阅读说明：本技术 膜状物接合结构及包括膜状物接合结构的液化气体存储槽 (Membrane bonded structure and liquefied gas storage tank including the same ) 是由 朴光俊 许行成 黄范锡 姜重圭 于 2018-12-27 设计创作，主要内容包括：公开了在用于存储液化气体的存储槽的第一面与第二面之间对用于形成密封壁的膜状物进行接合的膜状物接合结构。膜状物接合结构可包括平面部板(20)、接合用板(30)、第一膜状物(42)和第二膜状物(44),其中,平面部板(20)设置在第一面和第二面上以对存储槽进行隔热,接合用板(30)与平面部板一同设置在第一面与第二面的边界部处,第一膜状物(42)附接到第一面的平面部板和接合用板上以对存储槽进行密封,并且第二膜状物(44)附接到第二面的平面部板和接合用板上以对存储槽进行密封。此处,第一膜状物和第二膜状物可附接到接合用板上,而不直接连接。(A film joining structure for joining a film for forming a sealing wall between a first face and a second face of a storage tank for storing liquefied gas is disclosed. The film joining structure may include a planar panel (20), a joining panel (30), a first film (42), and a second film (44), wherein the planar panel (20) is disposed on the first and second faces to insulate the storing bath, the joining panel (30) is disposed together with the planar panel at a boundary portion of the first and second faces, the first film (42) is attached to the planar panel of the first face and the joining panel to seal the storing bath, and the second film (44) is attached to the planar panel of the second face and the joining panel to seal the storing bath. Here, the first membrane and the second membrane may be attached to the joining plate without being directly connected.)

1. A membrane engaging structure for engaging a membrane for forming a sealing wall between a first face and a second face of a storage tank for storing liquefied gas, the membrane engaging structure comprising:

a planar sheet disposed on the first and second faces to insulate the reservoir;

a joining plate provided at a boundary portion of the first surface and the second surface together with the planar plate;

a first film attached to the planar plate of the first face and the joining plate to seal the storage tank; and

a second film attached to the planar plate of the second face and the joining plate to seal the storing bath,

wherein the first membrane and the second membrane are attached to the joining plate without being directly connected.

2. The membrane-joining structure according to claim 1, wherein one side surface of the joining plate is finished with a metal material so that the first membrane and the second membrane can be joined by welding.

3. The membrane-joining structure according to claim 1, wherein the joining plate includes:

a pair of plywood sheets;

a heat insulator sandwiched between the pair of plywood panels;

a thermal protector laminatedly disposed on one of the pair of plywood panels; and

an invar sheet provided on the thermal protector in a stacked manner.

4. The membrane-joining structure according to claim 3, wherein the pair of plywood plates are attached to both side surfaces of the thermal insulator by adhesives, respectively, the thermal protector is fixed to the one plywood plate by staples, and the invar sheet is fixed by fastening screws penetrating the thermal protector and combined with the one plywood plate.

5. The membrane-joining structure according to claim 1, wherein the joining plate is provided in place of the planar plate or after partially cutting off the planar plate to insulate the storage tank.

6. The membrane joining structure according to claim 1, wherein the first face is a front face or a rear face of the storing bath, and the second face is an inclined face of the storing bath.

7. The membrane-joining structure according to claim 6, wherein a chamfered portion is formed between the front surface and the inclined surface or between the rear surface and the inclined surface, and the joining plate is provided in plurality in a line at the chamfered portion.

8. The membrane bonding structure according to claim 1, wherein the first membrane and the second membrane have a plurality of wrinkles to form a primary sealing layer of the storage tank, directly contact the liquefied gas of very low temperature, and absorb thermal stress that may occur when shrinking and expanding due to the liquefied gas of very low temperature.

9. The membrane-engaging structure of claim 1, further comprising:

a connection film disposed at a portion where the two joining plates are adjacent to each other and having a wrinkle portion.

10. The membrane-joining structure according to claim 9, wherein the connecting membrane is joined to a portion where the two joining plates are adjacent to each other, so that the first membrane and the second membrane are connected to each other.

11. A storage tank having a polyhedral shape and storing liquefied gas, the storage tank comprising:

the heat insulation layer is arranged on the inner wall of the ship body;

a primary seal layer disposed on the thermal insulation layer and in direct contact with the liquefied gas; and

a film joining structure joining the film for forming the primary sealing layer between the first face and the second face of the storing bath,

wherein the membrane engagement structure comprises:

a planar plate disposed on the first face and the second face to form a thermal insulation layer of the storage tank;

a joining plate provided at a boundary portion of the first surface and the second surface together with the planar plate;

a first film attached to the planar panel of the first face and the joining panel to form a primary seal layer of the storage tank; and

a second film attached to the planar plate of the second face and the joining plate to seal the storing bath,

wherein the first membrane and the second membrane are attached to the joining plate without being directly connected.

Technical Field

The present invention relates to a bonding structure of a film provided in a film type storage tank to form a primary sealing wall, and more particularly, to a film bonding structure of a portion where an inclined surface of the storage tank is connected with a front surface and a rear surface, and a liquefied gas storage tank including the same.

Background

As the interest in environmental utilities has become increasingly greater worldwide, there is an increasing demand for clean fuels that can replace existing energy sources such as oil, coal, etc. Under such circumstances, natural gas is used in various fields as a main energy source having cleanliness, stability and convenience.

Unlike the U.S. or europe, which directly receives Natural Gas through a pipeline, Liquefied Natural Gas (LNG), which is Liquefied at ultra-low temperature, is transported by an LNG carrier and supplied to consumers in korea. Therefore, as the demand for natural gas in korea increases, the demand for LNG carriers for storing and transporting liquefied natural gas also increases.

Natural gas (natural gas) has recently been attracting attention as a low-pollution energy source in various technical fields as a fossil fuel containing methane (methane) as a main component and a small amount of ethane (ethane), propane (propane), and the like.

Natural gas is transported in a gaseous state through a gas pipeline on land or at sea, or transported to a remote consumption site in the case where it is stored in an LNG storage tank of an LNG carrier in a Liquefied Natural Gas (LNG) state. Liquefied natural gas is obtained by cooling natural gas to very low temperatures (approximately below-163 ℃), and is very suitable for transport over long distances by sea, with a volume reduced to about 1/600 compared to when natural gas is in the gaseous state.

The lng carrier is provided with a storage tank (also referred to as a cargo tank) capable of storing and storing lng that cools and liquefies natural gas. The boiling point of lng is about-162 deg.c at atmospheric pressure, and thus in order to safely store and store lng, the storage tank for lng may be made of an ultra-low temperature resistant material such as aluminum steel, stainless steel, 35% nickel steel, etc., and is designed in a structure that is strong against thermal stress and thermal shrinkage and can prevent heat intrusion.

Not only LNG carriers for loading LNG and operating on the sea and unloading LNG at a desired location on the land and Regasification vessels (LNG RV) for regasifying and unloading stored LNG in a natural gas state after loading LNG and operating on the sea and arriving at the desired location on the land, but also Floating offshore structures such as LNGFPSO (Floating, Production, Storage and Offloading) or LNG FSRU (Floating, Storage, and Regasification Unit) have recently been provided with LNG Storage tanks provided on the LNG carriers or the LNG RV.

The LNG FPSO is stored in a storage tank for directly liquefying the generated natural gas at sea, and is a floating offshore structure used to move the LNG stored in the storage tank to an LNG carrier when necessary. In addition, the LNGFSRU is a floating offshore structure that vaporizes LNG as needed to be supplied to a desired location on land after LNG unloaded from an LNG carrier is stored in a storage tank at sea remote from land.

As described above, a storage tank for storing LNG in a very low temperature state is provided in a ship such as an LNG carrier that transports or stores liquid cargo such as LNG on the sea or an offshore structure such as an LNGRV, an LNG FPSO, and an LNG FSRU.

Such storage tanks can be classified into an Independent Type (Independent Type) and a Membrane Type (Membrane Type) according to whether a load by liquid cargo is directly applied to the heat insulator.

A general membrane-type LNG storage tank includes a secondary heat insulating layer provided on an inner wall of a hull, a secondary sealing layer provided on the secondary heat insulating layer, a primary heat insulating layer provided on the secondary sealing layer, and a primary sealing layer provided on the primary heat insulating layer.

The heat insulating layer prevents external heat from intruding into the inside of the cargo tank so that the liquefied natural gas is not heated, and the seal layers serve to prevent the liquefied natural gas from leaking to the outside of the storage tank, wherein the sealing structure of the cargo tank is configured to be double so that even if one seal layer is damaged, the other seal layers can block the leakage of the liquefied natural gas.

To provide the heat insulating layer and the sealing layer of the liquefied natural gas storage tank, it is manufactured by a process of first bonding a plurality of secondary heat insulating panels to the inner wall of the hull, disposing a secondary sealing wall to the plurality of secondary heat insulating panels, disposing a primary heat insulating panel to the secondary sealing wall, and finally disposing the primary sealing wall to the primary heat insulating panel.

However, liquefied gas of LNG or the like is stored in a liquid state in the storage tank, and a ship or a floating offshore structure is used at sea where flow occurs, and therefore sloshing load generated during the flow of the stored liquefied gas is inevitably caused on the wall surface of the storage tank.

In general, in order to cope with a sloshing load, the overall shape of the membrane-type LNG storage tank is designed in an octagonal prism shape. This is to design each corner of the inner hull for forming the storing bath to be an obtuse angle to disperse stress concentration. Further, the primary seal wall has a membrane (corrugated membrane) structure including a corrugated portion to be able to cope with extremely low thermal contraction in all regions of the cargo compartment.

In the storage tank of the octagonal prism shape, there are inclined surfaces between the upper surface and both side surfaces and between the lower surface and both side surfaces, and thus there is a disadvantage that it is difficult to uniformly connect the film having the wrinkled portion in all regions.

To overcome this drawback, as shown in FIG. 1, the existing film type liquefied gas storage tank will have 2 of the interval between the folds in the front and rear faces^1/2The membrane forming the bellows portion at the enlarged intervals is arranged on the inclined surface so as to connect the inclined surface and the front (or rear) membrane.

For example, fold lines (L1, L2) formed on the rear face (12) and the upper right-side inclined face (18) of the liquefied gas storage tank (10) are shown in fig. 1. When the interval between the fold lines (L1) of the rear face (12) is (a), the interval between the fold lines (L2) of the upper right inclined face (18) has a x 2^1/2The value of (c).

However, this structure causes a reduction in the structural performance of the membrane, i.e., the primary seal wall.

Disclosure of Invention

Technical problem

The present invention has been made to solve the conventional problems as described above, and an object thereof is to provide a film joining structure provided with a joining plate that can attach a film to a portion between an inclined surface connecting a storage tank and a front surface and between the inclined surface connecting the storage tank and a rear surface when a primary sealing wall is formed using a plurality of films, thereby being capable of maintaining a wrinkle part interval in the inclined surface to be the same as a wrinkle part interval in the front surface and the rear surface.

Means for solving the problems

According to an aspect of the invention for achieving the above object, there can be provided a film-joining structure involving a film-joining structure that joins a film for forming a sealing wall between a first face and a second face of a storage tank for storing liquefied gas, which includes a planar plate provided on the first face and the second face to insulate the storing bath, a joining plate provided together with the planar plate at a boundary portion of the first face and the second face, a first film attached to the planar plate of the first face and the joining plate to seal the storing bath, and a second film is attached to the planar plate of the second face and the joining plate to seal the storing bath.

In an embodiment, one side surface of the joining plate may be finished with a metal material so that the first membrane and the second membrane can be joined by welding.

In an embodiment, the splice plate may include a pair of plywood panels, a thermal insulator interposed between the pair of plywood panels, a thermal protector laminatedly disposed on one of the pair of plywood panels, and a invar sheet laminatedly disposed on the thermal protector.

In an embodiment, the pair of plywood panels may be attached to both side surfaces of the thermal insulation member by adhesives, the thermal protector may be fixed to the one plywood panel by staples, and the invar sheet may be fixed by fastening screws penetrating the thermal protector and combined with the one plywood panel.

In an embodiment, the joining plate may be provided instead of the planar plate or may be provided after partially cutting out the planar plate to insulate the storing bath.

In one embodiment, the first face may be a front or rear face of the reservoir, and the second face may be an inclined face of the reservoir.

In one embodiment, a chamfered portion may be formed between the front surface and the inclined surface or between the rear surface and the inclined surface, and the joining plate may be arranged in a plurality of rows at the chamfered portion.

In an embodiment, the first and second films may have a plurality of wrinkles to form a primary sealing layer of the storage tank, directly contact the liquefied gas of the very low temperature, and absorb thermal stress that may occur when the contraction and expansion due to the liquefied gas of the very low temperature.

In an embodiment, the membrane joining structure may further include a connection membrane disposed at a portion where the two joining plates are adjacent to each other and having a wrinkle portion.

In an embodiment, the connection film may be joined to a portion where the two joining plates are adjacent to each other, so that the first film and the second film are connected to each other.

According to another aspect of the present invention, there may be provided a storage tank which relates to a storage tank having a polyhedral shape and storing a liquefied gas, comprising a heat insulating layer provided on an inner wall of a hull, a primary seal layer provided on the heat insulating layer and in direct contact with the liquefied gas, and a film-joining structure joining a film for forming the primary seal layer between a first face and a second face of the storage tank, wherein the film-joining structure comprises a planar plate provided on the first face and the second face to form the heat insulating layer of the storage tank, a joining plate provided at a boundary portion of the first face and the second face together with the planar plate, a first film attached to the planar plate of the first face and the joining plate to form a primary seal layer of the storage tank, a second film joining structure provided on the planar plate of the first face and the joining plate to form the primary seal layer of the storage tank, And a second film attached to the planar plate of the second face and the joining plate to seal the storing bath, wherein the first film and the second film are attached to the joining plate without being directly connected.

Effects of the invention

According to the present invention, a film joining structure provided with a joining plate that can attach a film at portions between an inclined surface and a front surface of a connection storage tank and between the inclined surface and a rear surface of the connection storage tank when a primary sealing wall is formed using a plurality of films can be provided.

Thus, according to the membrane joining structure of the present invention, the interval of the wrinkle parts in the inclined surface of the storing bath can be maintained to be the same as the interval of the wrinkle parts in the front and rear surfaces.

In the existing storing bath, the interval is widened 2 compared with the film used in the plane when the flat such as the front and rear is connected with the inclined plane and the film used in the flat is provided with the corrugation part (corrugation) connection^1/2Double folds and thus a reduction in the structural performance of the cargo hold. In addition, it is also necessary to provide 2 to be used in the inclined surface^1/2The thermal and structural properties of the fold were evaluated. Further, in the manufacture of the storing bath, the wrinkle part interval requires other film-like materials in terms of construction management, so that the product kit is increased to cause negative effects, and also in terms of cost, because a mold of a new interval needs to be manufactured, so that the manufacturing cost is increased. However, when the film-bonding structure proposed in the present invention is used, there is an advantage that the performance of the reservoir can be improved without the above-described drawbacks.

Drawings

Fig. 1 is a perspective view of a liquefied gas storage tank having a general form of an inclined surface for coping with a sloshing load.

Fig. 2 is a view showing a part of a corner side connected to an inclined surface in the front or rear surface of a liquefied gas storage tank according to an embodiment of the present invention, which is a view showing a state in which a primary insulation plate is arranged.

FIG. 3 is a view showing a part of a corner side connected to an inclined surface in the front or rear surface of a liquefied gas storage tank according to an embodiment of the present invention, which is a view of a state where a joint plate is arranged to a primary heat insulating plate.

FIG. 4 is a view showing a part of a corner side connected to an inclined surface in the front or rear surface of a liquefied gas storage tank according to an embodiment of the present invention, which is a view of a state where a film forming a primary sealing wall is partially arranged on a primary insulating plate and a joint plate.

Fig. 5a is a perspective view of the joining plate to which the membrane is attachable.

Fig. 5b is a cross-sectional view of the joining plate of the attachable membrane.

Fig. 6 is a partially enlarged view for explaining an arrangement relationship between a joining plate and a film-like substance which is arranged at an upper portion of the joining plate in a stacked manner.

Detailed Description

Hereinafter, the configuration and operation according to the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments may be modified into various other forms, and the scope of the present invention is not limited to the following embodiments.

The liquefied gas storage tank can be used to store liquid cargo comprising, inter alia, hydrocarbon components such as LNG, LPG, etc. that are liquefied at extremely low temperatures. Further, the liquefied gas storage tank may be a film-type tank having a sealing and heat insulating barrier so as to be able to store very low temperature liquid cargo such as LNG. The sealing and heat insulating barrier prevents leakage of the liquefied gas contained in the interior of the storage tank, and is disposed in layers on all of the wall surfaces of the storage tank in all directions, i.e., the front wall, the rear wall, the left wall, the right wall, the top wall, and the lower wall, to block heat transfer from the outside.

The sealing and heat insulating barrier of the film-type LNG storage tank for storing LNG includes a secondary heat insulating layer provided on an inner wall of a hull, a secondary sealing layer provided on the secondary heat insulating layer, a primary heat insulating layer provided on the secondary sealing layer, and a primary sealing layer provided on the primary heat insulating layer.

The heat insulating layer prevents external heat from intruding into the inside of the cargo tank so that the liquefied natural gas is not heated, and the seal layers serve to prevent the liquefied natural gas from leaking to the outside of the storage tank, wherein the sealing structure of the cargo tank is configured to be double so that even if one seal layer is damaged, the other seal layers can block the leakage of the liquefied natural gas.

The sealing and heat insulating barrier of such a liquefied natural gas storage tank is manufactured by a process of forming a secondary heat insulating layer by first bonding a plurality of secondary heat insulating panels to the inner wall of a hull, forming a secondary sealing layer by disposing a secondary sealing wall onto the secondary heat insulating layer formed of the secondary heat insulating panels, forming a primary heat insulating layer by disposing a primary heat insulating panel onto the secondary sealing layer formed of the secondary sealing wall, and finally forming a primary sealing layer by disposing a primary sealing wall (for example, a film made of a material of SUS or the like) onto the primary heat insulating layer formed of the primary heat insulating panels.

A liquefied gas storage tank in which a primary seal layer is formed of a membrane according to an embodiment of the present invention may be provided inside a hull of a marine structure. In the present specification, the term "marine structure" refers to a concept of a platform including various liquefied gas carriers such as LNG carriers, LNG RVs (LNG Regasification vessels), and the like, and also including LNGFPSOs (LNG Floating, Production, Storage and Off-loading), LNG FSRUs (LNG Floating and Regasification Unit), LNG FRUs (LNG Floating and Regasification Unit), bmpp (heavy Mounted Power plant), fspp Floating and raw Power plant, and the like.

FIGS. 2 to 4 are views showing a part of a corner side connected to an inclined surface in the front or rear surface of a liquefied gas storage tank according to an embodiment of the present invention in the order of construction at the time of manufacture of the storage tank. Fig. 2 shows a state where the primary insulation panels are arranged, fig. 3 shows a state where the joint plates are arranged, and fig. 4 shows a state where the film forming the primary sealing wall is partially arranged on the primary insulation panels and the joint plates.

As shown in fig. 2 to 4, a membrane-joining structure according to an embodiment of the present invention includes a planar plate (20), a joining plate (30) and membranes (42, 44), wherein the planar plate (20) is disposed on a tank inner wall to form a liquefied gas storage tank, the joining plate (30) is disposed at a chamfered portion of a front and a rear of the liquefied gas storage tank together with the planar plate (20), and the membranes (42, 44) are attached to the joining plate (30).

The planar plate (20) is used to form a primary insulating layer as a part of a primary insulating plate manufactured to be provided to a flat portion in the front and rear faces of the liquefied gas storage tank. In this specification, the planar plate (20) is described as a primary insulating plate for forming a primary insulating layer. However, according to a variant of the invention, the planar panel (20) may be a panel module in which the secondary insulating panel, the secondary sealing wall and the primary insulating panel are integrated.

For example, one planar plate (20) may be a rectangular plate having a rectangular parallelepiped shape with a certain thickness. In the front and rear faces of the liquefied gas storage tank, the flat plate (20) provided at the chamfered portion (11a) may have a form in which one side is obliquely cut in accordance with the shape of the chamfered portion (11 a).

For example, only a part of the front surface of the liquefied gas storage tank is shown in fig. 2 to 4, and only one slope part (11a) formed between the front surface and the right slope surface is shown. However, the front (or rear) of the liquefied gas storage tank is connected by a total of four inclined surfaces (upper left inclined surface, upper right inclined surface, lower left inclined surface, and lower right inclined surface) and the chamfered portions, and the membrane joining structure according to the present invention can be equally applied to all the chamfered portions.

Furthermore, a metal strip (22) may be mounted on a surface of the planar panel (20) such that the primary sealing wall, i.e. the membrane (42, 44), for forming the primary sealing layer may be attached to the planar panel (20) by welding.

The structure, manufacturing method, construction method, and the like of the planar plate (20) do not limit the present invention, and therefore, further detailed description will be made.

As shown in FIG. 3, a joint plate (30) may be disposed at the beveled portion in the front and rear faces of the liquefied gas storage tank. The engaging plate (30) may be arranged in plural in a row along the oblique side portion.

A perspective view and a cross-sectional view of the joining plate (30) to which the membranes (42, 44) can be attached are shown in fig. 5a and 5 b.

As shown in fig. 3, fig. 5a and fig. 5b, the joint plate (30) as a part of the primary heat insulating plate made for being disposed at the flat portion in the front and rear of the liquefied gas storing tank can be used to form the primary heat insulating layer. In this specification, it is described that the joint plate (30) is included on a primary heat insulating plate for forming a primary heat insulating layer. However, according to a modification of the present invention, the joint plate (30) may be a plate module in which the secondary insulation plate, the secondary sealing wall, and the primary insulation plate are integrated.

Referring to fig. 5a, for example, one bonding plate (30) may be a rectangular flat plate having a rectangular parallelepiped shape with a certain thickness. In the front and rear faces of the liquefied gas storage tank, the joint plates (30) provided at both side end corner portions of the beveled portion (11a) may have a form other than a square according to the shape of the corner.

Referring to fig. 5b, each of the joint plates (30) includes a heat insulator (32) interposed between a pair of plywood plates (plywood) (31, 33), and one plywood plate (33) is sequentially laminated with a heat protector (34) and an invar sheet (35).

For example, as the heat insulator (32), polyurethane foam (PUF), reinforced polyurethane foam (RPUF), or the like can be used. A pair of plywood plates (31, 33) may be attached to both side surfaces of the thermal insulation member (32) by adhesives (e.g., pu-glue), respectively. The thermal protector (34) may be fixed to the plywood (33) by staples (staples). The invar sheet (35) can be fixed by a fastening screw which penetrates the thermal protection piece (34) and is combined with the plywood (33).

The joint plate (30) may be provided on the secondary heat insulating plate (not shown) and the secondary sealing wall (not shown) instead of the planar plate, and may also be provided after partially cutting off the planar plate provided on the secondary heat insulating plate (not shown) and the secondary sealing wall (not shown).

As shown in fig. 4, the films (42, 44) are joined to the primary heat insulating plate, i.e., the planar portion plate (20) and the joining plate (30), by welding. The membrane (42, 44) forms a primary seal layer and is in direct contact with the cryogenic liquefied gas. The membrane (42, 44) has a plurality of wrinkles (42a, 44a) to absorb thermal stress that may occur when the membrane contracts and expands due to the very low temperature LNG.

Fig. 4 shows a state in which the films (42, 44) are attached to the joining plate (30), and shows a state in which the films (42, 44) are not yet laminated at a part of the planar plate (20).

According to an embodiment of the present invention, the film disposed on the front and rear surfaces (hereinafter, referred to as a first film (42)) and the film disposed on the inclined surface (hereinafter, referred to as a second film (44)) may be individually joined to the joining plate (30) disposed at the inclined edge portion (11a), respectively. Thus, according to an embodiment of the invention, the first membrane (42) and the second membrane (44) are not directly connected to each other. Further, unlike the conventional art, the interval of the wrinkle parts (42a) formed on the first film (42) and the interval of the wrinkle parts (44a) formed on the second film (44) do not affect each other, and the intervals of the wrinkle parts (42a, 44a) may be formed to be the same for all the films (42, 44).

According to the present invention, the first film (42) and the second film (44) may have the same shape, and may include wrinkle parts (42a, 44a) formed in the same pattern.

Although shown in fig. 4 as if the first membrane (42) and the second membrane (44) were arranged on the same plane, this is for convenience of illustration and description only.

Fig. 6 is a partial method diagram for explaining the arrangement relationship between the joining plate (30) and the film-like materials (42, 44) arranged in a stacked manner on the upper portion of the joining plate (30).

As described above, the first film (42) and the second film (44) are not directly connected and are independently joined to the joining plate (30), respectively. Further, the wrinkle part (42a) formed on the first film (42) and the wrinkle part (44a) formed on the second film (44) are not directly connected.

However, a connecting membrane (46) is disposed at a portion where the two joining plates (30) are adjacent to each other. The connection membrane (46) may include a wrinkle part (46a), and the wrinkle part (46a) of the connection membrane (46) may connect the wrinkle part (42a) of the first membrane (42) and the wrinkle part (44a) of the second membrane (44) to each other.

The joining plate (30) is provided in a portion where the two joining plates (30) are adjacent to each other so as to connect the first film-like substance (42) and the second film-like substance (44), so that the first film-like substance (42) and the second film-like substance (44) can cope with thermal deformation movement of the joining plate (30) that contracts and expands due to an extremely low temperature of the liquefied gas.

In other words, since the joining plates (30) move toward the respective thermal deformation center points when contracting, the two joining plates (30) exert forces contracting in opposite directions to each other in adjacent portions. At this time, the respective films (42, 44) welded to the joining plate (30) move in accordance with the movement of the joining plate (30), and thereby stress concentration is induced. According to the present invention, stress concentration can be dispersed by the connecting membrane (46) having the wrinkle portion (46 a).

As shown in fig. 6, the wrinkle portion (46a) formed on one connection membrane (46) may be engaged such that one wrinkle portion (42a) on one first membrane (42) to which the connection membrane (46) is joined and one wrinkle portion (44a) on one second membrane (44) to which the connection membrane (46) is joined are connected to each other. Further, in order to facilitate understanding, the first film (42) and the second film (44) are illustrated in a translucent state in fig. 6 to show that the position of the bonding plate (30) can be confirmed.

Further, according to the present invention, since the first film (42) and the second film (44) can be individually joined to the joining plate (30) provided at the chamfered portions on the front and rear surfaces, respectively, it is possible to compensate for an error caused by a manufacturing tolerance of the hull (hull) at the time of the film construction of the liquefied gas storage tank.

Although the embodiments of the present invention have been described above with reference to the exemplary drawings, the present invention is not limited by the embodiments and drawings described above, and those skilled in the art to which the present invention pertains can implement various modifications and variations within the scope of the claims.