KR20210022222A - Insulation panel system for liquefied cargo containment tank - Google Patents

Abstract

According to one embodiment of the present invention, an insulation panel system for a liquefied cargo storage tank comprises: a primary blocking module (100) blocking liquefied natural gas and having a primary insulation layer (120); a secondary blocking module (200) positioned in a lower portion of the primary blocking module (100) and having a secondary membrane (210) and a secondary insulation layer (220); and a plurality of fixing modules (300) fixating the primary blocking module (100) and the secondary blocking module (200) to each other. The fixing module (300) comprises: a first base socket (310) fixated to the secondary insulation layer (200); a stud (320) coupled to the first base socket (310); a buffer member (325) covering an upper surface of the first base socket (310); and a second base socket (330) covering the buffer member (325) and the first base socket (310). The second base socket (330) can be welded and coupled to the secondary membrane (210).

Description

Insulation panel system for liquefied cargo storage tank {INSULATION PANEL SYSTEM FOR LIQUEFIED CARGO CONTAINMENT TANK}

The present invention relates to an insulation panel system for a liquefied cargo storage tank, and more particularly, to an insulation panel system for a liquefied cargo storage tank including a fixing module for fixing a primary blocking module and a secondary blocking module.

In general, Liquefied Natural Gas (LNG) refers to a colorless and transparent cryogenic liquid in which natural gas containing methane as its main component is cooled to -163°C and its volume is reduced to one-600th.

As such liquefied natural gas is used as an energy resource, a liquefied cargo carrier capable of transporting liquefied cargo consisting of a large amount of liquefied natural gas by sea has been developed. Such a liquefied cargo carrier is provided with a liquefied cargo storage tank capable of storing and storing liquefied natural gas liquefied in a cryogenic state.

These liquefied cargo storage tanks are classified into an independent tank type and a membrane type according to their type.

Of these, the membrane type is to make a storage tank for liquefied cargo by installing heat radiation material directly on the hull, and it is cheaper than the independent tank type and it is easy to change the design.

This membrane type has a dual blocking module structure of a secondary blocking module and a primary blocking module installed on the inner wall of the liquefied cargo storage tank. Each barrier module has a dual structure of an insulating layer made of polyurethane foam (PUF) and plywood, and a membrane made of thin metal. In particular, the second blocking module includes a second insulating layer and a second membrane, and the second insulating layer may include a second insulating member made of polyurethane foam and a second upper protective plate made of plywood.

A securing module is used to fix the first blocking module and the second blocking module to each other. In general, the fixing module includes a base socket fixed to the secondary blocking module and a stud connected to the primary blocking module. Here, the base socket is disposed adjacent to the second upper protective plate of the secondary blocking module, and the second membrane is welded to the base socket while simultaneously covering the base socket and the second upper protective plate.

However, since the base socket and the secondary upper protection plate are separated from each other, there is a step difference between the base socket and the secondary upper protection plate, and the level difference may increase due to the behavior of the hull. Accordingly, excessive stress is generated in the secondary membrane covering the base socket and the secondary upper protective plate at the same time.

That is, excessive stress is generated in the weld connection between the secondary membrane and the base socket. In addition, excessive stress is generated in the secondary membrane at a position corresponding to the boundary between the base socket and the secondary upper protective plate. In this case, the welded connection may be broken and liquefied natural gas may leak.

An object of the present invention is to provide an insulation panel system for a liquefied cargo storage tank capable of minimizing the stress generated in a secondary membrane connected to a fixing module that fixes a primary barrier module and a secondary barrier module to each other.

The insulating panel system for a liquefied cargo storage tank according to an embodiment of the present invention blocks liquefied natural gas, and the first blocking module 100 including the first insulating layer 120, the first blocking module 100 A second blocking module 200 located at the bottom and including a second membrane 210 and a second insulating layer 220, and the first blocking module 100 and the second blocking module 200 are fixed to each other The fixing module 300 includes a plurality of fixing modules 300, wherein the fixing module 300 includes a first base socket 310 fixed to the secondary insulating layer 220, and a stud coupled to the first base socket 310 ( 320), a buffer member 325 covering an upper surface of the first base socket 310, and a second base socket 330 covering the buffer member 325 and the first base socket 310, The second base socket 330 may be welded to the second membrane 210.

The second insulating layer 220 includes a second insulating material 221 and a second upper protective plate 222 formed on the second insulating material 221, and the second upper protective plate 222 is the first Located adjacent to the base socket 310, the secondary membrane 210 may cover a portion of the secondary upper protective plate 222 and the second base socket 330.

The second base socket 330 is in contact with a socket flat portion 331 in contact with an upper surface of the buffer member 325, and a side portion of the buffer member 325 and a side portion of the first base socket 310 It may include a socket side portion (332).

The socket side portion 332 may extend vertically downward from the edge of the socket flat portion 331.

A first thread (332a) is formed on an inner surface of the socket side portion (332), and a side surface of the first base socket (310) is coupled to the first thread (332a) in correspondence with the first thread (332a). A second thread 311b may be formed.

The socket flat portion 331 of the second base socket 330 has a first through hole 330a through which the stud 320 passes, and the buffer member 325 has a first through hole 330a through which the stud 320 passes. It has 2 through-holes 325a, and the first through-holes 330a and the second through-holes 325a may be positioned to have the same central axis Y.

An inner edge of the second base socket 330 formed by the first through hole 330a may be welded to the stud 320 to have an inner welded joint 10.

An outer edge of the second base socket 330 may be welded to the secondary membrane 210 to have an outer welded joint 20.

The stud 320 may include a cylindrical stud body 321, and the inner welding joint 10 may be formed on an outer circumferential surface of the stud body 321.

The stud 320 includes a cylindrical stud body 321, a wing portion 322 formed on an outer circumferential surface of the stud body 321, and the inner welding coupling portion 10 is the wing portion 322 Can be formed in

The secondary membrane 210 may be any one selected from stainless steel or Invar steel.

The second base socket 330 may be any one selected from stainless steel or Invar steel.

According to an embodiment of the present invention, by installing a buffer member and a second base socket on the first base socket, and welding the second base socket to the second membrane, the step between the first base socket and the second upper protective plate is reduced. As a result, stress generated in the secondary membrane can be minimized, and fatigue strength can be improved.

In addition, since the welding connection between the secondary membrane and the second base socket is not easily destroyed by the buffer member and the second base socket covering the same, leakage of liquefied natural gas can be prevented.

1 is a schematic cross-sectional view of an insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention.
2 is a schematic perspective view of an insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention.
3 is a detailed cross-sectional view of a first blocking module, a second blocking module, and a fixing module of the insulating panel system for a liquefied cargo storage tank according to an embodiment of the present invention.
4 is a perspective view of a second base socket and a buffer member of the insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention.
5 is an enlarged cross-sectional view of portion A of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

1 is a schematic side view of an insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention, and FIG. 2 is a schematic perspective view of an insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention, 3 is a detailed cross-sectional view of a first blocking module, a second blocking module, and a fixing module of the insulating panel system for a liquefied cargo storage tank according to an embodiment of the present invention.

1 to 3, the insulation panel system for a liquefied cargo storage tank according to an embodiment of the present invention includes a primary barrier module 100 including a primary membrane 110 and a primary thermal insulation layer 120. ), is located under the primary blocking module 100, the secondary blocking module 200 including the secondary membrane 210 and the secondary insulating layer 220, and the primary blocking module 100 and secondary blocking It includes a plurality of fixing modules 300 fixing the modules 200 to each other.

The insulating panel system for a liquefied cargo storage tank is stacked in the order of a second insulating layer 220, a second membrane 210, a first insulating layer 120, and a first membrane 110 from the inner wall of the hull. The fixing module 300 penetrates the second membrane 210 and connects the first insulating layer 120 and the second insulating layer 220 to each other.

Since the primary membrane 110 is in direct contact with liquefied natural gas in a cryogenic state, low temperature brittleness such as aluminum alloy, invar, 9% nickel steel, stainless steel (SUS), etc. that can respond to stress changes It can be made of a strong metal material. The first membrane 110 is hermetically welded on the first insulating layer 120, and may be performed by, for example, lapping welding or seam welding.

The first insulation layer 120 is located under the primary insulation 121 made of a material such as polyurethane foam with excellent insulation, and the primary lower part made of plywood and is located under the primary insulation 121 A protective plate 122 may be included.

The secondary membrane 210 may be made of stainless steel, invar, or the like. This secondary membrane 210 may be flat.

The secondary insulation layer 220 is a secondary insulation material 221 made of a material such as polyurethane foam with excellent insulation, and a second upper protective plate made of plywood, which is located on the top of the secondary insulation material 221 222, and a second lower protective plate (not shown) located under the secondary insulating material 221 and made of plywood.

The fixing module 300 passes through the first base socket 310 fixed to the second insulating layer 220 and the central hole 311a of the first base socket 310 and is coupled to the secondary insulating material 221 ( 320), a buffer member 325 covering an upper surface of the first base socket 310, a second base socket 330 covering the buffer member 325 and the first base socket 310, and a first insulating layer 120 ) And may include a fixing member 340 for fixing the stud 320.

The first base socket 310 is provided to protrude around the lower circumference of the socket body 311 and the socket body 311 constituting the body, and the groove 221a formed on the upper portion of the secondary insulating material 221 and the secondary It may include a socket flange 312 inserted into the space formed between the lower surface of the upper protection plate 222. The lower surface of the first base socket 310 may be bonded to the upper surface of the secondary insulating material 221.

The stud 320 may include a cylindrical stud body 321 and a wing portion 322 formed on an outer circumferential surface of the stud body 321 and contacting the upper surface of the socket body 311.

The lower surface of the stud body 321 is bonded to the upper surface of the secondary insulating material 221, and the stud body 321 has a first base socket 310, a buffer member 325, and a second base socket 330 And, it can penetrate through the primary heat insulating material (121).

The wing portion 322 may be formed to be inclined downward as it moves away from the stud body 321.

4 is a plan view of a second base socket and a buffer member of the insulating panel system for a liquefied cargo storage tank according to an embodiment of the present invention, and FIG. 5 is an enlarged cross-sectional view of portion A of FIG.

3 and 4, the second base socket 330 has a socket flat portion 331 in contact with an upper surface of the buffer member 325, and a side portion and a first base socket of the buffer member 325 It may include a socket side portion 332 in contact with the side portion of (310).

The socket flat portion 331 may have a first through hole 330a through which the stud 320 passes, and the buffer member 325 may have a second through hole 325a through which the stud 320 passes. The first through hole 330a and the second through hole 325a may be positioned to have the same central axis Y.

The socket side portion 332 may extend vertically downward from the edge of the socket flat portion 331. Accordingly, the buffer member may be fixed on the first base socket 310 without bonding to the first base socket 310 with a separate bonding material.

A first thread 332a may be formed on an inner surface of the socket side portion 332, and a second thread 311b may be formed on the side surface of the first base socket 310 to correspond to the first thread 332a. When the first screw thread 332a and the second screw thread 311b are coupled to each other, the first base socket 310 and the second base socket 330 may be more rigidly coupled. Accordingly, the buffer member 325 may be more completely fixed between the first base socket 310 and the second base socket 330.

The inner edge of the second base socket 330 formed by the first through hole 330a may be welded to the wing portion 322 of the stud 320 to have an inner welded joint 10. In this case, since watertightness is formed between the stud 320 and the first base socket 310, the central hole 311a of the first base socket 310 may be penetrated or blocked.

Meanwhile, an embodiment in which the stud 320 is made of only the stud body 321 having a cylindrical shape, and an inner welding joint is formed on the outer circumferential surface of the stud body 321 is also possible. In this case, since watertightness may not be achieved between the stud 320 and the first base socket 310, the central hole 311a of the first base socket 310 may be formed in a closed form.

The second upper protective plate 222 is positioned adjacent to the first base socket 310, and the second membrane 210 may cover a portion of the second upper protective plate 222 and the second base socket 330. The second base socket 330 may be any one selected from stainless steel or Invar steel. In this case, the outer edge of the second base socket 330 may be welded to the secondary membrane 210 to have an outer welded joint 20.

Accordingly, the second base socket 330 may be connected to the stud 320 and the secondary membrane 210.

In this way, a buffer member 325 and a second base socket 330 serving as a buffer are installed on the first base socket 310, and the second base socket 330 is attached to the stud 320 and the secondary membrane 210. ) By welding connection, it is possible to minimize the stress generated in the secondary membrane 210 due to the step between the first base socket 310 and the secondary upper protective plate 222, and improve the fatigue strength. I can.

In addition, since the outer welded joint 20 between the secondary membrane 210 and the second base socket 330 is not easily destroyed by the buffer member serving as a buffer and the second base socket 330 covering the same, liquefied natural gas Can prevent leakage.

On the other hand, the fixing member 340 is a self-lock nut 341 that is coupled with a part of the stud body 321 inserted in the fixing groove 121a of the primary insulating material to fix the stud body 321 , The stud body 321 penetrates and is disposed on the upper surface of the flat washer 342 in contact with the upper surface of the primary lower protective plate 122, and the self-lock nut 341 It may include a spring washer (Spring Washer) 343 for supporting.

In the above, the present invention has been described with reference to the embodiments shown in the drawings. However, the present invention is not limited thereto, and various modifications or other embodiments falling within the scope equivalent to the present invention are possible by those of ordinary skill in the art. Therefore, the true scope of protection of the present invention should be determined by the claims that follow.

110: primary membrane 120: primary insulating layer
210: secondary membrane 220: secondary insulating layer
221: secondary insulation 222: secondary upper protective plate
300: fixing module 310: first base socket
320: stud 325: cushioning member
330: second base socket 340: fixing member

Claims (12)

Blocking the liquefied natural gas, the first blocking module 100 including the first insulating layer 120,
A second blocking module 200 located below the first blocking module 100 and including a second membrane 210 and a second insulating layer 220, and
A plurality of fixing modules 300 fixing the primary blocking module 100 and the secondary blocking module 200 to each other
Including,
The fixing module 300 is
A first base socket 310 fixed to the second insulating layer 220,
Stud 320 coupled to the first base socket 310,
A buffer member 325 covering the upper surface of the first base socket 310, and
The second base socket 330 covering the buffer member 325 and the first base socket 310
Including,
The second base socket 330 is welded to the secondary membrane 210, the insulation panel system for a liquefied cargo storage tank. The method of claim 1,
The second insulating layer 220 includes a second insulating material 221 and a second upper protective plate 222 formed on the second insulating material 221,
The second upper protective plate 222 is located adjacent to the first base socket 310,
The secondary membrane 210 covers a part of the secondary upper protective plate 222 and the second base socket 330, a thermal insulation panel system for a liquid cargo storage tank. The method of claim 1,
The second base socket 330 is
The socket flat portion 331 in contact with the upper surface of the buffer member 325, and
Insulation panel system for a liquefied cargo storage tank comprising a side portion of the buffer member (325) and a socket side portion (332) in contact with the side portion of the first base socket (310). The method of claim 3,
The socket side portion 332 extends vertically downward from the edge of the socket flat portion 331, a liquefied cargo storage tank insulation panel system. The method of claim 3,
A first thread (332a) is formed on the inner side of the socket side portion (332),
Insulation panel system for a liquefied cargo storage tank is formed on a side portion of the first base socket 310, corresponding to the first thread 332a and coupled with the first thread 332a. The method of claim 3,
The socket flat portion 331 of the second base socket 330 has a first through hole 330a through which the stud 320 passes,
The buffer member 325 has a second through hole 325a through which the stud 320 passes,
The first through-hole (330a) and the second through-hole (325a) are located to have the same central axis, a liquefied cargo storage tank insulation panel system. The method of claim 6,
The inner edge of the second base socket 330 formed by the first through hole 330a is welded to the stud 320 to have an inner welded joint 10, an insulating panel for a liquefied cargo storage tank system. The method of claim 7,
The outer edge of the second base socket 330 is welded to the secondary membrane 210 to have an outer welded joint 20, the insulating panel system for a liquefied cargo storage tank. The method of claim 7,
The stud 320 is
Including a cylindrical stud body 321,
The inner welding coupling portion 10 is formed on the outer circumferential surface of the stud body 321, a liquefied cargo storage tank insulation panel system. The method of claim 7,
The stud 320 is
A cylindrical stud body 321,
Wing portion 322 formed on the outer circumferential surface of the stud body 321
Including,
The inner welding coupling portion 10 is formed on the wing portion 322, a liquefied cargo storage tank insulation panel system. The method of claim 1,
The secondary membrane 210 is any one selected from stainless steel or Invar steel, a liquefied cargo storage tank insulation panel system. The method of claim 1,
The second base socket 330 is any one selected from stainless steel or Inba steel, a liquefied cargo storage tank insulation panel system.

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