KR20130074266A - Storing container for liquefied natural gas - Google Patents

Abstract

PURPOSE: A storage container for liquefied natural gas is provided to reduce manufacturing costs by supporting the expansion and contraction of an inner shell and minimizing the use of metal. CONSTITUTION: A storage container for liquefied natural gas comprises an inner shell (110), an outer shell, an insulation layer (140), multiple extensions, a reinforced plastic, a cover (1330), and a support unit. The inner shell stores liquefied natural gas therein. The outer shell surrounds the outer side of the inner shell to form the space between the outer shell and the inner shell. The insulation layer is installed in the space between the outer and inner shells and reduces the transfer of heat. The extensions are extended from the outer shell to the outside. The reinforced plastic supports the inner shell. The cover seals the extensions. The support unit supports the inner shell by connecting the reinforced plastic and the cover to each other and absorbs the expansion and contraction of the inner shell.

Description

Storage container for liquefied natural gas {STORING CONTAINER FOR LIQUEFIED NATURAL GAS}

The present invention relates to a storage container for liquefied natural gas, which can efficiently supply liquefied natural gas, as well as liquefied natural gas pressurized at a constant pressure, to be supplied to a consumer, and minimize the use of a metal having excellent low temperature properties to reduce manufacturing costs. It relates to a liquefied natural gas storage container having an inner shell configured to reduce and a manufacturing method.

In general, liquefied natural gas (LNG) is a colorless transparent cryogenic liquid whose natural gas containing methane as its main component is cooled to cryogenic condition at -162 ℃ at atmospheric pressure, and its volume is reduced to one hundredth. It is known that it is economical for long distance transportation because it has better transport efficiency than gas state.

Such liquefied natural gas has been applied to large-scale and long-distance transportation in order to satisfy economic feasibility due to the high cost of construction of the production plant and the construction of carriers, whereas pipelines or compressed natural gas (CNG) for small- and short-haul transportation have been applied. Although it is known to have economic feasibility, transportation by pipelines is subject to geographical constraints, may cause problems of environmental destruction, and CNG has a disadvantage of low transportation efficiency.

In addition, natural gas has a liquefaction point of -163 ℃ at atmospheric pressure, when a certain pressure is applied has a characteristic that the liquefaction point rises under atmospheric pressure. This characteristic can reduce the processing steps such as removal of acid gas and fractionation of natural gas liquid (NGL) during the liquefaction process, which leads to a reduction in equipment and equipment capacity. It has the advantage of reducing the production cost of.

However, the liquefied natural gas storage tank provided in a conventional liquefied natural gas terminal or a vessel equipped with a gasification facility is not only limited to a certain size, but also liquefied natural gas which has economical characteristics by reflecting the characteristics of the natural gas as described above. It is difficult to transport liquefied natural gas to the consumer, which is inadequate for the storage, and to meet the needs of various consumers.

In order to solve the above problems, in order to store not only general liquefied natural gas but also liquefied natural gas pressurized at a constant pressure, a container is made to withstand cryogenic and high pressure of -120 ° C or more by using a metal material having excellent low temperature characteristics. This is possible, but for this purpose, the wall thickness of the container is inevitably increased, and there is another problem of difficulty in securing economic feasibility due to the use of expensive metal having excellent low temperature characteristics.

The present invention is to solve the conventional problems as described above, liquefied natural gas as well as liquefied natural gas pressurized at a constant pressure can be efficiently stored and supplied to the consumer, and minimize the use of metal with excellent low-temperature characteristics The purpose of the present invention is to provide a storage container for liquefied natural gas, which can secure structural stability and manufacturing economy due to temperature and pressure by reducing manufacturing costs.

According to an aspect of the present invention for achieving the above object, a container for storing liquefied natural gas, the inner shell 110 for storing the liquefied natural gas inside; An outer shell 120 surrounding an outer side of the inner shell 110 to form a space between the inner shell 110; An insulating layer part 140 installed in the space 115 between the inner shell 110 and the outer shell 120 to reduce heat transfer; A plurality of extensions 1310 extending outwardly from the outer shell 120; Reinforced plastics (150) installed in the space (115) of the height at which each of the extension portions (1310) are located, and support the inner shell (110) in contact; A cover 1330 installed at an outer end of each of the extension parts 1310 to seal the extension part 1310; And supporting means (1360) for connecting the reinforcement plastics (150) and the cover (1330) to support the inner shell (110) and absorb the contraction and expansion of the inner shell (110). It provides a storage container for liquefied natural gas characterized by.

The reinforcement plastic 150 is made of a low-temperature reinforcement plastic to reduce the heat transfer while withstanding the low temperature of the liquefied natural gas delivered from the inner shell (110).

The support means (1360), one end is connected to the reinforcement plastic 150, the other end is a support rod (1350) positioned to have a predetermined distance (d) with the cover (1330); And an elastic part 1340 having one end fixedly connected to the supporting rod 1350 and the other end connected to the inside of the cover 1330.

The support means 1360 may include: a first elastic part support member 1341 formed at an inner side of the inner shell 110 of the support rod 1350 to which one end of the elastic part 1340 is connected; A second elastic part supporting member 1342 formed on an inner side of the cover 1330 and protruding toward an inner space side of the extension part 1310 and connected to the other end of the elastic part 1340; It features.

The support means 1360, a reinforcing member (1351) formed at one end of the support rod (1350) connected to the reinforcement plastic 150; characterized in that it further comprises.

The elastic portion 1340, the disc spring (disc spring); characterized in that.

The outer end of the extension portion 1310 and the cover 1330 are flanged by a flange 1320 formed in each; characterized in that the.

The inner shell 110 is a cylindrical structure; characterized in that.

The inner shell 110 forms a corrugated structure 1110;

The pleat structure 1110 is composed of one or more pleats 1111, the pleat 1111 is formed to have one or more bends (1112);

The curved portion 1112 may be formed to have at least one of an angled corner curved portion, a rounded corner curved portion, and a wavy curved portion.

The inner shell 110 is made of a metal that withstands low temperature of the liquefied natural gas, the outer shell 120 is made of a steel (steel) material to withstand the internal pressure of the inner shell 110; do.

The inner shell 110 withstands a temperature of -120 ~ -95 ℃, the outer shell 120 withstands a pressure of 13 ~ 25bar;

The inner shell 110 and the outer shell 120 of the storage container such that the pressure of the space 115 between the inner shell 110 and the outer shell 120 of the storage container and the pressure inside the inner shell 110 are balanced. It is characterized in that it comprises a; connecting flow path installed between the space between the inner shell and the inner shell (110).

According to another aspect of the present invention, in the container for storing liquefied natural gas, the inner shell 110 is formed by placing the inner shell 110 on the inside of the storage container and the outer shell 120 on the outside. A heat insulation layer portion 140 is installed in the space 115 between the outer shell 120 and the outer shell 120, and the inner shell 110 is contacted and supported separately from the heat insulation layer portion 140 in the space 115. Inserting the reinforcement plastic 150, and between the reinforcement plastic 150 and the outer shell 120 to install a support means 1360 for absorbing the contraction and expansion of the inner shell 110; It provides a storage container for liquefied natural gas.

The outer shell 120 further includes a plurality of extensions 1310 extending to the outside and a cover 1330 for sealing an outer end of each of the extensions 1310, wherein the reinforced plastic 150 is the Installed in the space 115 at a height at which each of the extension parts 1310 is positioned, the support means 1360 connecting the cover 1330 and the reinforcement plastic 150, respectively; .

The support means (1360), one end is connected to the reinforcement plastic 150, the other end is a support rod (1350) positioned to have a predetermined distance (d) with the cover (1330); And an elastic part 1340 having one end fixedly connected to the support rod 1350 and the other end connected to the inside of the cover 1330. The elastic part 1340 includes the inner shell 110. Absorbing contraction and swelling of the; .

The inner shell 110 to form a corrugated structure (1110); .

The pleat structure 1110 is composed of one or more pleats 1111, the pleat 1111 is formed to have one or more bends (1112);

The inner shell 110 is made of a metal to withstand the low temperature of the liquefied natural gas, the outer shell 120 is made of a steel (steel) material to withstand the internal pressure;

The space between the inner shell 110 and the outer shell 120 of the storage container and the inner shell 110 so that the pressure between the inner shell 110 and the outer shell 120 and the pressure of the inner shell 110 is balanced. It is characterized in that the connection flow path is installed between the shell (110).

According to the present invention, the liquefied natural gas as well as the liquefied natural gas pressurized at a constant pressure can be efficiently stored and supplied to the consumer, and the elastic portion can support the expansion and contraction of the inner shell, so that the inner shell has low temperature characteristics. Manufacturing costs can be reduced by minimizing the use of good metals.

In addition, the internal pressure of the inner shell and the inner pressure of the insulation layer are designed to have a similar value to ensure structural safety, and the outer shell is used as a steel material that can withstand the internal pressure of the insulation layer, and thus, the high-temperature and low-temperature characteristics are excellent. The use of metals can be reduced to reduce manufacturing costs.

In addition, due to the inner shell of the corrugated structure, the structural strength of the inner shell is increased, the buckling strength is also significantly increased, so that the container can be manufactured in a thin plate, thereby reducing the manufacturing cost.

In addition, since the inner shell of the corrugated structure can absorb the heat deformation of the inner shell to prevent the occurrence of excessive thermal stress can ensure the structural stability.

1 is a longitudinal sectional view schematically showing a storage container of liquefied natural gas according to an embodiment of the present invention.
Figure 2 is a cross-sectional view schematically showing a storage container of liquefied natural gas according to an embodiment of the present invention.
3 is an enlarged view of a portion A of FIG. 2;
4 is an exploded view of each component of FIG. 3;
5 is a view showing the displacement control by the support of the liquefied natural gas storage container according to the present invention.
Figure 6 is a longitudinal sectional view schematically showing a liquefied natural gas storage container 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.

In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

1 is a longitudinal sectional view schematically showing a storage container of liquefied natural gas according to an embodiment of the present invention, Figure 2 is a cross-sectional view schematically showing a storage container of liquefied natural gas according to an embodiment of the present invention. 3 is an enlarged view of A of FIG. 2, FIG. 4 is an exploded view of each component of FIG. 3, and FIG. 5 is a view showing displacement control by a support of a liquefied natural gas storage container according to the present invention. 6 is a longitudinal sectional view schematically showing a liquefied natural gas storage container according to another embodiment of the present invention.

1 to 5, the storage container of the liquefied natural gas according to an embodiment of the present invention, a container for storing the liquefied natural gas, the inner shell 110 is disposed inside the storage container and the outer Insulating layer portion 140 to reduce heat transfer in the space 115 between the inner shell 110 and the outer shell 120 is formed by placing the outer shell 120 in the heat insulating layer portion ( Support means for absorbing the contraction and expansion of the inner shell 110 between the reinforcement plastic 150 and the outer shell 120 is inserted into the reinforcement plastic 150 to contact and support the inner shell 110 separately from the 140 1360 is provided.

In this case, the outer shell 120 further includes a plurality of extensions 1310 extending to the outside and a cover 1330 for sealing an outer end of each of the extensions 1310, wherein the reinforced plastic 150 is extended. Each of the parts 1310 may be installed in a space 115 having a height, and the support means 1360 may connect the cover 1330 and the reinforcement plastic 150, respectively.

Due to this configuration, the support means 1360 is able to absorb the contraction and expansion of the inner shell 110 due to the cold heat and evaporation of the liquefied natural gas stored inside the inner shell 110, and also to strengthen the reinforced plastic Since the supporting means 1360 is not exposed to the low temperature environment of the liquefied natural gas, the supporting means 1360 can be manufactured using a material for room temperature, thereby making it possible to manufacture the liquefied natural gas storage container more economically.

Looking at the configuration of the storage container of the liquefied natural gas according to the present invention in detail, for example, the inner shell 110, the outer shell 120, the heat insulating layer portion 140, the extension portion 1310, reinforced plastic 150, The cover 1330 and the support means 1360 may be configured.

The inner shell 110 forms a space for storing the liquefied natural gas inside the storage container, and has a low temperature characteristic such as a metal that withstands low temperature of the liquefied natural gas, for example, aluminum, stainless steel, and 5 to 9% nickel steel. It may be made of an excellent metal, and may have a cylindrical structure (tube form) as in the present embodiment, or may have various shapes including other polyhedrons.

The outer shell 120 surrounds the outside of the inner shell 110 to form a space 115 between the inner shell 110 and may be made of steel.

At this time, the internal pressure applied to the inner shell 110 is shared by a connection flow path to be described later, so that the outer shell 120 withstands the inner pressure of the inner shell 110, thereby reducing the amount of material used for the inner shell 110. It is possible to further reduce the manufacturing cost of the storage container.

The heat insulation layer part 140 is installed in the space 115 between the inner shell 110 and the outer shell 120, and is made of a heat insulating material to reduce heat transfer, so that the cold heat of the liquefied natural gas stored in the inner shell 110 is liquefied. Prevents natural gas from evaporating

The insulation layer 140 may have a structure or a material design in which the same pressure (pressure balance) as the pressure in the inner shell 110 is applied, and the same pressure (pressure) between the insulation layer 140 and the inside of the inner shell 110. Connection paths (not shown) may be installed to form a balance.

As such, when a connection flow path is installed between the heat insulation layer part 140 and the inner shell 110, and the pressure is balanced between the inner shell 110 and the outer 115, the outer shell 120 supports a considerable portion of the pressure. It is possible to reduce the thickness of the inner shell (110).

In addition, since the pressure of the inner shell 110 and the heat insulating layer 140 may be the same as or close to the inner shell 110 by the connection flow path, the pressurized liquefied natural gas having a predetermined pressure applied to the liquefied natural gas is the inner shell ( Even if stored in the 110, the outer shell 120 can sufficiently support the internal pressure of the inner shell 110, thereby reducing the thickness of the inner shell 110.

 Therefore, since the inner shell 110 can be formed to have a smaller thickness than the thickness of the outer shell 120, the manufacturing cost can be reduced by reducing the use of expensive metal having excellent low temperature characteristics when manufacturing the storage container of liquefied natural gas. It becomes possible.

Natural gas has a characteristic that the liquefaction point becomes higher under atmospheric pressure (for example, -120 to -95 ° C) when it is constantly pressurized (for example, 13 to 25 bar). In order to reduce the energy required for liquefaction, the inner shell 110 is manufactured to withstand the temperature of the liquefied natural gas (for example, -120 to -95 ° C) at a constant pressure (for example, 13 to 25 bar). And the outer shell 120 can be produced to withstand a certain pressure (for example, 13 ~ 25bar) to achieve the effect of reducing the manufacturing cost of the liquefied natural gas as described above.

As described above, the storage container of the liquefied natural gas according to the present invention has an inner shell 110 made of a metal having excellent low temperature characteristics and a high strength steel to store not only natural gas liquefied under atmospheric pressure but also pressurized liquefied natural gas. Insulation layer portion 140 having a thickness for maintaining a proper BOR (Boil Off Rate) is also installed between the outer shell 120 and the outer shell 120, and pressure balance between the inner and outer sides of the inner shell 110 is provided. Due to this, the thickness of the inner shell 110 may be reduced to reduce the use of expensive metals having excellent low temperature characteristics.

In addition, it is possible to prevent the occurrence of structural defects due to the internal pressure of the inner shell 110, it is possible to provide a storage container with excellent durability.

Extension portion 1310 is installed to extend from the outer shell 120 to the outside, the reinforcement plastic 150 to be described later is connected to the reinforcement plastic 150 to support and support the inner shell 110 to be described later It provides a space in which the means 1360 are installed.

The extension part 1310 may be provided in plural in various positions of the outer shell 120 so that the reinforced plastic 150 can stably contact and support the inner shell 110.

The reinforcement plastics 150 are respectively installed in the spaces 115 having a height at which each of the plurality of extension portions 1310 are positioned, and contact and support the inner shell 110. The inner shell 110 is stably contacted and supported. To do so, as shown in Figure 2, it is installed to be in contact with the inner shell 110 of a large area.

Since the reinforced plastic 150 is installed separately from the heat insulation layer unit 140 in the space 115 between the inner shell 110 and the outer shell 120, the cold heat of the liquefied natural gas stored in the inner shell 110 is It is preferable to manufacture a material (for example, low temperature reinforced plastic) that can withstand the low temperature of liquefied natural gas while having a heat insulating function so as not to be transferred to the outside.

The cover 1330 is installed at the outer end of each of the extension parts 1310 to seal the extension part 1310, but may be sealed in various ways, but it may be desirable to seal the detachable part. This is to facilitate the separation of the inner shell 110 and the outer shell 120, and other components when the maintenance and repair work of the storage container is required later.

That is, as shown in FIG. 3, the cover 1330 may be sealed and fixed by inserting an adhesive into a portion of the cover 1330 in contact with the end of the extension part 1310, or may be sealed by welding. In order to form the removable cover 1330, the flange 1320 may be formed on each of the outer ends of the extension part 1310 and the cover 1330 to be coupled to each other so as to be fastened using bolts and nuts. .

The support means 1360 connects each of the reinforcement plastic 150 and the cover 1330 to support the inner shell 110, and absorbs the contraction and expansion of the inner shell 110. ) And an elastic portion 1340.

The support means 1360 structurally reinforces the inner shell 110 and the outer shell 120 while supporting the inner shell 110 and the outer shell 120, and as described above, the inner shell (110) by the reinforced plastic 150. Since it is not affected by the liquefied natural gas stored in 110, it is not necessary to manufacture the metal (eg, low temperature steel) to endure the low temperature of the liquefied natural gas.

And, as shown in Figures 1 and 2, as shown in Figure 1, the plurality of installation along the circumference of the outer shell 120, or a plurality of spaced up and down at the side of the outer shell 120 to be installed. Can be.

One end of the support rod 1350 is connected to the reinforcement plastic 150, and the other end thereof is positioned to have a predetermined distance d from the cover 1330. The elastic part 1340 has one end of the support rod 1350. Is fixedly connected to, and the other end may be connected to the inside of the cover 1330.

One end of the supporting rod 1350 is connected to the reinforcement plastic 150 that contacts and supports the inner shell 110, and the other end has a predetermined distance d from the cover 1330, thereby allowing the inner shell 110. Due to the expansion and contraction of the liquefied natural gas stored inside the inner shell 110, the inner shell 110 can move as much as the displacement that expands and contracts when the inner shell 110 expands and contracts.

At this time, the moving displacement amount is a displacement by the distance d between the other end of the support rod 1350 and the cover 1330, and the displacement amount exceeding this is supported by the cover 1330 connected to the outer shell 120. do.

 In addition, the support rod 1350 may also serve to support the elastic part 1340 to maintain a constant position in the extension part 1310.

The elastic part 1340 is fixedly connected to one end of the support rod 1350 to support the expansion and contraction force when the inner shell 110 expands and contracts. In addition, in consideration of economics, a general spring having a space therein (a space into which the supporting rod 1350 can be inserted) may be installed, or a disc spring may be installed to allow the inner shell 110 to have a predetermined displacement. The inner shell 110 can be supported when expanding or contracting.

When the inner shell 110 is expanded, a compressive force is applied to the elastic part 1340 to support the inner shell 110 by the elastic part 1340. When the inner shell 110 contracts, the elastic part ( Since the inner shell 110 may not be supported by the 1340, the elastic portion 1340 may be used in such a contracted displacement amount in consideration of the displacement amount when the inner shell 110 is contracted when the elastic portion 1340 is installed. Is preferably connected to the cover 1330 in a state in which the elastic portion 1340 is compressed to some extent to support the inner shell (110).

As shown in FIG. 3, first and second support members 1341 and 1342 supporting the elastic part 1340 may be additionally added to the support means 1360.

The first elastic part supporting member 1342 is formed on the inner shell 110 direction side of the supporting rod 1350 so that one end of the elastic part 1340 is connected, and the second elastic part supporting member 1342 is a cover ( Is formed on the inner side of the 1330 and protrudes toward the inner space side of the extension portion 1310, the other end of the elastic portion 1340 is connected, considering the magnitude of the force that the elastic portion 1340 supports the inner shell 110. By adjusting the distance between the support members (1341, 1342) to adjust the elastic force of the elastic portion 1340.

One end of the support rod 1350 may be connected to the reinforcement plastic 150 by installing a reinforcing member 1351, and by widely distributing the force applied to the inner shell 110 by the elastic portion 1340, It is desirable to have a large surface area so as to prevent damage to the shell 110 to contact the reinforcement plastic 150 in a large area.

As shown in FIG. 6, the storage container of the liquefied natural gas according to another embodiment of the present invention may be manufactured to have a cylindrical (or tubular) shape having an inner shell 110 having a corrugated structure 1110.

The corrugation structure 1110 formed in the inner shell 110 may have various bends 1112 according to the cross-sectional shape of the corrugations, and may have one or more corrugations 1111 having various bends 1112.

One or more corrugations 1111 may determine the bending angle 1113, the corrugation depth 1114, and the corrugation distance 1115 to have the same shape throughout one inner shell 110, or some may have different shapes. The bending angle 1113, the wrinkle depth 1114, and the wrinkle distance 1115 may be determined such that the whole shapes have different shapes.

The shape of the various curved portions 1112 may have various shapes such as an angled corner curved portion, a rounded corner curved portion, and a wavy curved portion.

FIG. 6 illustrates an inner shell 110 fabricated such that four angled corner flexures 1112 are formed in one corrugation 1111, and various configurations of the bending angles 1113 of the angled corner flexures 1111 are various. It will be possible to have various shapes of wrinkles.

In FIG. 6, although the corrugation structure 1110 is formed on the side of the outer surface of the inner shell 110, the corrugation structure 1110 may be formed on the upper cover or the lower cover as well as the side surface.

The storage container of the liquefied natural gas according to the present invention may be installed in the transverse direction, in which case the components supporting the inner shell 110 should be installed on the side of the outer shell 120.

Hereinafter will be described the operation of the storage container of the liquefied natural gas according to the present invention.

The inner shell 110 of the liquefied natural gas storage container is in contact with and supported by the reinforced plastic 150. As shown in FIG. 5, the liquefied natural gas stored inside the inner shell 110 is evaporated to form an inner shell ( When the 110 is expanded, the reinforced plastic 150 also expands to the outside, so that the support means 1360 supporting the reinforced plastic 150 also expands together.

At this time, after expanding by the distance d between the supporting rod 1350 and the cover 1330, the other end of the supporting rod 1350 comes into contact with the cover 1330, and thereafter, the cover 1330 and The outer shell 120 supports the expansion of the inner shell 110.

As can be seen from the various embodiments of the present invention described above, the present invention provides a storage container capable of stably and economically storing the liquefied natural gas and pressurized liquefied natural gas to achieve the various effects described above.

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 will be.

110: inner shell 115: space
120: outer shell 1310: extension
1320: flange 1330: cover
1340: elastic portion 1341: first elastic portion support member
1342; Second elastic portion support member 1350: support rod
1351: reinforcing member 1360: support means
140: heat insulation layer portion 150: reinforced plastic
d: gap between cover and supporting rod

Claims (21)

In the container for storing liquefied natural gas,
An inner shell 110 storing the liquefied natural gas inside;
An outer shell 120 surrounding an outer side of the inner shell 110 to form a space between the inner shell 110;
An insulating layer part 140 installed in the space 115 between the inner shell 110 and the outer shell 120 to reduce heat transfer;
A plurality of extensions 1310 extending outwardly from the outer shell 120;
Reinforcement plastics 150 installed in the spaces 115 each having a height at which each of the extension parts 1310 are positioned, and contacting and supporting the inner shell 110;
A cover 1330 installed at an outer end of each of the extension parts 1310 to seal the extension part 1310; And
Supporting means (1360) for connecting the reinforcement plastics (150) and the cover (1330) to support the inner shell (110) and absorb the contraction and expansion of the inner shell (110);
Storage container of liquefied natural gas comprising a. The method according to claim 1,
The reinforced plastic 150 is made of a low temperature reinforced plastic to reduce the heat transfer while withstanding the low temperature of the liquefied natural gas delivered from the inner shell (110);
Storage container for liquefied natural gas, characterized in that. The method according to claim 1, The support means 1360,
A support rod 1350 having one end connected to the reinforcement plastic 150 and the other end positioned to have a predetermined distance d from the cover 1330; And
An elastic part 1340 having one end fixedly connected to the support rod 1350 and the other end connected to the inside of the cover 1330;
Storage container for liquefied natural gas comprising a. The method of claim 3, wherein the support means 1360,
A first elastic part support member 1341 formed at an inner side of the support rod 1350 in the direction of the inner shell 110 and having one end of the elastic part 1340 connected thereto;
A second elastic part supporting member 1342 formed in the inner side of the cover 1330 and protruding toward the inner space of the extension part 1310, and the other end of the elastic part 1340 is connected to the second elastic part supporting member 1342;
Storage container for liquefied natural gas further comprising a. The method according to claim 4, The support means 1360,
A reinforcing member 1351 formed at one end of the supporting rod 1350 connected to the reinforcing plastic 150;
Storage container for liquefied natural gas further comprising a. The method of claim 3, wherein the elastic portion 1340,
Being disc springs;
Storage container for liquefied natural gas, characterized in that. The method according to claim 1,
The outer end of the extension part 1310 and the cover 1330 are flanged by flanges 1320 formed in each;
Storage container for liquefied natural gas, characterized in that. The method according to any one of claims 1 to 7,
The inner shell 110 is a cylindrical structure;
Storage container for liquefied natural gas, characterized in that. The method according to claim 8,
The inner shell 110 forms a corrugation structure 1110;
Storage container for liquefied natural gas, characterized in that. The method according to claim 9,
The wrinkle structure 1110 is composed of one or more wrinkles (1111),
The corrugations 1111 are formed to have one or more bends 1112;
Storage container for liquefied natural gas, characterized in that. The method of claim 10,
The bend 1112 is formed to have any one or more of an angled corner bend, a rounded corner bend, and a wavy bend;
Storage container for liquefied natural gas, characterized in that. The method according to any one of claims 1 to 7,
The inner shell 110 is made of a metal that withstands the low temperature of the liquefied natural gas, the outer shell 120 is made of a steel (steel) material to withstand the internal pressure of the inner shell (110);
Storage container for liquefied natural gas, characterized in that. The method of claim 12,
The inner shell 110 withstands a temperature of -120 ~ -95 ℃, the outer shell 120 withstands a pressure of 13 ~ 25bar;
Storage container for liquefied natural gas, characterized in that. The method according to any one of claims 1 to 7,
The inner shell 110 and the outer shell 120 of the storage container such that the pressure of the space 115 between the inner shell 110 and the outer shell 120 of the storage container and the pressure inside the inner shell 110 are balanced. A connection flow path installed between the space between the inner shell and the inner shell 110;
Storage container for liquefied natural gas comprising a. In the container for storing liquefied natural gas,
Insulating layer to reduce heat transfer in the space 115 between the inner shell 110 and the outer shell 120 formed by placing the inner shell 110 on the inside of the storage container and the outer shell 120 on the outside. Install the unit 140,
The reinforcement plastic 150 for contacting and supporting the inner shell 110 is inserted into the space 115 separately from the heat insulation layer part 140, and between the reinforcement plastic 150 and the outer shell 120. Installing support means 1360 for absorbing the contraction and expansion of the inner shell 110;
Storage container for liquefied natural gas, characterized in that. The method according to claim 15,
The outer shell 120 further includes a plurality of extensions 1310 extending to the outside and a cover 1330 for sealing an outer end of each of the extensions 1310.
The reinforcement plastics 150 are respectively installed in the space 115 at the height of each of the extension portions 1310, and the support means 1360 connects the cover 1330 and the reinforcement plastics 150, respectively. To do;
Storage container for liquefied natural gas, characterized in that. The method according to claim 16, The support means 1360,
A support rod 1350 having one end connected to the reinforcement plastic 150 and the other end positioned to have a predetermined distance d from the cover 1330; And
One end is fixedly connected to the support rod 1350, the other end is an elastic portion 1340 connected to the inside of the cover 1330; includes,
The elastic portion 1340 to absorb the contraction and expansion of the inner shell (110);
Storage container for liquefied natural gas, characterized in that. The method according to any one of claims 15 to 17,
The inner shell 110 to form a corrugated structure (1110);
Storage container for liquefied natural gas, characterized in that. 19. The method of claim 18,
The wrinkle structure 1110 is composed of one or more wrinkles (1111),
The corrugations 1111 are formed to have one or more bends 1112;
Storage container for liquefied natural gas, characterized in that. The method of claim 19,
The inner shell 110 is made of a metal to withstand low temperatures of liquefied natural gas, the outer shell 120 is made of a steel (steel) material to withstand the internal pressure;
Storage container for liquefied natural gas, characterized in that. The method of claim 20,
The space between the inner shell 110 and the outer shell 120 of the storage container and the inner shell 110 so that the pressure between the inner shell 110 and the outer shell 120 and the pressure of the inner shell 110 is balanced. Connecting passages are installed between the shells 110;
Storage container for liquefied natural gas, characterized in that.

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