KR102201249B1 - Membrane panel of membrane type tank for cryogenic fluid storage - Google Patents

Abstract

The present invention relates to a membrane panel of a membrane-type tank for cryogenic fluid storage, and more specifically, by having an independent structure of corrugation forming a corrugated structure, it is required for storage of cryogenic fluid while eliminating the intersection of corrugation. The present invention relates to a membrane panel of a membrane-type tank for cryogenic fluid storage that satisfies the strength and absorption of heat shrinkage, facilitates automation, and improves productivity and quality by allowing the panel body to be assembled by lapping welding.
The membrane panel of the membrane-type tank for cryogenic fluid storage according to the present invention has a rectangular shape, and includes a panel body disposed in a plurality of horizontal and vertical directions to form a flat surface; And a corrugation formed on a portion of the panel body excluding an edge.

Description

Membrane panel of membrane type tank for cryogenic fluid storage

The present invention relates to a membrane panel of a membrane-type tank for cryogenic fluid storage, and more specifically, it is configured to improve productivity and quality by eliminating the cross section of the corrugation and enabling lapping welding of the panel body. It relates to a membrane panel of a membrane type tank for cryogenic fluid storage.

In general, Liquified Natural Gas (hereinafter referred to as'LNG') is obtained by cooling natural gas to a cryogenic temperature of -163°C, and its volume is approximately 1/600 of that of gaseous natural gas. As it is reduced to, it is suitable for long distance transportation by sea.

Ships or floating offshore structures requiring storage of such LNG, for example, LNGC (LNG Carrier), LNG RV (LNG Regasification Vessel), LNG FPSO (LNG Floating, Production, Storage and Offloading), LNG FSRU (LNG Floating Storage) and Regasification Unit) is provided with a storage tank (also called a'cargo hold') made of a structure and material to withstand cryogenic temperatures for the storage of LNG.

Among the LNG storage tanks, the membrane-type storage tank minimizes the generation of vaporized gas due to the amount of heat secreted from the outside by enclosing a sealing wall made of a metal membrane panel with insulation. In addition, the membrane metal panel is made of a metal material with strong low temperature brittleness to respond to stress changes by being in direct contact with the cryogenic LNG. It has a corrugation structure to facilitate contraction.

As a membrane panel of a conventional membrane-type tank, there is a membrane metal panel of an insulation tank for an LNG carrier of Korean Patent Publication No. 10-2005-0050170. It is formed in parallel to each other at equal intervals on the membrane metal panel, and has a plurality of transverse linear corrugations connected at both ends in a fan or semicircular shape with a flat part by a finishing part, and is orthogonal to the transverse linear corrugation, A plurality of longitudinal straight corrugations, which are formed at equal intervals in parallel with each other, and connected in a flat or semicircular shape with a flat part at both ends, and the transverse/vertical straight corrugation of the finished part and the membrane metal panel. It is composed of a flattened contact welding portion positioned between four sides and having a predetermined width, and is configured to be linearly welded by the flattened contact welding portion when overlapping a single membrane metal panel and another single membrane metal panel.

However, the membrane panel of a conventional membrane-type tank has a complex structure of a portion where the transverse linear corrugation and the longitudinal linear corrugation intersect (that is, the intersection in the form of a cross (+)). process), etc., is required, and this leads to difficulties in manufacturing, as well as taking a lot of time and cost, and causing a decrease in productivity and an increase in manufacturing cost.

The present invention is to solve the conventional problems as described above, while eliminating the intersection of the corrugation, satisfies the strength and absorption of heat contraction required for storage of cryogenic fluid, easy automation, productivity and quality It aims to improve.

According to an aspect of the present invention for achieving the above object, there is provided a membrane panel of a membrane-type tank for storing a cryogenic fluid, comprising: a panel body disposed in a plurality to form a flat surface; A corrugation formed on the panel body except for the edge; There is provided a membrane panel of a membrane-type tank for cryogenic fluid storage comprising a.

At the same time, the corrugation is not formed at the edge of the panel body, and the panel body is joined to the other panel body by lapping welding on a plane, so that the corrugation formed on the panel body is applied to the other panel body. It may not intersect with the formed corrugation.

The panel body may be rectangular.

The panel body may be made such that the long side is an integer multiple of the short side.

The length ratio of the short side and the long side of the panel body may be 1:1.

The length ratio of the short side and the long side of the panel body may be 1:3.

When a plurality of the panel bodies are arranged to form a flat surface, a long side of one panel body and a short side of another panel body may contact each other to form a continuous pattern.

According to the present invention, the corrugation forming the corrugation structure has an independent structure, thereby eliminating the intersection of the corrugation while satisfying the strength required for storage of cryogenic fluid and absorption of heat shrinkage, and assembling the panel body to each other by lapping welding. By making it easy to automate, productivity and quality can be improved.

1 is a perspective view showing a membrane panel of a membrane-type tank for storing cryogenic fluid according to a first embodiment of the present invention.
2 is a plan view showing an assembled state of a membrane panel of a membrane-type tank for storing cryogenic fluid according to the first embodiment of the present invention.
3 is a perspective view showing a membrane panel of a membrane-type tank for cryogenic fluid storage according to a second embodiment of the present invention.
4 is a plan view showing an assembly state of a membrane panel of a membrane-type tank for cryogenic fluid storage according to a second embodiment of the present invention.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples may be modified in various different forms, and the scope of the present invention is not limited to the following examples.

1 is a perspective view showing a membrane panel of a cryogenic fluid storage membrane-type tank according to a first embodiment of the present invention, and FIG. 2 is a membrane panel of a cryogenic fluid storage membrane-type tank according to a first embodiment of the present invention. It is a plan view showing the assembly state of.

1 and 2, the membrane panel 100 of the membrane-type tank for cryogenic fluid storage according to the first embodiment of the present invention is disposed in a plurality of horizontal and vertical directions when the tank is manufactured to form a plane. It includes a panel body 110 having a shape to achieve. The corrugation 120 formed on the panel body 110 is formed to avoid the edge of the panel body 110, so that the edges of the panel body 110 are all flat and all are located on the same plane. Herein, the panel body 110 will be described by taking a rectangle as an example, but if a shape is formed in a plane by being disposed in a plurality in the horizontal and vertical directions, it is not necessarily limited to a rectangle.

Meanwhile, the membrane panel 100 of a membrane-type tank for cryogenic fluid storage according to an embodiment of the present invention is a ship or floating offshore structure requiring storage of cryogenic fluid, such as LNG, and includes LNGC (LNG Carrier), LNG RV (LNG Regasification Vessel), LNG FPSO (LNG Floating, Production, Storage and Offloading), and LNG FSRU (LNG Floating Storage and Regasification Unit).

The panel body 110 is made of a rectangle as in this embodiment, but is arranged in a plurality in the horizontal direction and the vertical direction to form a flat surface, and the vertical long side 112 is an integer multiple of the horizontal short side 111, for example 2 It can have a length corresponding to a boat. In addition, the panel body 110 may form a sealing wall of a membrane-type tank by lapping welding with another panel body 110.

The panel body 110 is arranged in plural and connected to each other by welding to form a sealing wall that directly contacts a cryogenic fluid such as LNG. In general, membrane-type storage tanks have primary and secondary sealing walls that prevent LNG from leaking, and primary and secondary insulation walls that prevent LNG from vaporizing by blocking heat transfer, and the interior of the bottom or inner wall constituting the hull. It is manufactured by being laminated and installed on the surface, and a plurality of the panel body 110 according to the present embodiment may be bonded to each other to form a primary sealing wall (ie, the membrane panel 100) in direct contact with the LNG. Although not shown in the drawing, under the panel body 110 forming the primary sealing wall, a primary insulating material forming a primary insulating wall, a secondary panel forming a secondary sealing wall, and a secondary insulating wall are The secondary insulating material to be formed may be sequentially stacked to be used in a single unit modular state.

The panel body 110 may be made of, for example, stainless steel so as to respond to stress changes caused by direct contact with LNG, which is a cryogenic fluid, and in addition, such as aluminum alloy or nickel alloy steel including Invar, It may be made of a metal material that is strong in low temperature brittleness, and the corrugation 120 is formed to satisfy a certain strength, and at the same time, it facilitates expansion and contraction in response to repeated temperature changes and load changes of the storage liquid.

As an example, as in the present embodiment, the panel body 110 has a horizontal: vertical length ratio, that is, a length ratio of the short side 111: the long side 112 is 1:2, and as shown in FIG. The plane can be achieved by a phosphorus arrangement.

The corrugation 120 is formed on a portion of the panel body 110 except for an edge, so as not to cause interference with other corrugations 120 during lapping welding between the panel bodies 110. In addition, the corrugation 120 may be formed to protrude from the panel body 110 by a forming process of the panel body 110, and the cross-section may be a semicircle or arc, or a similar shape, or ∩ It can be formed in a ruler or ∧ shape.

Corrugation 120 may be formed to form a straight line along the longitudinal direction of the panel body 110 as in the present embodiment. In addition, the corrugation 120 may be formed so that a plurality of corrugations 120 are parallel to the panel body 110. On the other hand, the corrugation 120 may be formed along the horizontal direction on the panel body 110 and may be formed to have a shape other than a straight line, but as in this embodiment, the long side 112 corresponding to the panel body 110 By being formed in the direction, not only is it advantageous to increase the length, but also enables stable expansion and contraction of the panel body 110. In particular, as the panel body 110 is arranged in the horizontal and vertical directions, the corrugation 120 is also arranged in the horizontal and vertical directions, thereby facilitating heat contraction in both the horizontal and vertical directions.

According to the present invention, the panel body 110 may form a plane constituting the primary sealing wall with only a single type having the same standard and the formation structure of the corrugation 120.

FIG. 2 shows a state in which the membrane panel 100 according to the first embodiment of the present invention is arranged in a pattern to form a primary sealing wall. As shown in FIG. 2, two membrane panels 100 may come into contact with each other to form an approximately L-shaped continuous pattern 131 and 132. In order to form an L-shaped pattern, it is preferable that the short side of one membrane panel 100 and the long side of another membrane panel 100 contact each other.

Among the L-shaped patterns, the member number 131 is assigned, as seen in FIG. 2, when the short side of the other membrane panel 100 located on the right abuts against the long side of one membrane panel 100 located on the left. It shows an example of forming. In addition, among the L-shaped patterns, the member number 132 is assigned, as shown in FIG. 2, with respect to the short side of one membrane panel 100 located on the left, the long side of the other membrane panel 100 located on the right is correct. An example of touching and forming a pattern is shown.

3 is a perspective view showing a membrane panel of a cryogenic fluid storage membrane-type tank according to a second embodiment of the present invention, and FIG. 4 is a membrane panel of a cryogenic fluid storage membrane-type tank according to a second embodiment of the present invention. It is a plan view showing the assembly state of.

3 and 4, the membrane panel 200 of the cryogenic fluid storage membrane-type tank according to the second embodiment of the present invention is formed in a rectangular shape and is arranged in a plurality of horizontal and vertical directions. The panel body 210 and the corrugation 220 formed in portions other than the edge of the panel body 210 may be included, and the panel body 210 and the corrugation 220 are the previous embodiment. Since it has been described in detail in the above, a description will be made mainly on differences from the membrane panel 100 of the membrane-type tank for cryogenic fluid storage according to the first embodiment of the present invention.

In this embodiment, the panel body 210 has a width: length ratio, that is, a length ratio of the short side 211: the long side 212 is 1: 3, and thus, for example, a pair of the panel body 210 In the state of being L-shaped, it is possible to form the above-described plane, that is, a continuous primary sealing wall by their repetitive arrangement.

According to the present invention, the panel body 210 may form a plane constituting the primary sealing wall with only a single type having the same standard and the formation structure of the corrugation 220.

FIG. 4 shows a state in which the membrane panel 200 according to the second embodiment of the present invention is arranged in a pattern to form a primary sealing wall. As shown in FIG. 4, two membrane panels 200 may come into contact with each other to form an approximately L-shaped continuous pattern 231 and 232. In order to form an L-shaped pattern, it is preferable that the short side of one membrane panel 200 and the long side of another membrane panel 200 contact each other.

Among the L-shaped patterns, the member number 231 is assigned, as seen in FIG. 4, when the short side of the other membrane panel 200 located on the right abuts against the long side of one membrane panel 200 located on the left side. It shows an example of forming. In addition, among the L-shaped patterns, the member number 232 is assigned, as shown in FIG. 4, with respect to the short side of one membrane panel 200 located on the left, the long side of the other membrane panel 200 located on the right is correct. An example of touching and forming a pattern is shown.

The operation of the membrane panel of the membrane-type tank for cryogenic fluid storage according to the present invention will be described.

In a membrane-type storage tank for storing LNG, which is a cryogenic fluid, corrugations 120 and 220 are formed to each have an independent structure on the membrane panels 100 and 200 serving as primary sealing walls in direct contact with LNG. That is, each of the corrugations 120 and 220 is not connected to the corrugations 120 and 220 formed on another adjacent membrane panel 100 and 200.

Furthermore, since the panel bodies 110 and 210 are arranged in the horizontal and vertical directions, the corrugations 120 and 220 are also arranged in the horizontal and vertical directions along with them. Accordingly, the strength required for storage of the cryogenic fluid and the deformation during thermal contraction and thermal expansion are satisfied while eliminating the intersection of the corrugation.

In addition, since the panel bodies 110 and 210 can be assembled with each other by lapping welding, all welding can be performed on a flat surface, minimizing the time and effort required for the welding process, and facilitating automation, thereby increasing productivity. Not only can it improve, but it can also increase its quality.

On the other hand, from the top, the panel body 110, 210 is made in a rectangular shape, but the vertical long sides 112 and 212 of the panel body are an integer multiple of the horizontal short sides 111 and 211, for example, 2 times (first embodiment ) Or 3 times (second embodiment), but the long side does not necessarily need to be an integer multiple of the short side, and according to the present invention, the long side is made so that the long side does not become an integer multiple of the short side if necessary. You can lose.

It is apparent to those of ordinary skill in the art that the present invention is not limited to the above embodiments and can be implemented with various modifications or variations within the scope of the technical gist of the present invention. I did it.

110, 210: panel body 111, 211: short side
112, 212: long side 120, 220: corrugation

Claims (7)

In the membrane panel of a membrane-type tank storing cryogenic fluid,
A panel body disposed in a plurality of horizontal and vertical directions in the tank to form a flat surface, the long side being provided in a rectangular shape having an integer multiple of the short side; And
It is formed on a portion of the panel body excluding the edge, and includes a corrugation formed to extend only in one direction along the long side of the panel body,
When a plurality of the panel bodies are arranged to form a flat surface, a pattern forming an L-shaped structure is repeatedly arranged by a short side of the other panel body contacting the long side of one panel body to form a sealing wall. A membrane panel of a membrane-type tank for cryogenic fluid storage in which the long side of another adjacent panel body and the short side of another adjacent panel body contact each other on the long side. The method according to claim 1,
At the same time, the corrugation is not formed at the edge of the panel body, and the panel body is joined to the other panel body by lapping welding on a plane, so that the corrugation formed on the panel body is applied to the other panel body. Membrane panels of membrane type tanks for cryogenic fluid storage that do not intersect with the formed corrugation. The method according to claim 1,
A membrane panel of a membrane-type tank for storing cryogenic fluid, wherein the corrugation is provided in plural for each of the panel bodies and arranged side by side. delete The method according to claim 1,
A membrane panel of a membrane-type tank for storing cryogenic fluid in which the length ratio of the short side and the long side of the panel body is 1:2. The method according to claim 1,
A membrane panel of a membrane-type tank for storing cryogenic fluid in which the length ratio of the short side and the long side of the panel body is 1:3. delete

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