchange unit;
A second shut-off valve provided in the seawater discharge pipe for opening and closing the seawater discharge pipe; And
Further comprising a temperature measuring unit provided on the seawater discharge pipe and measuring the temperature of the seawater discharged from the regenerator. The water treatment system according to claim 3, wherein the seawater circulation unit
A bypass pipe connecting the seawater supply pipe and the seawater discharge pipe; And
Further comprising a third shut-off valve for opening and closing the bypass piping,
Wherein when the first shutoff valve is shut off, the seawater is discharged to the seawater discharge pipe through the bypass pipeline. 3. The method of claim 2,
Wherein the seawater supply pipe is connected to the pipeline and supplied with seawater. The method according to claim 1,
Wherein the vessel is an FLNG including LNG-FPSO.

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