KR20150041820A - Gas Liquefaction System And Method - Google Patents

Abstract

Disclosed are a gas liquefaction system and a method thereof. The gas liquefaction system of the present invention comprises a pipe transfer line for transferring gas, which is drilled for on the ground and then transferred; a preprocessing plant, which receives gas transferred through the pipe line and pre-processes the gas by being located on the coast; and a liquefaction plant, which floats on the sea to receive the gas preprocessed in the preprocessing plant, and to liquefy and store the gas.

Description

[0001] Gas Liquefaction System and Method [

The present invention relates to a gas liquefaction system and method, and more particularly, to a gas liquefaction system and method, and more particularly, to a gas liquefaction system and method, Gas liquefaction systems and methods.

As interest in environmentally friendly energy has increased, the consumption of natural gas has been rapidly increasing worldwide. Natural gas is transported in a gaseous state via land or sea gas piping, or is transported to a distant consumer where it is stored in an LNG carrier (particularly an LNG carrier) in the state of liquefied natural gas. Liquefied natural gas is obtained by cooling natural gas at cryogenic temperatures (approximately -163 ° C), and its volume is reduced to approximately 1/600 of that of natural gas, making it well suited for long-distance transport through the sea.

In order to produce liquefied natural gas (LNG) by liquefying natural gas drilled in oil wells or gas wells, the process of removing acid gas or sulfur oxide contained in natural gas And the like. Natural gas that has been subjected to various pretreatment processes is liquefied to produce LNG and transferred to the consumer.

The process of producing LNG from the drilled natural gas has been done by constructing a plant on the land. In recent years, however, the LNG production process has become more and more important. The LNG production process, such as LNG FPSO (Floating, Production, Storage and Offloading) Structures have been developed and are being carried out at sea.

Korean Patent No. 10-1138401

In order to transport liquefied natural gas to remote consumers, it is necessary to use vessels such as LNG carriers. In order to do this, natural gas drilled onshore is installed in a plant near the shore including gas pretreatment, liquefaction and storage facilities Transfer to the pipeline, then liquefy and store in the plant. In this way, when the liquefied LNG stored on the offshore plant is transported to the vessel and transported to the place of sale, a plant for processing all the processes on the land is installed. Therefore, the initial investment cost such as site acquisition cost and construction cost is high, In addition, in order to unload the produced LNG by ship, there is a problem that the cost for the ship port facility and the LNG unloading facility must be additionally increased. There may also be a problem of securing local manpower in the installation area and destroying the natural environment such as forests.

On the other hand, in FPSO, natural gas production, gas pretreatment, liquefaction and storage processes are all done at sea, LNG is stored, and then it is unloaded by ship and transported to the place of sale.

If a facility is installed to perform all the processes on an offshore structure, the footprint becomes very large and floats on the sea, so it is affected by the marine environment. Particularly, in the gas pretreatment process, distillation columns having a height of about 30 m are installed, and the efficiency of the distillation columns can be greatly influenced by the motion of the hull. The capacity of the utility system for cooling and heating is also very large, requiring large pipe diameters, pumps, heat exchangers, etc., so that the footprint becomes larger, making it difficult to design and dry the marine structure. In addition, if an expensive subsea production equipment is required and a specific component is excessive in the produced natural gas, a device for treating the natural gas must be provided in the structure, so that there is a problem that the footprint of equipment installed on the structure becomes larger.

Particularly, in the case of the structures provided on the sea, the natural gas drilled from the land is difficult to process in the sea structure, and the existing land infrastructure can not be utilized.

The present invention solves this problem and proposes an economical and compact gas liquefaction system.

According to an aspect of the present invention, in a gas liquefaction system,

A pipeline for transporting gas produced by drilling at least one of land and sea;

A pretreatment plant provided on the coast and supplied with the gas transferred from the pipeline and pretreated; And

There is provided a gas liquefaction system including a liquefaction plant which floats on the sea and is supplied with the gas pretreated from the pretreatment plant and liquefied and stored.

Preferably, the liquefaction plant includes: a hull floating on the sea; a liquefaction facility provided in the hull; a storage tank provided in the hull to store liquefied gas liquefied in the liquefaction facility; And a cargo handling device for unloading gas to the outside of the hull.

Preferably, the liquefaction plant further includes a power supply facility for supplying electricity necessary for the liquefaction plant, and the storage tank may be a membrane type NO 96 tank provided inside the hull.

Preferably, the pretreatment plant comprises an acidic gas removal unit for removing acidic gas including carbon dioxide and sulfur oxide from the gas, a dehydration unit for dehydrating the gas, And a mercury removal unit for removing the mercury.

Preferably, the pretreatment plant may further include a recovery processing unit for separating and recovering hydrocarbons having three or more carbon atoms including propane and butane contained in the gas.

Preferably, the gas may be at least one of natural gas and shale gas produced by drilling in at least one of land and sea.

According to another aspect of the present invention, in the gas liquefaction method,

1) transporting a gas produced by drilling at least one of land and sea to a pipeline;

2) pretreatment of the transferred gas including acid gas removal and dehydration treatment in a pretreatment plant provided along the coast of the land; And

3) feeding the pretreated gas to a liquefaction plant floating in the sea, liquefying and storing the gas.

In the gas liquefaction system of the present invention, the gas produced by drilling in the land is transferred to a pipeline to be pretreated in a pretreatment plant provided on the coast, and the liquefied liquefied plant floating in the sea is liquefied, stored and unloaded. By pre-treating the gas transferred through the offshore pipeline on the shore adjacent to the sea, it is possible to prevent the problem of low efficiency of the high distillation towers provided in the pretreatment plant due to the hull motion due to the sea condition, As the plant is dispersed and the offshore structures are unloaded, there is no need to build a port facility, which can shorten the construction air of the entire system.

Figure 1 schematically illustrates the concept of a gas liquefaction system in accordance with an embodiment of the present invention.
Figure 2 schematically shows a carrier moored to unload liquefied gas from a liquefaction plant in the embodiment of Figure 1;

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.

1 schematically shows the concept of a gas liquefaction system according to an embodiment of the present invention.

As shown in FIG. 1, the gas liquefaction system of the present embodiment includes a pipeline PL for transporting gas produced by drilling in the land G, and a gas supply pipe A pretreatment plant 100 for pretreatment and a liquefaction plant 200 for liquefying and storing the gas pretreated from the pretreatment plant 100 suspended in the sea.

In this embodiment, the gas to be liquefied through the pretreatment may be a natural gas or a shale gas produced by drilling in a well (G), a gas well, a sail gas layer (S), and the like.

The liquefaction plant 200 provided in the sea of the present embodiment includes a ship 210 floating on the sea, a liquefaction facility 220 provided on the ship 210, a liquefaction facility 220 provided on the ship 210, And an unloading device for unloading the liquefied gas stored in the storage tank 230 to the outside of the hull 210. The liquefied plant 200 is supplied with electricity necessary for the liquefaction plant 200 A power supply facility 240 for supplying power may be provided.

It is possible to mount the liquefier 220 on the topside of the hull 210 such as a barge floating on the sea and to store the liquefied gas such as LNG in the liquefaction facility 220 A storage tank (230) is provided inside the hull (210). The LNG stored in the storage tank 230 is unloaded to the cargo ship C through a cargo handling device (not shown), and is delivered to an external consumer.

As shown in FIG. 2, the carrier C for conveying the liquefied gas can be moored side by side on the side of the liquefying plant 200 hull 210, in which case the loading device is pumped to the side (Not shown), a pipe (not shown), a manifold (not shown), and the like, which can carry LNG in the storage tank 230 by a carrier line and can be unloaded.

The liquefaction plant 200 floating on the sea of the present embodiment of the present invention floats on the sea, liquefies and stores natural gas, and is capable of unloading the stored liquefied natural gas to a vessel such as an LNG carrier. FLSO (Floating Liquefaction , Storage and Offloading).

In the liquefaction plant 200 of this embodiment, when an anchoring facility is provided on a coastal sea in which the pretreatment plant 100 is provided, the liquefaction plant 200 is operated by berthing through an anchoring facility. When the berthing is difficult, Can be operated.

Meanwhile, the storage tank 230 provided in the liquefaction plant 200 may be a membrane type NO 96 tank provided along the side wall in the inside of the ship 210, and a plurality of the storage tanks 230 may be provided . If necessary, a stand-alone tank may be provided.

In addition, the liquefaction plant 200 may be provided with a liquefaction facility (not shown) for treating the evaporation gas generated from the stored liquefied gas, and the evaporation gas generated in the storage tank 230 may be re- And may be supplied as fuel to the power supply facility 240 of the liquefaction plant 200. The power supply facility 240 may be provided in such a manner that the evaporation gas or the LNG is directly generated in the liquefaction plant 200 by the fuel and the electricity transmitted from the outside is supplied to the liquefaction plant 200 It is possible.

In the present embodiment, the pretreatment plant 100 provided in the shore (G) comprises an acid gas removal unit (not shown) for removing acidic gas including carbon dioxide and sulfur oxide in the gas, And a mercury removal unit (not shown) for removing the mercury contained in the gas. The dehydration unit (not shown) processes the dehydration unit.

The LPG may be separated and sold depending on the components of the gas transferred to the pretreatment plant 100. The pretreatment plant 100 may be provided with a separator for separating and recovering the hydrocarbons having three or more carbon atoms including propane and butane contained in the gas, A Natural Gas Liquid Recovery unit (not shown) may also be provided.

According to another aspect of the present invention, in the gas liquefaction method,

1) transferring the gas produced by drilling in the land (G) to the pipeline (PL);

2) pretreating the transferred gas including acid gas removal and dehydration treatment in the pretreatment plant 100 provided on the coast of the land G; And

3) supplying the pretreated gas to a liquefaction plant 200 floating in the sea, liquefying and storing the gas.

As described above, in the gas liquefaction system according to the present invention, the gas liquefaction system transfers the gas produced by drilling in the land G to the pipeline PL, preprocesses it in the pretreatment plant 100 provided in the coast, The liquefying plant 200 floats in the liquefied liquefied and stored in the liquefied plant 200 and constitutes a system for unloading.

By thus pretreating the gas transferred through the pipeline PL of the land G in the land G adjacent to the sea, the efficiency of the high distillation columns provided in the pretreatment plant 100 due to the hull motion due to the sea state The problem of falling can be prevented. Also, since the pipeline (PL) is provided through the land (G), the installation of the pipeline (PL) is easy and the cost can be reduced. In addition, since the pretreatment plant 100 is not installed in the marine liquefaction plant 200, the footprint and utility system can be reduced, and the plant can be appropriately dispersed on the land (G) The construction air can be shortened and the offshore structure can be unloaded. Therefore, it is not necessary to construct a port facility, which can shorten the infrastructure construction air.

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 or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

G: Athletics
PL: Pipeline
100: Pretreatment plant
200: Liquefaction plant
210: Hull
220: Liquefaction facility
230: Storage tank
240: Power supply equipment
C: Carrier

Claims (7)

In a gas liquefaction system,
A pipeline for transporting gas produced by drilling at least one of land and sea;
A pretreatment plant provided on the coast and supplied with the gas transferred from the pipeline and pretreated; And
And a liquefaction plant floating on the sea and supplied with the gas pretreated from the pretreatment plant, liquefied and stored. The method according to claim 1, wherein the liquefaction plant
A floating hull at sea;
A liquefaction facility provided on the hull;
A storage tank provided in the hull to store liquefied gas liquefied in the liquefaction facility; And
And a unloading device for unloading the liquefied gas stored in the storage tank to the outside of the hull. 3. The method of claim 2,
Wherein the liquefaction plant further comprises a power supply facility for supplying electricity necessary for the liquefaction plant,
Wherein the storage tank is a membrane type NO 96 tank provided inside the hull. The method of claim 1, wherein the pretreatment plant
An acidic gas removal unit for removing acidic gas including carbon dioxide and sulfur oxide in the gas;
A dehydration unit for dehydrating the gas; And
And a mercury removal unit for removing mercury included in the gas. 5. The apparatus of claim 4, wherein the pretreatment plant
Further comprising a recovery processing unit for separating and recovering hydrocarbons having 3 or more carbon atoms including propane and butane contained in the gas. The method according to claim 1,
Wherein the gas is at least one of a natural gas and a shale gas produced by being drilled in at least one of land and sea. In the gas liquefaction process,
1) transporting a gas produced by drilling at least one of land and sea to a pipeline;
2) pre-treating the transferred gas including acid gas removal and dehydration treatment in a pretreatment plant provided along the coast of the land; And
3) supplying the pretreated gas to a liquefaction plant floating in the sea, liquefying and storing the gas.

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