KR101908563B1 - Heat insulation structure for cryogenic liquid storage tank and installation method thereof - Google Patents

Abstract

The present invention relates to a heat insulating structure and a method for installing a heat insulating structure in a cryogenic fluid storage tank, more specifically, a bridge strip is provided between the heat insulating boards, and a unit membrane is welded on the bridge strip, The present invention relates to a heat insulating structure and a method of installing a heat insulating structure in a cryogenic fluid storage tank, in which a unit membrane is provided to minimize a special member of a corner portion and minimize stress concentration phenomenon occurring in a membrane due to a height step of a heat insulating board.
The heat insulating structure of the cryogenic fluid storage tank according to the present invention comprises a plurality of heat insulating boards spaced apart from each other on the inner wall of the storage tank, the heat insulating structure being coupled to the inner wall of the storage tank for insulating the cryogenic fluid storage space. A bridge strip installed so as to extend between the adjacent heat insulating boards; A cover member provided on an upper portion of the bridge strip; And a unit membrane installed on the heat insulating board.

Description

TECHNICAL FIELD [0001] The present invention relates to a cryogenic fluid storage tank and a method of installing the cryogenic fluid storage tank,

The present invention relates to a heat insulating structure and a method for installing a heat insulating structure in a cryogenic fluid storage tank, more specifically, a bridge strip is provided between the heat insulating boards, and a unit membrane is welded on the bridge strip, The present invention relates to a heat insulating structure and a method of installing a heat insulating structure in a cryogenic fluid storage tank, in which a unit membrane is provided to minimize a special member of a corner portion and minimize stress concentration phenomenon occurring in a membrane due to a height step of a heat insulating board.

In general, the cargo hold of a membrane type liquefied natural gas carrier transports -163 degrees of liquefied natural gas from the sea, so it is exposed to a static / dynamic load including loads due to cryogenic heat load and movement of the ship and hull deformation, High technology is required to transport the gas safely.

The liquefied natural gas storage tank includes a primary barrier, an upper insulation board, a secondary barrier and a lower insulation board, and the like disposed outwardly from the inside of the liquefied natural gas storage tank, and is coupled to the inside of the hull.

Such a liquefied natural gas storage tank is formed by joining a plurality of lower heat insulating boards in a hull, installing a secondary barrier on a plurality of lower heat insulating boards, installing an upper insulating board and a primary barrier on the secondary barrier .

For example, a method of manufacturing a conventional liquefied natural gas storage tank will be described as follows. First, the operator joins the lower insulation board, the main secondary barrier, and the upper insulation board to the inner hull adjacent to each other. And the operator installs an auxiliary secondary barrier and connection board in the space between the upper secondary insulation board and the upper secondary insulation board above the lower insulation board. Install a primary barrier over the top insulation board and the connection board.

For example, since the primary barrier, that is, the plurality of unit membranes is installed on the anchor strip provided on the upper insulating board through welding, the upper insulating board and the unit membrane must be staggered from each other.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a heat insulating structure of a cryogenic fluid storage tank according to the prior art.

As shown in FIG. 1, when a heat insulating board is installed on the inner wall of the liquefied natural gas storage tank, a gap is maintained between the heat insulating board 10 and the heat insulating board 10, An anchor strip 30 of an SUS material is installed on the upper part of the heat insulating board 10 and a unit membrane 20 is disposed on the anchor strip 30 to form an anchor strip 30 and a unit membrane 20) is fixed by welding.

As described above, when the heat insulating board 10 and the membrane 20 are arranged in a staggered arrangement, special type membranes must be separately manufactured and installed at the corners of the liquefied natural gas storage tank, .

On the other hand, there is a problem that a height difference between the heat insulating boards occurs due to a static / dynamic load including a load due to the movement of the ship and the deformation of the hull, thereby causing a stress concentration phenomenon in the primary barrier.

Korean Patent Publication No. 10-2013-0005539 (2013.01.16)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a bridge strip, And it is an object of the present invention to minimize the stress concentration concentrated on the primary barrier welded to the unit membrane due to the height difference of the heat insulating board.

According to an aspect of the present invention, there is provided a heat insulating structure coupled to an inner wall of a storage tank for inspecting a cryogenic fluid storage space, the heat insulating structure comprising: a plurality of heat insulating boards disposed on an inner wall of the storage tank; A bridge strip installed so as to extend between the adjacent heat insulating boards; A cover member installed on an upper surface of a stepped surface formed on the bridge strip; And a unit membrane installed on the upper part of the heat insulating board, wherein the heat insulating board comprises: a first stepped surface formed stepwise at the upper surface of the heat insulating board; and a second stepped surface formed at the first stepped surface, Wherein the bridge strip includes a first strip stepped surface formed to be stepped on an upper surface of the bridge strip and provided at the same height as the first stepped surface, And the cover member is provided to share an upper surface of the first stepped surface and the upper surface of the first stripped stepped surface, and the unit membrane is disposed at a position corresponding to each of the heat- To provide a thermal insulation structure of a cryogenic fluid storage tank to be installed.

And at least one side of the bridge strip which is stepped is preferably slidable with respect to the heat insulating board and the cover member.

The bridge strip and the heat insulating board are preferably spaced from each other in a lateral direction so that the bridge strip can slide in a horizontal direction.

The bridge strip and the cover member may be laterally spaced apart from each other such that the bridge strip can slide in a horizontal direction.

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The unit membrane preferably has a wrinkle portion that does not cross each other.

Wherein the bridge strips have a rectangular cross-section, wherein the bridge strips are disposed in a plurality of neighboring two pleat portions parallel to each other, the length of the bridge strip being less than or equal to the spacing between the two pleat portions .

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According to the present invention, since a bridge strip is provided between the heat insulating boards and a membrane is welded on the bridge strips, a unit membrane is provided at a position corresponding to each of the heat insulating boards to minimize the special member of the corner portion, The stress concentration phenomenon occurring in the primary barrier welded to each other by the unit membrane is minimized.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a heat insulating structure of a cryogenic fluid storage tank according to the prior art.
2 is a view showing a heat insulating structure of a cryogenic fluid storage tank according to the present invention.
3 is a view showing the generation of the membrane stress according to the height difference between the heat insulating boards in the heat insulating structure of the cryogenic fluid storage tank according to the present invention.
4 is a perspective view of a heat insulating structure according to an embodiment of the present invention.
5 is a side view of a heat insulating structure according to an embodiment of the present invention.
6 is a perspective view of a heat insulating structure according to another embodiment of the present invention.
7 is a side view of a heat insulating structure according to another embodiment of the present invention.
8 is a view showing a state where a membrane of a heat insulating structure according to the present invention is installed.
Fig. 9 is an enlarged view of a portion B in Fig. 5 and Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an embodiment of a heat insulating structure of a cryogenic fluid storage tank according to the present invention will be described in detail with reference to the drawings, wherein like reference numerals designate like or corresponding components, A duplicate description will be omitted.

According to the present embodiment, the LNG storage tank is a storage tank storing a cryogenic fluid such as LNG, and a primary barrier welded with a plurality of unit membranes sealing the interior of the storage tank is installed.

That is, the storage tank is provided with a heat insulating structure for inserting the inside, and a membrane can be used as the primary wall directly contacting the LNG in the heat insulating structure.

FIG. 2 is a view showing a heat insulating structure of a cryogenic fluid storage tank according to the present invention, and FIG. 3 is a view showing the occurrence of a membrane stress according to a height difference between heat insulating boards in a heat insulating structure of a cryogenic fluid storage tank according to the present invention FIG. 4 is a perspective view of a heat insulating structure according to an embodiment of the present invention, FIG. 5 is a side view of a heat insulating structure according to an embodiment of the present invention, and FIG. FIG. 7 is a side view of a heat insulating structure according to another embodiment of the present invention, and FIG. 8 is a view showing a state where a membrane of the heat insulating structure according to the present invention is installed Fig.

As shown in FIGS. 2 to 8, the thermal insulation structure of the cryogenic fluid storage tank according to the present invention is arranged so as to be spaced apart from each other on the inner wall of the storage tank to insulate the cryogenic fluid storage space, and includes a ply wood layer A cover member 150 provided on the upper portion of the bridge strip 130 and a cover member 150 disposed on the upper side of the insulation board 110. The cover member 150 is installed on the bridge strip 130, And may include a unit membrane 120 installed on the upper part.

In other words, conventionally, since the unit membrane is installed on the anchor strip provided on the heat insulating board through welding, the heat insulating board and the unit membrane can not be arranged to be staggered from each other, so that a special type membrane must be separately manufactured at the corner portion As shown in FIG. 2, in the present invention, by providing the unit membrane 120 at a position corresponding to each of the heat insulating boards 110, it is possible to use the standard membrane and the heat insulating board as much as possible.

On the other hand, as shown in FIG. 3, the height difference between the heat insulating boards 110 occurs due to the movement of the ship and the load due to the deformation of the hull, and the like, A portion (A) in which the stress due to the height step is concentrated is generated.

Accordingly, the bridge strips 130 may be installed so as to span between the adjacent heat insulating boards 110 to minimize the stress generated in the welded primary walls of the plurality of unit membranes.

Fig. 9 is an enlarged view of part B of Fig. 5 and Fig. 7, showing the construction of the heat insulating board 110, the bridge strip 130, and the cover member 150. Fig. 9, the heat insulating board 110 includes a stepped portion formed stepwise along the circumference, the stepped portion including a first stepped surface 112 formed to be stepped on the upper surface 111, And a second stepped surface 113 that is stepped back on the second surface 112. That is, the height becomes lower toward the upper surface 111, the first step surface 112, and the second step surface 113.

The bridge strip 130 also includes a strip step formed at least on one side and the strip step may include a first strip step surface 132 that is stepped on the strip upper surface 131.

A bridge strip 130 is installed on the second stepped surface 113 of the adjacent heat insulating board 110 and a cover member 150 is installed on the first stepped surface 112 and the first stripped stepped surface 132 .

The height difference A1 between the upper surface 111 and the first step face 112 is substantially the same as the height difference B1 between the upper face 131 of the strip and the first strip face 132, And the height difference A2 between the first step face 112 and the second step face 113 is substantially the same as the thickness C1 of the first strip face 132 and the bridge strip lower surface 113. [ The height difference B2 may be substantially the same as the height difference B2.

 Here, the same height can be used to mean that there is a difference in height.

4 and 5, a cover member 150 is placed on one side of a bridge strip 130 made of stainless steel on the heat insulating board 110, The cover member 150 and the heat insulating board 110 can be fastened by the fastening member 160 such as a rivet or a screw.

After the cover member 150 is fastened to the heat insulating board 110, the unit membrane 120 is placed at a position corresponding to the heat insulating board 110 and the unit membrane 120 is welded to the bridge strip 130 have.

The bridge strip 130 is slidably mounted to the heat insulating board 110 and the cover member 150 so that the bridge strip 130 and the heat insulating board 110 are slidable in the horizontal direction The bridge strip 130 and the cover member 150 are spaced apart from each other in the lateral direction and have a spacing space 134. The bridge strip 130 and the cover member 150 are spaced apart from each other in the lateral direction.

6 to 7, the cover member 150 is placed on one side of the bridge strip 130 made of stainless steel on the heat insulating board 110, The cover member 150 is disposed only on one side of the bridge strip 130 installed on the adjacent heat insulating board 110 so that only the upper surface of the heat insulating board 110 is installed.

The bridge strip 130 is stepped on one side of the bridge strip 130 on which the cover member 150 is placed so that the cover member 150 and the heat insulating board 110 are fastened to the fastening member 160, The other side of the bridge strip 130 where the cover member 150 is not placed is held by the bridge strip 130 and the heat insulating board 110 without being stepped, And can be fastened by a fastening member 160 such as a screw.

Therefore, the bridge strip 130 is slidably installed only on one side.

The corner strip 132 of the heat insulating board 110 has a "+" shape at the corner 132. In one embodiment of the present invention, the four corner strips 130 of the cross- The cover member 150 may be placed on both sides of the cross-shaped bridge strip 130. In other embodiments, the cover member 150 may be placed on the two corner tops of the cross-shaped bridge strip 130. FIG.

8, the unit membrane 120 has wrinkles 121 and 122 that do not intersect with each other, and the bridge strip 130 is disposed between the wrinkles 121 and 121 that are parallel to each other. And the length of the bridge strip 130 may be less than or equal to the distance l between the two pleats.

Since the bridge strip 130 is installed between the adjacent heat insulating boards 110 and is installed by welding with the membrane 120, the bridge strips 130 serve to connect the heat insulating board 110 and the heat insulating board 110, By making the height step between the boards 110 as continuous as possible, the stress generated in the first primary barrier, where the unit membranes 120 are welded to each other, can be minimized.

The unit membrane 120 may be disposed at a position corresponding to each of the heat insulating boards 110. The connecting space between the heat insulating boards 110 and the unit membrane 120 may be a plane The special members of the corner portions can be minimized.

A method of installing the heat insulating structure coupled to the inner wall of the storage tank to insulate the cryogenic fluid storage space will be described as follows.

In general, the heat insulating board includes an upper insulating board and a lower insulating board, and the unit membrane includes an upper unit membrane and a lower unit membrane. However, in the following description, This is explained separately.

A method for installing a heat insulating structure coupled to an inner wall of a storage tank for inspecting a cryogenic fluid storage space includes a first step of installing a lower heat insulating board on an inner wall of a storage tank, a second step of installing a lower unit membrane on a lower heat insulating board, A fourth step of installing a bridge strip so as to extend between adjacent upper heat insulating boards, a fifth step of installing a cover member on at least one side of the bridge strip, And a sixth step of installing an upper unit membrane on the heat insulating board through welding with the bridge strip.

The fourth step may be such that the bridge strip and the upper heat insulating board are spaced apart from each other in a lateral direction so that the bridge strip can slide in the horizontal direction. In the fifth step, the bridge strip is slidable in the horizontal direction, And the cover members may be provided so as to be laterally spaced from each other.

In the sixth step, the upper unit membrane may be installed at a position corresponding to each of the upper insulating boards.

The insulation structure of the cryogenic fluid storage tank applied in the embodiment of the present invention may be installed on a ship or the like, and may be installed on land to store, store or transport LNG.

Here, a ship is a concept that includes both a structure and a ship that are floated at sea where a flow occurs and a storage tank for storing LNG, which is a liquid cargo such as an LNG carrier, is loaded at a cryogenic temperature. For example, (LNG-SRV), as well as offshore structures such as LNG-FPSO (Floating, Production, Storage and Offloading) and LNG-FSRU (Floating Storage and Regulation Unit) .

According to the present invention, there is provided a method of installing a heat insulation structure and a heat insulation structure in a cryogenic fluid storage tank, wherein a bridge strip is provided between the heat insulation boards, and a membrane is welded to the bridge strip, It is possible to minimize the special member of the corner portion and minimize stress concentration phenomenon occurring in the membrane due to the height difference of the heat insulating board.

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. It is.

110: Insulation board 120: Unit membrane
130: bridge strip 150: cover member
160: fastening member

Claims (17)

1. A heat insulating structure for coupling to a cistern interior of a storage tank for inspecting a cryogenic fluid storage space,
A plurality of heat insulating boards disposed on the inner wall of the storage tank so as to be spaced apart from each other;
A bridge strip installed so as to extend between the adjacent heat insulating boards;
A cover member installed on an upper surface of a stepped surface formed on the bridge strip; And
And a unit membrane installed on the upper part of the heat insulating board,
Wherein the heat insulating board includes a first stepped surface stepped on an upper surface of the heat insulating board and a second stepped surface stepped back from the first stepped surface,
Wherein the bridge strip includes a first strip stepped surface formed at an upper surface of the bridge strip and provided at the same height as the first stepped surface,
Wherein the bridge strip is provided so as to share an upper surface of the second stepped surface of the adjacent heat insulating board,
Wherein the cover member is provided to share an upper surface of the first stepped surface and a surface of the first stripped stepped surface,
And the unit membrane is installed at a position corresponding to each of the heat insulating boards. The method according to claim 1,
Wherein at least one side of the bridge strip is slidably slidable with respect to the heat insulating board and the cover member. The method of claim 2,
Wherein the bridge strip and the heat insulating board are laterally spaced apart from each other such that the bridge strip is slidable in a horizontal direction. The method of claim 2,
Wherein the bridge strip and the cover member are laterally spaced from each other such that the bridge strip is slidable in a horizontal direction. delete delete delete delete delete The method of claim 2,
Wherein the unitary membrane has corrugations that do not cross each other. The method of claim 10,
Wherein the bridge strip has a rectangular cross-section,
The bridge strips are provided in a plurality of bridging strips, respectively, and are disposed between neighboring two wrinkles that are parallel to each other,
Wherein the length of the bridge strip is less than or equal to the distance between the two wrinkles. delete delete delete delete delete delete

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