KR102525949B1 - Insulation system of membraine type storage tank and membrain type storage tank - Google Patents

Abstract

The present invention relates to an insulation system structure of a membrane type storage tank and a membrane type storage tank including the same, and more specifically, primary insulation in the corner area of a liquefied natural gas storage tank that is vulnerable to structural deformation due to hull bending It relates to an insulation system structure of a membrane type storage tank that minimizes structural deformation by forming a deformation absorbing space between a panel and a secondary insulation panel, and a membrane type storage tank including the same.
The insulation system of the membrane type storage tank of the present invention is provided to insulate the inner space of the liquefied natural gas storage tank from the outside, and has a secondary insulation panel having a bent shape to be provided at the corner of the liquefied natural gas storage tank; A secondary membrane laminated on the secondary insulation panel; A primary insulation panel laminated on the secondary membrane and having a bent shape to be combined with the secondary insulation panel; and a primary membrane laminated on the primary insulation panel, and a strain absorbing space portion is formed between the inner surface of the corner portion of the secondary insulation panel and the outer surface of the corner portion of the primary insulation panel.

Description

Insulation system of membrane type storage tank and membrane type storage tank including the same

The present invention relates to an insulation system structure of a membrane type storage tank and a membrane type storage tank including the same, and more specifically, primary insulation in the corner area of a liquefied natural gas storage tank that is vulnerable to structural deformation due to hull bending It relates to an insulation system structure of a membrane type storage tank that minimizes structural deformation by forming a deformation absorbing space between a panel and a secondary insulation panel, and a membrane type storage tank including the same.

Natural gas is a fossil fuel containing methane as a main component and a small amount of ethane, propane, etc., and has recently been spotlighted as a low-emission energy source in various technical fields.

Natural gas is transported in a gaseous state through onshore or offshore gas pipelines, or transported in a liquefied natural gas (LNG) state to a distant consumer while being stored in an LNG carrier. Liquefied natural gas is obtained by cooling natural gas to a cryogenic temperature (approximately -163 ° C or less), and its volume is reduced to approximately 1/600 of that of gaseous natural gas, making it very suitable for long-distance transportation through sea.

A liquefied natural gas carrier is equipped with a storage tank (cargo, also referred to as a cargo hold) capable of storing and storing liquefied natural gas obtained by cooling and liquefying natural gas. Since the boiling point of liquefied natural gas is about -162℃ at atmospheric pressure, the storage tank for liquefied natural gas is made of materials that can withstand ultra-low temperatures, such as aluminum steel, stainless steel, and 35% nickel steel, in order to safely store and store liquefied natural gas. It can be manufactured, and it is designed with a structure that is strong against thermal stress and heat shrinkage and can prevent heat intrusion.

An LNG transporter for loading and unloading LNG to a place of demand on land by navigating the sea by loading LNG, and an LNG RV (Regasification Vessel) that regasifies stored LNG and unloads it in the form of natural gas after navigating the sea carrying LNG and arriving at a place of demand on land. includes storage tanks installed on LNG carriers or LNG RVs in floating offshore structures such as LNG FPSO (Floating, Production, Storage and Offloading) or LNG FSRU (Floating Storage and Regasification Unit).

The LNG FPSO is a floating offshore structure used to directly liquefy produced natural gas at sea, store it in a storage tank, and transfer the LNG stored in the storage tank to an LNG carrier when necessary. In addition, the LNG FSRU is a floating offshore structure that stores LNG unloaded from an LNG carrier at sea far from the land in a storage tank and vaporizes the LNG as needed to supply it to land demand.

In this way, a storage tank for storing LNG in a cryogenic state is installed in offshore structures such as LNG carriers, LNG RVs, LNG FPSOs, and LNG FSRUs that transport or store liquid cargo such as LNG at sea.

These storage tanks can be classified into an independent tank type and a membrane type depending on whether the cargo load directly acts on the insulation material. The membrane type storage tank is divided into GTT NO 96 type and TGZ Mark Ⅲ type, and the independent tank type storage tank is divided into MOSS type and IHI-SPB type.

The TGZ Mark III type storage tank, which is a type of conventional liquefied natural gas storage tank, has a structure in which a primary membrane, a primary insulation panel, a secondary membrane, and a secondary insulation panel are laminated. The primary membrane is a part in direct contact with the liquefied natural gas stored in the storage tank and is made of a stainless steel membrane with a thickness of 1.2 mm.

Since stainless steel has excellent sealing ability, it is suitable as a membrane, but since thermal deformation is large, the primary membrane is configured by forming a plurality of wrinkles in consideration of thermal deformation.

However, unlike the primary membrane, the secondary membrane has a structure in which a primary insulation panel is stacked on top of the membrane and a secondary insulation panel is stacked on the bottom of the membrane, that is, a structure in which the secondary membrane is interposed, so that the secondary membrane Despite the arrangement of, there is a problem that the primary insulation panel and the secondary insulation panel must be able to be combined. In the case where the secondary membrane is stainless steel, it is difficult to form a laminated bonding structure with further thermal deformation, such difficulties. In particular, it is more urgent in the case of the corner part of the insulation system structure of the storage tank.

That is, the corner region of the insulation system structure of the storage tank is vulnerable to structural deformation due to hull bending caused by the maneuvering of the ship.

Korean Patent Publication No. 10-2012-0131902

The present invention has been made to solve the above problems, the present invention is a deformation absorbing space between the primary insulation panel and the secondary insulation panel in the corner region of the liquefied natural gas storage tank, which is vulnerable to structural deformation for hull bending (banding) The purpose is to minimize structural deformation by forming a part.

According to one aspect of the present invention for achieving the above object, it is provided to insulate the inner space of the liquefied natural gas storage tank from the outside, and the secondary insulation panel having a bent shape to be provided at the corner of the liquefied natural gas storage tank ; A secondary membrane laminated on the secondary insulation panel; A primary insulation panel laminated on the secondary membrane and having a bent shape to be combined with the secondary insulation panel; And a membrane type comprising a primary membrane laminated on the primary insulation panel, wherein a strain absorbing space is formed between the inner surface of the corner portion of the secondary insulation panel and the outer surface of the corner portion of the primary insulation panel. Provides an insulation system for storage tanks.

The primary insulation panel, the first insulation member of the bent form; Wood blocks installed on both flat sides of the first heat insulating member; A second heat insulating member coupled to the side of the wood block; a first plywood installed parallel to the bottom of the storage tank and stacked on lower surfaces of the first heat insulating member, the wood block, and the second heat insulating member; and a second plywood installed in parallel with the side surface of the storage tank and stacked on the side surfaces of the first heat insulating member, the wood block, and the second heat insulating member, and coupled to the first heat insulating member and the wood The total length (L1) of the block and the second heat insulating member is preferably formed longer than the length (P1) of the first plywood and the length (P2) of the second plywood.

It is preferable that the outer surface of the corner portion of the primary insulation panel is formed to have a right angle shape.

It is preferable that the outer surface of the corner portion of the primary insulation panel is formed to have a chamfered shape.

The outer surface of the corner portion of the primary insulation panel is preferably formed to have a curvature.

It is preferable that the primary insulation panel is coupled to the secondary insulation panel by inserting the primary insulation panel coupling means provided on the secondary insulation panel into a coupling hole provided in the primary insulation panel.

The secondary insulation panel, the first membrane bonding layer coupled along the bent edge and provided by assembling the second steel plate on the plywood, coupled to the first membrane bonding layer spaced apart, the metal strip on the plywood It includes a formed second membrane bonding layer, and the primary insulation panel coupling means is preferably mounted on a metal strip formed on the secondary membrane bonding layer of the secondary insulation panel.

Preferably, the second membrane is welded to the metal strips of the first membrane bonding layer and the second membrane bonding layer.

The primary insulation panel includes a first steel plate laminated on an upper surface of the first insulation member and the wood block; And it is preferable to further include an upper plywood laminated on the upper surface of the second heat insulating member.

A plurality of stud bolts are formed on both sides of the first steel plate, and the plurality of stud bolts are inserted into a plurality of bolt coupling holes formed in the wood block, so that the first steel plate and the wood block are coupled. do.

Grooves are formed on the lower surfaces of the first insulating member and the wood block, and one groove formed in the first insulating member and one groove formed in the wood block form one coupling groove, and in the coupling groove By inserting a block-shaped coupling key, it is preferable that the first heat insulating member and the wood block are fixedly coupled.

A secondary insulation panel coupling hole is formed through the second insulation member and the plywood bonded to the upper and lower surfaces of the second insulation member, and the primary insulation panel coupling means formed in the secondary insulation panel is the secondary insulation panel. By being defective in the panel coupling hole, it is preferable that the primary insulation panel and the secondary insulation panel are coupled.

According to another aspect of the present invention, a membrane type storage tank including the insulation system is provided.

According to the insulation system of the membrane-type storage tank of the present invention and the membrane-type storage tank including the same, the primary insulation panel and the secondary insulation panel in the corner area of the liquefied natural gas storage tank, which is vulnerable to structural deformation for hull bending There is an effect of minimizing structural deformation by forming a deformation absorbing space portion therebetween.

In addition, by providing an empty space for absorbing deformation, the ratio of material use is lowered, thereby reducing the overall weight of the storage tank, thereby enabling loading of a larger amount of LNG than before.

In addition, there is an effect of preventing the secondary membrane from being destroyed due to a change in the shape of the liquefied natural gas storage tank due to hull deformation and thermal deformation.

1 schematically shows a part of a membrane type storage tank according to the present invention.
Figure 2 is a three-dimensional view of the corner structure of the insulation system of the membranous storage tank according to the present invention.
Figure 3 shows a secondary insulation panel constituting the insulation system of the membrane type storage tank according to the present invention.
Figure 4 is an enlarged view of a part of the secondary insulation panel and the secondary membrane constituting the insulation system of the membranous storage tank according to the present invention.
Figure 5 shows a primary insulation panel constituting the insulation system of the membrane type storage tank according to the present invention.
Figure 6 shows an embodiment of the corner portion shape of the primary insulation panel of the insulation system of the membrane-type storage tank according to the present invention.
Figure 7 shows another embodiment of the corner portion shape of the primary insulation panel of the insulation system of the membrane-type storage tank according to the present invention.
Figure 8 shows another embodiment of the corner portion shape of the primary insulation panel of the insulation system of the membrane-type storage tank according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

First, a liquefied natural gas storage tank according to an embodiment of the present invention will be described with reference to FIG. 1 . 1 schematically shows a part of a membrane-type storage tank for storing liquefied natural gas according to the present invention.

As shown in FIG. 1, the membrane type storage tank according to an embodiment of the present invention includes a primary membrane 110, a primary insulation panel 120, a secondary membrane 200 and a secondary insulation panel 300. include

The primary membrane 110 is installed on the primary insulation panel 120 to make the liquefied natural gas (LNG) stored in the storage tank liquid-tight while in contact with the liquefied natural gas.

The secondary membrane 200 is installed between the primary insulation panel 120 and the secondary insulation panel 300 and serves to liquid-tighten the liquefied natural gas when the primary membrane 110 leaks.

A plurality of wrinkles are formed on the primary membrane 110 to prevent shrinkage due to temperature change and damage during elongation. The wrinkles are stretched or contracted by the temperature change according to the loading of the liquefied natural gas to prevent damage due to thermal deformation applied to the primary membrane 110.

The primary membrane 110 may be made of stainless steel.

The present invention relates to a corner portion of a liquefied natural gas storage tank of this structure.

The corner portion of the membrane type storage tank according to the present invention constitutes an insulation system in which an insulation panel and a membrane for sealing are laminated in two layers.

Figure 2 is a three-dimensional view of the corner structure of the insulation system of the membranous storage tank according to the present invention.

Referring to FIG. 2, the insulation system of the membrane-type storage tank according to the present invention includes a secondary insulation panel 300 bent in a shape suitable for a corner, and a secondary membrane laminated on the secondary insulation panel 300 ( 200) and the secondary membrane 200 and the primary insulation panel 120 bent in the same shape as the secondary insulation panel 300 and stainless steel material laminated on the primary insulation panel 120 1 It is composed of a secondary membrane (not shown).

In the insulation system of the membrane-type storage tank according to the present invention, not only the primary membrane but also the secondary membrane 200 can be made of stainless steel, and is optimal for the secondary insulation panel 300 and the primary insulation panel 120. It can be stacked in the structure of.

In addition, the secondary insulation panel 300 and the primary insulation panel 120 configured with steel plates at the corners of the secondary insulation panel 300 and the primary insulation panel 120 bent to fit the corner portion of the membrane type storage tank can provide.

Accordingly, the primary insulation panel coupling means 332 provided in the secondary insulation panel 300 to be described later is inserted into the coupling hole provided in the primary insulation panel 120, and the secondary insulation panel 300 and The primary insulation panel 120 is coupled.

Hereinafter, the structure of the secondary insulation panel 300 and the primary insulation panel 120 for this will be looked at, respectively.

Referring to Figures 3 and 4, the secondary insulation panel 300 according to the present invention by the heat insulation member 310 formed of polyurethane foam, etc., the internal space of the liquefied natural gas storage tank is thermally blocked from the outside Let it be.

In the heat insulating member 310, the third heat insulating member 311 and the fourth heat insulating member 312 are coupled to each other to form a corner portion of the heat insulating system, and may form an angle of about 90 degrees.

The combination of the third heat insulating member 311 and the fourth heat insulating member 312 is, as shown in FIG. 2, a plywood 315 in a portion between the third heat insulating member 311 and the fourth heat insulating member 312 is inserted to secure a space, and glass wool 316 is foamed in the remaining space to be adhesively fixed. The glass wool 316 may not be filled up to the inner plywood of the heat insulating member 310 to form an empty space region on the corner side.

Membrane bonding layers 320 and 330 are assembled on the heat insulating member 310 , and membranes are stacked on the membrane bonding layers 320 and 330 .

The membrane bonding layer in the present invention is assembled by being divided into a first membrane bonding layer 320 and a second membrane bonding layer 330 assembled along the bent edge of the heat insulating member 310 .

The first membrane bonding layer 320 formed at the corner is formed by coupling the second steel plate 321 to the third plywood 322 by a screw, and between the two third plywoods 322, a corner insulation material ( 323) are combined. That is, it is formed by combining the third plywood and the corner insulator in a bent form like the second steel plate 321 . The first membrane bonding layer 320 is formed along the bent edge of the heat insulating member 310, and as shown, a plurality of the first membrane bonding layer 320 is divided and arranged and bonded.

And, the second membrane bonding layer 330 is provided with plywood, is assembled on a flat surface other than the corner of the heat insulating member 310, and is arranged spaced apart from the first membrane bonding layer 320, and the heat insulating member 310 ) Along the length direction of the plurality are divided and arranged are bonded (bonding).

On the second membrane bonding layer 330, a metal strip 331 (steel strip) is formed in a regular pattern.

The secondary insulation panel 300 of the present invention is made of a configuration for configuring a membrane laminated on the insulation panel with stainless steel (SUS) to seal the internal space of the storage tank, and also, on the secondary membrane, which will be described later. The primary insulation panel 120 is laminated and made of a configuration that can be combined with the secondary insulation panel 300.

So, the secondary membrane 200 laminated on the secondary insulation panel 300 is laminated by welding the metal strip 331 on the second membrane bonding layer 330 and the first membrane bonding layer 320.

The metal strip 331 is formed in a lattice shape to be suitable for stacking the second membrane bonding layer 330 thereon.

The second membrane 200 made of stainless steel is formed with a plurality of wrinkles 210 to prevent damage during contraction and elongation due to temperature change.

In the secondary insulation panel 300 of the present invention, the first membrane bonding layer 320 and the second membrane bonding layer 330 are spaced apart so that the plurality of wrinkles 210 can be seated, and a gap is formed therebetween. In addition, the first membrane bonding layer 320 and the second membrane bonding layer 330 are formed by being divided into many, so that a gap is formed between them.

Accordingly, the wrinkled portion 210 of the second membrane 200 can be seated in the gap formed.

In addition, on the metal strip 331 of the second membrane bonding layer 330, the primary insulation panel 120, which will be described later, is laminated on the second membrane to be combined with the secondary insulation panel 300. Panel coupling means 332 is mounted, such coupling means is provided as an anchor (anchor), etc., may be formed such that the primary insulation panel 120 can be fitted.

As described above, the corner portion insulation panel of the membrane type storage tank according to the present invention is formed of stainless steel and has a configuration in which a membrane having wrinkles can be welded, even though the membrane is stainless steel, the storage tank on the membrane. By having a configuration in which the primary insulation panel corresponding to the inner side is laminated and can be easily coupled to the secondary insulation panel, the membrane type storage tank can be configured as such a laminated structure.

Figure 5 shows a primary insulation panel constituting the insulation system of the membrane type storage tank according to the present invention.

Referring to FIG. 5, the primary insulation panel 120 according to the present invention is a first insulation member 121 provided in a bent form, and a wood block coupled to both flat side surfaces of the first insulation member 121 ( 122), the first steel plate 123 laminated on the upper surface of the first heat insulating member 121 and the wood block 122, the second heat insulating member 124 coupled to the side of the wood block 122, the second heat insulating member ( 124), the upper surface plywood 125 laminated on the upper surface, installed in parallel with the bottom of the storage tank, and on the lower surface of the first heat insulating member 121, the wood block 122, and the second heat insulating member 124 The first ply wood 126 and the storage tank are installed in parallel with the side surfaces of the first ply wood 126 and the storage tank, and the second ply is laminated on the side surfaces of the first heat insulating member 121, the wood block 122, and the second heat insulating member 124 Wood 127 may be included.

First, the first steel plate 123 is provided in a form bent to fit the corner portion of the membrane type storage tank of the present invention, and a plurality of stud bolts are formed on the lower surface of the first steel plate 123.

In addition, a plurality of bolt coupling holes are formed in the wood block 122 to be coupled to the lower surface of the first steel plate 123 to correspond to the stud bolts, so that the wood block 122 is coupled to the lower surface of the first steel plate 123.

Wood blocks 122 are coupled to both sides of the first steel plate 123, and a first heat insulating member 121 is coupled between the wood blocks 122.

The first heat insulating member 121 is difficult to bond with the first steel plate 123, and is instead fixedly coupled with the wood block 122.

To this end, grooves are formed on the lower surfaces of the first insulating member 121 and the wood block 122, respectively, and these grooves face each other to form one coupling groove.

By inserting a block-type coupling key into such a coupling groove, the first heat insulating member 121 and the wood block 122 are coupled.

This coupling key may be made of wood material, and the coupling key may be fitted or fixed by screws, whereby the first heat insulating member 121 and the wood block 122 are coupled.

The second heat insulating member 124 is bonded to the side of the wood block 122, and the upper surface of the plywood 125 is laminated on the upper surface of the second heat insulating member 124.

Then, the primary membrane 110 is coupled by welding on the primary insulation panel (120).

As such, the present invention does not consist of steel on the top of the heat insulating member of the entire corner portion, but separates the plywood to form the upper and lower surfaces outside the steel, facilitating the process and reducing material costs.

And, the combination of the primary insulation panel with the secondary insulation panel is made through a layer formed with plywood on the upper and lower surfaces, and the position corresponds to the position of the above-mentioned secondary insulation panel coupling means of the primary insulation panel. .

That is, the primary insulation panel coupling hole 128 is formed through the first plywood 126 or the second plywood 127 together with the second heat insulating member 124 and the upper surface plywood 125, 1 As the secondary insulation panel coupling means 332 of the secondary insulation panel 300 described above is coupled to the secondary insulation panel coupling hole 128, the primary insulation panel 120 and the secondary insulation panel 300 are made of stainless steel. Despite the configuration of the material of the secondary membrane 200, easy and efficient physical bonding is possible.

On the other hand, the deformation absorbing space portion 350 may be formed between the inner surface 340 of the corner portion of the secondary insulation panel 300 and the outer surface 129 of the corner portion of the primary insulation panel 120.

That is, as shown in FIGS. 6 to 8, the primary insulation panel 120 is installed parallel to the bottom of the storage tank, and the first insulation member 121, the wood block 122, and the second insulation The first plywood 126 laminated on the lower surface of the member 124 is installed in parallel with the side surface of the storage tank, and the first heat insulating member 121, the wood block 122, and the second heat insulating member 124 It may include a second plywood 127 stacked on the side.

The length P1 of the first plywood 126 and the length P2 of the second plywood 127 are coupled to the first heat insulating member 121, the wood block 122, and the second heat insulating member 124 It is formed shorter than the overall length (L1) of the first plywood ( 126) and the second plywood 127 may be formed in a space where the deformation absorbing space 350 is stacked.

In other words, when the primary insulating panel 120 and the secondary insulating panel 300 are coupled, the corner of the first plywood 126 and the second plywood 127 are not laminated first insulating member 121 The deformation absorbing space portion 350 is formed between the outer surface 129 of the portion and the inner surface 340 of the secondary insulation panel, so that even if hull deformation, that is, hull bending occurs, the primary insulation panel 120 and the secondary insulation Interference due to deformation of the panel 300 can be minimized.

In addition, in general, SUS shrinks by 0.175% when the temperature decreases by 1°C, and Invar shrinks by 0.015% when the temperature decreases by 1°C. Therefore, due to the nature of the storage tank for storing cryogenic liquefied natural gas, most of the components of the insulation system are deformed at cryogenic temperatures. Interference between the primary membrane and the primary region of the primary heat plate and the secondary region of the secondary membrane and secondary insulation panel can be minimized.

The shape of the outer surface of the corner portion of the first heat insulating member 121 may be implemented by various embodiments.

That is, as shown in FIG. 6 , the outer surface 129 of the corner portion of the first heat insulating member 121 may be formed to have a right angle shape. Since this right angle shape may cause interference when the secondary insulation panel touches the corner portion, as another embodiment, as shown in FIGS. 7 and 8, the outer surface of the corner portion of the first insulation panel 121 has a curvature. It may be formed or formed to have a chamfered shape.

As such, the insulation system of the membrane-type storage tank according to the present invention and the membrane-type storage tank including the same have a primary insulation panel and a secondary insulation panel in the corner area of the liquefied natural gas storage tank, which is vulnerable to structural deformation for hull bending. Structural deformation may be minimized by forming a deformation absorbing space between the insulation panels.

In addition, there is an advantage in that a large amount of LNG can be loaded compared to the existing one because the overall weight of the storage tank is reduced by lowering the material use rate by providing an empty space for absorbing deformation.

As described above, although it has been described with reference to the illustrated drawings, the present invention is not limited by the embodiments and drawings described above, and by those skilled in the art to which the present invention belongs within the scope of the claims. Of course, various modifications and variations may be made.

110: primary membrane
120: primary insulation panel
121: first heat insulating member
122: Wood Block
123: first steel plate
124: second heat insulating member
125: top plywood
126: first plywood
127: 2nd ply wood
128: primary insulation panel coupling hole
200: secondary membrane
210: wrinkles
300: secondary insulation panel
310: insulation member
311: third heat insulating member
312: fourth heat insulating member
320: first membrane bonding layer
330: second membrane bonding layer
331: metal strip
332: primary insulation panel coupling means
350: deformation absorbing space

Claims (13)

A secondary insulation panel provided to insulate the interior space of the liquefied natural gas storage tank from the outside and having a bent shape so as to be provided at the corner of the liquefied natural gas storage tank;
A secondary membrane laminated on the secondary insulation panel;
A primary insulation panel laminated on the secondary membrane and having a bent shape to be combined with the secondary insulation panel; and
Including a primary membrane laminated on the primary insulation panel,
A strain absorbing space is formed between the inner surface of the corner portion of the secondary insulation panel and the outer surface of the corner portion of the primary insulation panel,
The primary insulation panel,
A first heat insulating member in a bent form;
Wood blocks installed on both flat sides of the first heat insulating member;
A second heat insulating member coupled to the side of the wood block;
a first plywood installed in parallel with the bottom of the storage tank and stacked on lower surfaces of the first insulating member, the wood block, and the second insulating member; and
It is installed in parallel with the side surface of the storage tank and includes a second plywood stacked on the side surface of the first insulating member, the wood block, and the second insulating member,
The total length (L1) of the combined first heat insulating member, the wood block, and the second heat insulating member is formed longer than the length (P1) of the first plywood and the length (P2) of the second plywood , Insulation system of membrane type storage tank. delete The method of claim 1,
Insulation system of a membrane-type storage tank in which the outer surface of the corner portion of the first insulation member is formed to have a right angle shape. The method of claim 1,
The insulation system of the membrane-type storage tank formed to have a shape obtained by chamfering the outer surface of the corner portion of the first insulation member. The method of claim 1,
The outer surface of the corner portion of the first heat insulating member is formed to have a curvature, the insulation system of the membrane type storage tank. The method of claim 1,
Characterized in that the primary insulation panel is coupled to the secondary insulation panel by inserting the primary insulation panel coupling means provided on the secondary insulation panel into the coupling hole provided in the primary insulation panel, Insulation system for membrane type storage tanks. The method of claim 6,
The secondary insulation panel,
A first membrane bonding layer coupled along the bent edge and provided by assembling a second steel plate on the plywood;
A second membrane bonding layer coupled to the first membrane bonding layer at a distance from each other and having a metal strip formed on the plywood;
The primary insulation panel coupling means is characterized in that mounted on a metal strip formed on the secondary membrane bonding layer of the secondary insulation panel, the insulation system of the membrane-type storage tank. The method of claim 7,
The insulation system of the membrane-type storage tank, characterized in that the secondary membrane is welded to the metal strip of the first membrane bonding layer and the second membrane bonding layer. The method of claim 1,
The primary insulation panel,
a first steel plate laminated on upper surfaces of the first insulating member and the wood block; and
Insulation system of a membrane-type storage tank further comprising an upper surface plywood laminated on the upper surface of the second heat insulating member. The method of claim 9,
A plurality of stud bolts are formed on both sides of the first steel plate,
The plurality of stud bolts are inserted into a plurality of bolt coupling holes formed in the wood block, so that the first steel plate and the wood block are coupled. The method of claim 1,
A groove is formed on the lower surface of the first heat insulating member and the wood block, and one groove formed on the first heat insulating member and one groove formed on the wood block form one coupling groove,
The insulation system for a membrane-type storage tank, characterized in that the first insulation member and the wood block are fixedly coupled by inserting a block-shaped coupling key into the coupling groove. The method of claim 1,
A secondary insulation panel coupling hole is formed through the second insulation member and the plywood bonded to the upper and lower surfaces of the second insulation member,
The insulation of the membrane-type storage tank, characterized in that the primary insulation panel and the secondary insulation panel are coupled by connecting the primary insulation panel coupling means formed in the secondary insulation panel to the secondary insulation panel coupling hole. system. A membrane type storage tank comprising the insulation system according to any one of claims 1 and 3 to 12.

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