KR20210088832A - Insulation System of Liquefied Gas Storage Tank - Google Patents

Abstract

Disclosed is an insulation system of a liquefied gas storage tank, which can be manufactured at reduced costs. The insulation system of a liquefied gas storage tank according to the present invention comprises: a plurality of insulation panels constituting an insulation wall of the liquefied gas storage tank; a two-way corner panel installed on a two-way corner part on which two inner walls of the liquefied gas storage tank meet at the insulation wall; and a three-way corner panel installed on a 3-way corner part on which three inner walls of the liquefied gas storage tank meet at the insulation wall, wherein a corner part of the three-way corner panel is fixed by a fixing device installed on a lower portion thereof, one corner part disposed to face an inner side of the liquefied gas storage tank is fixed with a fixed point, and the remaining corners facing the inner walls of the liquefied gas storage tank are fixed so that the fixed point is movably fixed within a predetermined area.

Description

Insulation System of Liquefied Gas Storage Tank

The present invention relates to a thermal insulation system for a liquefied gas storage tank having a double barrier structure in which an insulating wall and a sealing wall are sequentially stacked, and more particularly, when constructing a corner insulation system of a liquefied gas storage tank, separate measurement and production are required. It relates to an insulation system of a liquefied gas storage tank that can be installed without a special panel.

Natural gas is transported as gas through land or sea gas pipelines, or stored in LNG carriers as liquefied natural gas (LNG) and transported to remote consumers. LNG is obtained by cooling natural gas to a cryogenic temperature (about -163°C), and its volume is reduced to about 1/600 of that of gaseous natural gas, so it is very suitable for long-distance transportation by sea.

A storage tank (commonly referred to as a 'cargo hold') that can withstand the cryogenic temperature of LNG is installed in a structure for transporting or storing LNG, such as an LNG carrier for loading and unloading LNG to an onshore destination by navigating the sea with LNG.

LNG storage tanks can be classified into independent type storage tanks and membrane type storage tanks depending on whether the load of cargo acts directly on the insulation. In general, the membrane type storage tank is divided into NO 96 type and MARK Ⅲ type of GTT, and the independent storage tank is divided into the MOSS type and IHI-SPB type.

The NO 96 storage tank is equipped with primary and secondary sealing walls made of Invar (36% nickel steel) membrane with a thickness of 0.5 to 0.7 mm, and insulation materials such as perlite powder in a plywood box. It includes primary and secondary insulating walls in which filled insulation boxes are continuously arranged.

In the NO 96 storage tank, the primary sealing wall and the secondary sealing wall have almost the same level of liquid-tightness and strength, so in case of leakage of the primary sealing wall, only the secondary sealing wall can safely support cargo for a considerable period of time. In addition, the NO 96 type storage tank is provided in the form of a thermal insulation wall filled inside a wooden box, so it can have high compressive strength and rigidity compared to the MARK Ⅲ type storage tank, and the welding is easy and the automation rate is high.

The MARK Ⅲ type storage tank has a primary sealing wall made of a stainless steel (SUS) membrane with a thickness of 1.2 mm, a secondary sealing wall made of a triplex, and upper, lower, or upper and lower surfaces of polyurethane foam. It includes primary and secondary insulating walls formed by continuously arranging insulation panels to which wood plywood is adhered.

The primary sealing wall of the MARK Ⅲ storage tank has corrugated corrugations to absorb heat shrinkage caused by LNG in cryogenic conditions, and since these corrugated corrugations absorb the deformation of the membrane, large stress is not generated within the membrane. In addition, the MARK Ⅲ type storage tank has a disadvantage in terms of installation/manufacturing due to the low welding automation rate of the primary sealing wall with corrugation, but compared to the Invar membrane, the stainless steel membrane and triplex are cheaper and easier to construct. Polyurethane foam has an excellent thermal insulation effect.

As such, the membranous storage tank including the NO 96 type storage tank and the MARK Ⅲ type storage tank has a secondary insulating wall, a secondary sealing wall, a primary insulating wall, and 1 from the inner wall of the hull toward the inner space in which the LNG is accommodated. It has a double barrier structure in which the car sealing walls are sequentially stacked.

And it is known that the heat insulation wall of the membranous storage tank is formed by repeatedly arranging components such as an insulation box or insulation panel. ) is called an insulating layer, and the insulating wall composed of insulating panels like a MARK Ⅲ type storage tank is also called a panel type insulating layer.

On the other hand, tolerances occur in the manufacture and installation of components such as insulation boxes or insulation panels constituting the insulation wall, and as a plurality of components are repeatedly arranged, there is a variable space in the corner of the LNG storage tank due to the accumulated tolerance. This happens.

As a method to supplement this, conventionally, an insulation box or insulation panel manufactured in a standard size is installed from the center of the storage tank toward the corner, and then an insulation box or insulation having a special size according to the remaining space in the corner of the storage tank. A separate panel was fabricated and installed.

According to the conventional insulation wall installation process of the LNG storage tank as described above, whenever a standard size insulation box or insulation panel is installed, the space remaining in the corner of the storage tank is measured every time, and a insulation box of a special size suitable for the space is measured. Alternatively, there is a disadvantage of having to manufacture an insulating panel, which increases production and installation costs and delays the production process.

1 is an internal perspective view showing the thermal insulation structure of a conventional NO 96 type storage tank.

1, the conventional NO 96 storage tank has a secondary insulating wall 10, a secondary sealing wall 20, a primary insulating wall 30 and a primary sealing wall 40 are sequentially stacked, The insulation system is constructed. And, as described above, the sealing walls 20 and 40 are made of an Invar membrane, and the heat insulating walls 10 and 30 are composed of a plurality of heat insulating boxes 11 and 31 .

At this time, the insulating walls 10 and 30 and the sealing walls 20 and 40 are heat-shrinked by the LNG in a cryogenic (-163 ℃) state accommodated in the storage tank, and are also subjected to a load due to the deformation of the hull (H).

In particular, since the sealing walls 20 and 40 are formed with a very thin thickness, structural stability must be ensured. For this purpose, in the NO 96 storage tank, the sealing walls 20 and 40 are connected to the inner wall of the hull (H) and have.

Specifically, in the NO 96 storage tank, the sealing walls 20 and 40 are connected to the inner wall of the hull (H) by an invar tube 50 installed at the transverse corner of the storage tank, , various loads applied to the sealing walls 20 and 40 (eg, the load of LNG accommodated in the storage tank, thermal deformation by LNG in a cryogenic state, sloshing load caused by the sloshing phenomenon of LNG, etc.) It is delivered to the tank hull (H) by the invar tube (50).

As shown, the conventional Invar tube 50 installed in the NO 96 type storage tank has a '#'-shaped lattice structure so that the primary sealing wall 40 and the secondary sealing wall 20 are simultaneously connected. However, the conventional Invar tube 50 is not easy to manufacture due to the complicated '#' shape, and the installation of an insulating material for the support of the structure inside the Invar tube 50 and between the Invar tube 50 and the hull H is very difficult. I have a problem that is getting complicated.

On the other hand, in general, in the NO 96 storage tank, the load in the width direction (transverse direction) of the hull is not greater than the load generated in the longitudinal direction (longitudinal direction), so the transverse direction at the longitudinal corner of the storage tank Even structures that are relatively weaker than corners can withstand heat shrinkage loads.

In the conventional NO 96 storage tank, the sealing wall (20, 40) is composed of a plurality of invar strakes (21, 41) extending along the longitudinal direction of the storage tank, invar strakes (21, 41) edge portions of the heat insulating walls 10 and 30 are continuously arranged along the transverse direction of the storage tank by welding to the tongue (tongue) member installed on the top.

At this time, the edges of the invar strakes 21 and 41 welded to the tongue member are provided in a raised edge type so that transverse deformation of the membrane can be allowed by these raised edges, and conventional NO 96 storage In the longitudinal corner of the tank, there is no separate structure for connecting the sealing walls 20 and 40 to the inner wall of the hull (H) like the invar tube 50 .

As described above, the conventional NO 96 storage tank having a structure in which the longitudinal corner portion is relatively weaker than the transverse corner portion is applied without difficulty when the sealing walls 20 and 40 are formed of a plurality of invar strakes 21 and 41. This is possible, but when a membrane of another type is used as the sealing walls 20 and 40, the structure cannot withstand the heat shrinkage load generated in the transverse direction of the storage tank.

The technical problem to be achieved by the present invention is to provide a liquefied gas storage tank of a new structure in which thermal insulation performance and ease of installation are significantly improved compared to the existing ones.

In particular, the present invention enables easy construction regardless of installation and manufacturing tolerances when constructing an insulation system at the corner of a liquefied gas storage tank, thereby simplifying the production process and reducing installation costs, and ultimately economical We want to secure competitiveness in terms of people.

According to an aspect of the present invention for achieving the above object, a plurality of insulation panels constituting the insulation wall of the liquefied gas storage tank; a 2-way corner panel installed in a 2-way corner where two inner walls of the liquefied gas storage tank meet in the insulating wall; and a 3-way corner panel installed in a 3-way corner where the three inner walls of the liquefied gas storage tank meet in the insulating wall. Doedoe, one corner portion disposed toward the inner direction of the liquefied gas storage tank is fixed with a fixed point fixed, and the remaining corner portion facing the inner wall of the liquefied gas storage tank has a fixed point An insulation system of a liquefied gas storage tank can be provided, characterized in that it is movably fixed within a predetermined area.

The 3-way corner panel includes a lower plate; a panel portion disposed on the lower plate and configured by attaching a first upper plate to an upper portion of an insulating material made of a foam insulating material; and a connection part formed in two lateral directions of the panel part on the lower plate, having a 'L'-shaped cross-sectional shape, and configured by coupling a second upper plate to an upper portion of a support block made of hardwood or compressed wood. can do.

The connecting portion may be disposed so that the inner curved surface is disposed in close contact with the panel portion, and the outer curved surface faces the inner wall of the liquefied gas storage tank.

In the panel part, the remaining two lateral edges on which the connection part is not formed are arranged to coincide with the edge part of the lower plate, and the lower plate is partially exposed on the outer side of the connection part and the bent part of the connection part, The exposed portion of the lower plate may be pressed downward by the fixing device to fix the remaining corner portions of the corner panel.

As the exposed portion of the lower plate is provided to have a predetermined area, the fixing point of the fixing device may be movable on the exposed portion of the lower plate.

In the corner panel, a sector-shaped groove portion is formed in a corner portion where the fixing point is fixed, and the lower plate portion exposed according to the formation of the groove portion is pressed downward by the fixing device to form a corner portion of the corner panel. Fixation can be made.

An inclined surface may be formed on the outer curved surface of the connection part in consideration of the angle formed by the inner wall of the liquefied gas storage tank.

The insulation system of the liquefied gas storage tank according to an aspect of the present invention connects the upper surface of the 3-way corner panel respectively disposed on the two inner walls of the liquefied gas storage tank adjacent to each other in the 3-way corner part 2-way corner steel installed to do; and a 3-way corner steel installed to connect all of the upper surfaces of the 3-way corner panels respectively disposed on the three inner walls of the liquefied gas storage tanks adjacent to each other in the 3-way corner part, wherein the connecting part is provided in a form having a reduced height than the panel part, the 3-way corner panel is provided in a stepped form in which the upper surface of the connection part is stepped from the upper surface of the panel part, and the 2-way corner steel has two inner walls where installation is made It is provided in a bent form at an angle corresponding to the angle formed, and both ends are fixed to the upper part of the connection part of the 3-way corner panel respectively disposed on the two inner walls of the liquefied gas storage tank adjacent to each other, and the 3-way corner The steel is provided as a structure in which metal plates having plane directions in three directions are joined to correspond to the 3-way corner part, and each side is disposed on the three inner walls of the liquefied gas storage tank, respectively, the 3-way corner It may be fixed to the upper part of the connection part of the panel.

After the installation of the 2-way corner steel and the 3-way corner steel, a variable plywood processed by measuring the remaining space is placed in the space remaining on the upper part of the connection part, so that the insulation panel and the 3-way corner panel It is possible to compensate for the tolerances resulting from the manufacture and installation of

The variable plywood may have a width corresponding to the distance between the 2-way corner steel and the 3-way corner steel and the panel part, and may have a thickness corresponding to a height difference between the connection part and the panel part.

According to the present invention, by providing a connection structure installed at the corner of the liquefied gas storage tank in order to connect the sealing wall to the inner wall of the hull in a single ten-shape different from the conventional lattice form, the liquefied gas storage tank There is an effect of simplifying the structure of the insulation system built in the corner of the

As described above, the insulation system of the liquefied gas storage tank according to the present invention is easy to manufacture as the shape of the connection structure installed in the corner is simplified, and the installation operation of the insulation material disposed around the connection structure is facilitated, so that the productivity is improved. This has an improved effect.

In addition, according to the present invention, since it is possible to delete a special panel that requires separate measurement and production when constructing an insulating wall in the corner of the liquefied gas storage tank, it has the effect of reducing production costs as well as reducing the number of products, which is positive in terms of production management. effect can be achieved.

In addition, according to the present invention, since the production and installation of the insulating panel constituting the insulating wall of the liquefied gas storage tank and the corner box or corner panel can be made at the same time, the installation process is simplified and workability is greatly improved and the liquefied gas storage tank It has the effect of significantly shortening the drying period of

In addition, the insulation system of the liquefied gas storage tank according to the present invention has the effect of improving the insulation performance because it is possible to configure the insulation wall as a panel-type insulation layer instead of a box-type insulation layer.

On the other hand, even if it is an effect not explicitly mentioned herein, it is added that the effects described in the following specification and their potential effects expected by the technical features of the present invention are treated as if they were described in the specification.

1 is an internal perspective view showing the thermal insulation structure of a conventional NO 96 type storage tank.
Figure 2 is a side cross-sectional view showing the corner portion insulation structure of the liquefied gas storage tank according to the present invention.
3 is an internal perspective view showing the insulating structure of the liquefied gas storage tank according to the present invention, and shows a state in which the installation of the secondary insulating wall is completed.
4 is an internal perspective view showing the insulating structure of the liquefied gas storage tank according to the present invention, and shows a state in which the installation of the secondary insulating wall and the primary insulating wall is completed.
5 is a perspective view showing a 2-way corner panel installed in a 2-way corner where two inner walls meet in a liquefied gas storage tank according to the present invention.
6 is a perspective view showing a 2-way corner steel installed in a connection part of a 2-way corner panel in a liquefied gas storage tank according to the present invention.
7 is a perspective view showing a structure in which a 2-way corner panel is connected in a liquefied gas storage tank according to the present invention.
8 is a perspective view showing a 3-way corner panel installed in a 3-way corner where three inner walls meet in a liquefied gas storage tank according to the present invention.
9 is a perspective view showing the 3-way corner steel installed in the connection part of the 3-way corner panel in the liquefied gas storage tank according to the present invention.
10 is a perspective view showing a structure in which a 3-way corner panel is connected in a liquefied gas storage tank according to the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

In the present invention, the use of the terms 'primary' and 'secondary' refers to whether the function primarily seals or insulates the LNG based on the LNG stored in the storage tank, or the function to secondary seal or insulate the LNG. It is used as a criterion for classification.

Also, the terms 'upper' or 'above', as customarily applied to elements of a tank, refer to the direction towards the inside of the tank, irrespective of the direction to gravity; likewise, the terms 'lower' or 'below' are used to refer to the direction towards gravity. Regardless of the direction, it points toward the outside of the tank.

And in the present specification, the liquefied gas storage tank includes LNG, which is the most representative liquefied gas, LPG (Liquefied petroleum gas), LEG (Liquefied Ethane Gas), liquefied ethylene gas (Liquefied Ethylene Gas), liquefied propylene gas (Liquefied Propylene Gas), etc. It may include all of the storage tanks for storing various types of liquefied gas that can be stored/transported by liquefying it at a low temperature.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

Figure 2 is a side cross-sectional view showing the corner portion insulation structure of the liquefied gas storage tank according to the present invention. And Figures 3 and 4 are internal perspective views showing the insulation structure of the liquefied gas storage tank according to the present invention, respectively, a state in which the installation of the secondary insulating wall is completed, and the state in which the installation of the secondary insulating wall and the primary insulating wall is completed. it has been shown

5 is a perspective view showing a 2-way corner panel installed in a 2-way corner where two inner walls meet in a liquefied gas storage tank according to the present invention, and FIG. 6 is a 2-way corner in a liquefied gas storage tank according to the present invention. It is a perspective view showing the 2-way corner steel installed in the connection part of the panel, and FIG. 7 is a perspective view showing the structure in which the 2-way corner panel is connected in the liquefied gas storage tank according to the present invention.

8 is a perspective view showing a 3-way corner panel installed in a 3-way corner where three inner walls meet in a liquefied gas storage tank according to the present invention, and FIG. 9 is a 3-way corner in a liquefied gas storage tank according to the present invention. It is a perspective view showing the 3-way corner steel installed in the connection part of the panel, and FIG. 10 is a perspective view showing the structure in which the 3-way corner panel is connected in the liquefied gas storage tank according to the present invention.

First, referring to FIG. 2 , the liquefied gas storage tank according to the present invention is a secondary insulating wall 100 disposed on the inner wall of the hull (H), and a secondary sealing wall installed on the second insulating wall 100 . A double barrier in which 200, the primary insulating wall 300 disposed on the secondary sealing wall 200, and the primary sealing wall 400 installed on the first insulating wall 300 are sequentially stacked It can be seen that the structure is

In the present invention, in order to improve the thermal insulation performance of the liquefied gas storage tank, the primary insulating wall 300 and the secondary insulating wall 100 are composed of a panel type insulating layer using foam insulation such as polyurethane foam.

Specifically, the heat insulation walls 300 and 100 may include heat insulation panels 310 and 110 using a foam insulation material and plywood as main members. The insulation panels 310 and 110 are to be provided in the form of a sandwich panel in which plywood is attached to the upper surface, lower surface, or both the upper and lower surfaces of the insulating material made of polyurethane foam (PUF) or reinforced polyurethane foam (R-PUF). can Here, the plywood serves as a protective plate for imparting mechanical rigidity to the insulating panels 310 and 110, and a composite material such as fiber-reinforced plastic may be applied instead of the plywood.

The heat insulating panels 310 and 110 are provided as unit panels in the form of a hexahedron, and a plurality of them are continuously arranged on the inner wall of the storage tank, so that the primary and secondary heat insulating walls 300 and 100 can be configured, respectively.

And in the present invention, both the primary sealing wall 400 and the secondary sealing wall 200 may be provided with a membrane made of a metal material having strong low-temperature brittleness, specifically, Invara stainless steel or high manganese steel. A low-temperature steel such as these can be applied as a material for the membrane.

As described above, in the present invention, the insulating walls 100 and 300 are composed of a panel-type insulating layer, and the primary and secondary sealing walls 400 and 200 are both provided with a metal membrane as a basic structure. In this study, we look at the detailed elements for constructing the insulation system of this structure in more detail.

At the corner of the liquefied gas storage tank according to the present invention, as a structure for connecting the secondary sealing wall 200 to the inner wall of the hull (H), a cross-connector having a cross-sectional shape of a ten (十) shape. ) 500 may be installed.

Unlike the conventional NO 96 type storage tank (see FIG. 1) in which the invar tube 50 is provided in a lattice structure, the cross connector 500 installed in the liquefied gas storage tank according to the present invention is a single ten (十) Only the secondary sealing wall 200 can be connected to the inner wall of the hull (H) provided in a ruler structure.

The cross connector 500 is installed along the inner hull of the hull (H) at the corner of the storage tank, and is respectively connected to the secondary sealing wall 200 installed on the inner wall adjacent to each other and to the secondary sealing wall 200 . It transmits various loads applied to the hull (H).

The cross connector 500 may be made of a structure made of an Invar material, and is welded to a connection member A such as an anchoring bar and fixed to the wall surface of the hull H. The end of the secondary sealing wall 200 is connected to the cross connector 500 by welding.

The cross connector 500, as shown in FIGS. 3 and 4, may be installed in the transverse corner of the storage tank as well as in the longitudinal corner. Here, the transverse corner part includes all areas where the inner wall having the area in the transverse direction from the storage tank, that is, the front wall and the rear wall of the storage tank, meets the neighboring inner wall (side wall, ceiling wall, bottom wall) at an angle. may mean to In addition, the longitudinal corner portion, the inner wall having an area in the longitudinal direction in the storage tank, that is, the ceiling wall and the bottom wall of the storage tank and the inner wall (side wall) and the neighboring inner wall (side wall) at an angle It may mean including all areas that meet. .

That is, in the present invention, the secondary sealing wall 200 has both ends along the longitudinal direction (longitudinal direction) of the hull and both ends along the width direction (transverse direction) of the hull of the hull (H) by the cross connector 500 . ) may be connected to the inner wall, and in the case of the secondary sealing wall 200 installed in the vertical direction, both ends along the height direction may be connected to the inner wall of the hull (H) by the cross connector 500 . However, hereinafter, for convenience of description, the secondary sealing wall 200 installed on the bottom wall of the storage tank will be described as a reference.

As described above, in the present invention, both the load generated in the longitudinal direction of the hull as well as the load generated in the width direction on the secondary sealing wall 200 can be transmitted to the hull (H) through the cross connector (500). , therefore, it is possible to respond to loads generated in all directions even if the secondary sealing wall 200 is not composed of a plurality of invar strikes as in the conventional NO 96 type storage tank.

In the present invention, the secondary sealing wall 200 may be composed of a flat membrane without the need to include corrugations by itself because the load acting on the membrane is transmitted to the hull (H).

When wrinkles are formed in the secondary sealing wall 200 interposed between the secondary insulating wall 100 and the primary insulating wall 300 in the liquefied gas storage tank, interference with the insulating walls 100 and 300 is prevented In order to do this, the installation process may be very complicated because processing must be performed on the upper part of the secondary insulating wall 100 or the lower part of the primary insulating wall 300 . Therefore, the present invention makes it a preferred embodiment to configure the secondary sealing wall 200 as a flat membrane in a flat shape to improve the ease of installation, and stores it as a means for responding to the load applied to the secondary sealing wall 200 . A cross connector 500 for connecting the secondary sealing wall 200 to the inner wall of the hull (H) is provided at the corner of the tank.

On the other hand, since the primary sealing wall 400 is a portion in direct contact with the liquefied gas accommodated in the storage tank, the response to heat shrinkage is more important than the secondary sealing wall 200 . However, considering that only the secondary sealing wall 200 is connected to the above-described cross connector 500, the load acting on the primary sealing wall 400 is difficult to transmit to the hull (H). The sealing wall 400 is preferably provided as a corrugated membrane having a plurality of corrugations to absorb heat shrinkage by itself.

In other words, according to the present invention, the load applied to the secondary sealing wall 200 made of a flat membrane is configured to be transmitted to the hull H through the cross connector 500 , and the load applied to the primary sealing wall 400 . can be configured to be able to respond by absorbing itself from the primary sealing wall 400 side. However, the present invention is not limited or limited thereto, and when a separate device capable of coping with the heat shrinkage of the primary sealing wall 400 is provided at the corner of the storage tank, the primary sealing wall 400 is also flat. It goes without saying that it can be provided as a flat membrane in the form of a flat membrane.

Hereinafter, the structures of the insulating walls 100 and 300 installed in the liquefied gas storage tank according to the present invention will be described in detail with reference to FIGS. 2 to 4 , respectively. For reference, in FIGS. 3 and 4 , the configuration of the sealing walls 200 and 400 is excluded from the illustration in order to show the structure of the heat insulating walls 100 and 300 in more detail.

First, the structure of the secondary insulating wall 100 of the liquefied gas storage tank according to the present invention will be described with reference to FIGS. 2 and 3 .

2 and 3, at the corner of the liquefied gas storage tank according to the present invention, the cross connector 500 is provided in the form of a cross section along the inner hull, that is, the inner wall edge of the storage tank. do.

In addition, a corner support member 510 and a secondary corner box 120 may be installed between the cross connector 500 and the hull H to support the cross connector 500 . The corner support member 510 is disposed in a space closed by the two inner walls of the storage tank and the cross connector 500 , and the secondary corner box 120 is welded by the secondary sealing wall 200 in the cross connector 500 . It is disposed between the end and either inner wall of the storage tank.

The corner support member 510 and the secondary corner box 120 may be provided in the form of an insulating box. Specifically, the corner support member 510 and the secondary corner box 120 are to be provided in a form in which an insulating material such as pearlite powder or glass wool is filled inside a box made of a plywood (or composite material) material. can

However, the present invention is not limited thereto, and when it is determined that sufficient support is possible even with a panel type by structural analysis, the secondary corner box 120 is a composite of polyurethane foam and plywood (or composite material). It may be provided in the form of a laminated insulation panel.

The secondary corner box 120 may be provided in plurality and may be continuously arranged along the corner of the storage tank, and an insulating material such as glass wool is inserted into a gap occurring between the secondary corner boxes 120 adjacent to each other. can be

On the other hand, as the cross connector 500 is installed in both the transverse corner part and the longitudinal corner part of the liquefied gas storage tank according to the present invention, in the 3-way corner part where the three inner walls of the storage tank meet, the transverse side of the storage tank A trihedron 600 may be installed as a structure for connecting the cross connector 500 extending along the directional corner and the cross connector 500 extending along the longitudinal corner of the storage tank.

On the inner wall of the hull (H) of the area except for the corner part of the storage tank, a plurality of secondary insulation panels 110 are continuously arranged in line with the rows.

As described above, the secondary insulation panel 110 may be provided in the form of an insulation panel in which polyurethane foam and plywood (or composite material) are compositely laminated, and an adhesive such as resin or mastic. And it can be fixed to the inner wall of the hull (H) by a stud (stud). Insulation materials, such as glass wool, may be inserted into the gaps generated between the adjacent secondary heat insulating panels 110 .

In the present invention, the secondary insulation panel 110 and the secondary corner box 120 may be manufactured in a predetermined size from the outside and then put into the storage tank to be installed.

A plurality of secondary insulation panels 110 are sequentially installed from the center of the storage tank toward the corner, and in the case of the secondary corner box 120, the secondary insulation panel 110 is installed prior to installation. can be

Accordingly, between the secondary corner box 120 disposed at the corner of the storage tank and the secondary insulating panel 110 disposed adjacently, due to the tolerance occurring during the manufacture and installation of the secondary insulating panel 110, A variable gap arises.

The present invention compensates for the tolerance occurring at the level of the secondary insulating wall 100 as described above by disposing the variable insulating material 130 between the secondary corner box 120 and the secondary insulating panel 110 . can do.

A specific arrangement structure of the variable insulator 130 can be seen in FIG. 2 . The secondary corner box 120 is arranged so that the side is in contact with the cross connector 500, and accordingly, the tolerance resulting from the manufacture and installation of the secondary insulation panels 110 is the secondary corner box 120 and the secondary insulation It becomes a gap between the panels 110 .

The present invention measures the gap between the secondary corner box 120 and the secondary insulating panel 110 after the installation of the secondary corner box 120 and the secondary insulating panel 110 is completed, and measuring the gap between the secondary corner box 120 and the secondary insulating panel 110, The installation tolerance is compensated for by machining the variable insulation 130 with the measured dimensions and placing it in the gap.

In this case, the variable heat insulating material 130 may be formed of a combination of the first variable heat insulating material 131 made of glass wool and the second variable heat insulating material 132 made of polyurethane foam or reinforced polyurethane foam.

The reason why the variable heat insulating material 130 is configured by the combination of the first variable heat insulating material 131 and the second variable heat insulating material 132 as described above is the secondary corner box 120 and the secondary insulating panel ( When 110) contracts, the second corner box 120 and the second corner box 120 and 2 are made possible by the flexible first variable insulation material 131 and by the second variable insulation material 132 with some rigidity. This is to secure support in the gap between the heat insulating panels 110 .

In addition, the present invention installs a connecting bridge 140 between the secondary corner box 120 and the secondary insulation panel 110 adjacent to each other, so that the secondary corner box 120 and the secondary insulation panel 110 are connected to each other. By continuously supporting the secondary sealing wall 200 even in the upper part of the generated gap, stress concentration on the secondary sealing wall 200 in the gap portion caused by the installation tolerance is prevented and structural integrity is secured. can do.

The connection bridge 140 is arranged so that both ends span the step portion formed on the upper edge of the secondary corner box 120 and the secondary insulation panel 110, respectively, and the upper surface of the connection bridge 140 is a corner box ( 120) and the secondary heat insulation panel 110 is formed on the same plane.

According to the present invention as described above, it is possible to collectively manufacture the secondary corner box 120 in the same size regardless of the installation tolerance. In addition, the installation of the secondary corner box 120 is not performed after the installation of the secondary insulation panels 110 is completed, but the installation of the secondary corner box 120 is performed with other secondary insulation panels 110 . It can be done simultaneously or in advance.

That is, according to the present invention, it is possible to eliminate the inefficient process of measuring the space remaining after the installation of the standard size insulating panel is completed and manufacturing and installing the insulating panel of a special size to be arranged in the space as in the prior art. and simply arranging the variable insulation material 130, which is relatively easy to process, between the secondary corner box 120 and the secondary insulation panel 110, it is possible to easily supplement the installation tolerance.

As described above, in the liquefied gas storage tank according to the present invention, the secondary corner box 120 is disposed along the edge of each wall constituting the storage tank, and the secondary corner box 120 is disposed inside. The secondary thermal insulation wall 100 is constituted by the secondary thermal insulation panel 110 . That is, in the present invention, the secondary heat insulating wall 100 may have a structure in which a box-type heat insulating layer disposed in a corner portion and a panel-type heat insulation layer disposed in a region other than the corner portion are mixed.

However, the present invention is not limited thereto, and the structure of the secondary insulating wall 100 may be variously deformed depending on the material and shape of the secondary sealing wall 200 installed on the secondary insulating wall 100 . can

Specifically, if sufficient support is possible even with a panel type by structural analysis, the secondary corner box 120 is provided in the form of an insulating panel in which polyurethane foam and plywood (or composite material) are compositely laminated to form a secondary insulating wall. (100) The whole can be composed of a panel-type insulation layer, and on the contrary, when it is determined that it is necessary to supplement the bearing capacity by structural analysis, the secondary insulation panel 110 is a box provided with a plywood (or composite material) material It is also possible to configure the entire secondary insulation wall 100 as a box-type insulation layer by providing an insulation box filled with an insulation material such as pearlite powder or glass wool therein.

In addition, although it is shown in the drawing that all three wall surfaces of the storage tank meet at an angle of 90°, when a chamfer surface is provided at the corner of the storage tank, the corner structure of the insulation system including the cross connector 500 is Of course, it can be deformed according to the angle formed by the chamfered surface.

Next, a structure of the primary insulating wall 300 installed on the secondary insulating wall 100 in the liquefied gas storage tank according to the present invention will be described with reference to FIGS. 2 to 4 .

In the present invention, since the primary sealing wall 400 installed on the upper portion of the primary insulating wall 300 is in direct contact with the liquefied gas even if it absorbs the heat shrinkage caused by the cryogenic liquefied gas from the wrinkles, the heat shrinkage/relaxation is repeated repeatedly. can happen Therefore, it is preferable that the primary insulating wall 300 supporting the primary sealing wall 400 is composed of a panel-type insulating layer in which polyurethane foam and plywood (or composite material) are compositely laminated as described above.

Specifically, in the present invention, the primary insulating wall 300 is a primary corner panel (320, 320') disposed at the corner of the storage tank, and a primary insulating panel disposed in an area excluding the corner of the storage tank ( 310) may be included.

As described above, the primary thermal insulation panel 310 may be provided in the form of a thermal insulation panel in which polyurethane foam and plywood (or composite material) are compositely laminated, and the second thermal insulation panel 110 is provided on the upper portion. 1 It can be fixed by the fixing device (S1).

The primary thermal insulation panel 310 may be manufactured to have the same length and width as the secondary thermal insulation panel 110 , and each corner portion of the primary thermal insulation panel 310 is disposed at the lower portion of the secondary thermal insulation panel 110 . By being fixed to the center of the primary insulating panel 310 and the secondary insulating panel 110 can be arranged to cross each other.

The first fixing device (S1), a first stud fastened to a base socket fixedly installed on the upper portion of the secondary insulation panel 110, and a first setting plate in the form of a disk fitted to the first stud, and It may include a first fixing nut fastened to the upper end of the first stud for pressing and fixing the first setting plate.

In this case, each corner portion of the four primary heat insulating panels 310 adjacent to each other may be simultaneously fixed to one first fixing device S1. To this end, a groove portion having a sectoral cross-sectional shape with a central angle of 90° may be formed in the four corners of the primary heat insulation panel 310, and the lower plywood (or composite material) exposed by the formation of the groove portion is produced. 1 It can be fixed by being pressed downward by the first setting plate of the fixing device (S1).

On the other hand, in the present invention, the primary corner panels (320, 320') disposed at the corner of the storage tank are easy to connect between the inner walls adjacent to each other in the storage tank, and the manufacture and installation of the primary insulating panels 110 It has a slightly different structure from that of the primary heat insulation panel 110 so that easy construction is possible regardless of tolerances occurring during the operation.

In the present invention, the first corner panel (320, 320') is a 2-way corner panel 320 disposed in a 2-way corner where two inner walls meet in a storage tank, and a 3-way where three inner walls meet in a storage tank It may include a 3-way corner panel 320' disposed at the corner.

First, look at the structure of the 2-way corner panel 320 disposed in the 2-way corner of the storage tank.

Referring to FIG. 5 , the 2-way corner panel 320 includes a lower plate 321 made of plywood (or composite material), a panel portion 322 and a connection portion 323 disposed on the lower plate 321 . ) may be included.

The lower plate 321 provides a space in which the panel part 322 and the connection part 323 are disposed, and may be provided in the form of a plate having a rectangular cross section.

The panel part 322 is made of a heat insulator 322a made of polyurethane foam or reinforced polyurethane foam, and a plywood (or composite material) and a first upper plate 322b attached to the upper portion of the heat insulator 322a. It may be manufactured as a hexahedral panel including, and one edge is disposed to coincide with one edge portion of the lower plate 321 .

The connection part 323 is a support block 323a made of hard wood or compressed wood, and a second upper plate made of plywood (or composite material) and attached or coupled to the upper portion of the support block 323a. (323b). At this time, it is also possible to configure the support block 323a and the second upper plate 323b as an integral member, in this case, it is preferable that the entire configuration is made of hardwood or compressed wood.

One side of the connection part 323 is disposed to be in close contact with the other side of the panel part 322 . In addition, an inclined surface may be formed on the other side of the connection part 323 in consideration of the angle formed by the inner wall of the storage tank. For example, when the inner wall of the storage tank forms an angle of 90°, the inclined surface of the connection part 323 may be formed at an angle of 45° with respect to the horizontal direction. In addition, the lower end of the inclined surface of the connecting portion 323 is disposed to coincide with the other corner portion of the lower plate 321 .

The connection part 323 may have a height reduced by about the thickness of the first upper plate 322b with respect to the panel part 322 , and accordingly, the 2-way corner panel 320 is separated from the upper surface of the panel part 322 . The upper surface of the connection part 323 may be provided in a stepped shape.

In addition, the connecting portion 323 may be provided in a slightly reduced width as compared to the panel portion 322, and accordingly, on both sides of the connecting portion 323 for the width direction in the 2-way corner panel 320, The lower plate 321 may be provided in an exposed state.

In the 2-way corner panel 320 , the panel part 322 is manufactured as a panel type including a foam insulation material in consideration of thermal insulation performance, and the connection part 323 supports the bending load of the primary sealing wall 400 . For this purpose, it can be manufactured using hardwood or compressed wood with high strength. However, when the strength required through structural analysis is not large, it is also possible to manufacture the connection part 323 in a panel type (a form in which polyurethane foam and plywood are compositely laminated).

The 2-way corner panel 320 is, as shown in FIGS. 2 to 4 , the first fixing device S1 and the second fixing device S2 provided on the second corner box 120 above. The corner portion may be fixed by

The second fixing device S2 includes a second stud fastened to a base socket fixedly installed on the upper portion of the secondary corner box 120, a second setting plate in the form of a square plate fitted to the second stud, and a second stud It may include a second fixing nut fastened to the upper end of the pressing and fixing the second setting plate.

In the 2-way corner panel 320, one corner portion may be fixed simultaneously with the corner portion of the adjacent primary heat insulating panel 310 by the first fixing device (S1). To this end, a groove having the same shape as that of the primary heat insulating panel 310 may be formed in two corner portions formed on one side of the 2-way corner panel 320 .

On the other hand, in the 2-way corner panel 320, the other corner part is fixed by the second fixing device S2, at this time both sides of the connection part 323 in the lower plate 321 of the 2-way corner panel 320. The portion exposed to the second fixing device (S2) can be fixed by being pressed downward by the second setting plate.

The 2-way corner panel 320 having the above structure is fixed by the second fixing device S2 while the fixing point fixed by the first fixing device S1 is fixed. The fixing point to be fixed may be freely formed on the lower plate 321 exposed to both sides of the connection part 323 .

That is, in the present invention, the other corner portion of the 2-way corner panel 320 is exposed in a form in which the lower plate 321 extends while having a predetermined length along the longitudinal direction of the panel, even if an installation tolerance occurs 2 It is possible to install while freely forming a fixing point of the other corner portion of the -way corner panel 320 .

Therefore, in the present invention, there is no need to manufacture and install a special size insulation panel to be placed in the corner of the storage tank as in the prior art, and the 2-way corner panel 320 is pre-installed like the rest of the primary insulation panels 310 . After being pre-fabricated from the outside in a predetermined size, it can be put into the storage tank and sequentially installed together with the primary insulation panels 310 .

On the other hand, as the installation of the primary insulation panel 310 and the 2-way corner panel 320 is sequentially made, the corner of the storage tank has the primary insulation panel 310 and the 2-way corner panel 320. Tolerances resulting from manufacturing and installation occur, and these installation tolerances can be supplemented in the following way.

5 to 7, the step surface formed on the upper portion of the 2-way corner panel 320, that is, the upper surface of the connection part 323 is formed in a size sufficient to correspond to the installation tolerance. Here, the sufficient size means a size sufficient to secure an arrangement space of the 2-way corner steel 330, which will be described later, even when the largest installation tolerance occurs.

And, the 2-way corner panel 320 is arranged so that the connecting portion 323 faces the corner of the storage tank, and interconnects the 2-way corner panel 320, which is respectively arranged on two inner walls adjacent to each other in the storage tank. A 2-way corner steel 330 is installed to finish the primary insulating wall 300 .

The 2-way corner steel 330 is provided with a metal plate bent at an angle corresponding to the corner of the storage tank, and both ends of the 2-way corner panel 320 are installed on the inner wall adjacent to each other in the storage tank. The connection part 323 may be fixed to the upper part. Although the drawing shows an embodiment in which the 2-way corner steel 330 is bent at 90°, the corner portion of the storage tank having a chamfered surface may be bent at an angle corresponding to the corner portion.

The 2-way corner steel 330 may include a stiffener formed to protrude downward for the purpose of reinforcing support strength. The stiffener may be made of the same material as the 2-way corner steel 330 and may be connected to the lower surface of the 2-way corner steel 330 by welding, and at least one may be installed at regular intervals. A groove for insertion of a stiffener may be formed in the connection portion 323 of the 2-way corner panel 320 .

As described above, the installation of the 2-way corner panel 320 may be sequentially performed together with the installation of the primary insulation panel 310 on the inner wall of the storage tank. At this time, as shown in (a) of FIG. 7 , the fixing point fixed by the second fixing device S2 in the 2-way corner panel 320 moves freely within the exposed portion of the lower plate 321 ( '↔') is possible.

When the installation of the 2-way corner panel 320 is completed, the 2-way corner steel 330 is installed to connect the 2-way corner panel 320 disposed on the inner wall adjacent to each other. The 2-way corner steel 330 may be fixed to the upper part of the connection part 323 of the 2-way corner panel 320 by a fastening member such as a rivet, a screw, or a bolt.

The 2-way corner steel 330 is manufactured to a predetermined size prior to installation. Therefore, due to the tolerance resulting from the manufacture and installation of the primary insulation panels 310, a space remaining in the step portion formed on the 2-way corner panel 320 may be generated.

As shown in (b) of FIG. 7, the present invention provides a space remaining in the step portion of the 2-way corner panel 320 after the installation of the 2-way corner steel 330, that is, the 2-way corner steel 330. ) and the distance (L1, L2) between the panel part 322 is measured, and the variable plywood 340 is processed with the measured dimensions and placed in the space to compensate for the installation tolerance.

The variable plywood 340 may have the same thickness as the height of the step portion, that is, the first upper plate 322b described above, and may be fixed to the upper surface of the connecting portion 323 by an adhesive.

As such, in the present invention, by processing the variable plywood 340 of a simple structure having a rectangular cross section and arranging it in the remaining space of the step, the tolerance generated at the level of the primary insulating wall 300 can be easily supplemented compared to the prior art have.

The space (E: see FIG. 2) between the 2-way corner panels 320 respectively installed on the inner walls adjacent to each other in the storage tank is left as a void space, or an insulating material such as glass wool is inserted in the space. can be

The end of the primary sealing wall 400 is sealingly connected to the 2-way corner steel 330 by welding. In this case, when the primary sealing wall 400 is made of a pleated membrane including wrinkles, a pleat closing member such as an end cap or an angle piece may be additionally installed for sealing and finishing the pleats. have.

Next, look at the structure of the 3-way corner panel 320' disposed on the 3-way corner of the storage tank.

Referring to Figure 8, the 3-way corner panel 320' is the above-mentioned 2-way corner panel 320, except that the connection part 323' is formed in the two lateral directions of the panel part 322'. It may be provided in a similar structure. That is, in the above-mentioned 2-way corner panel 320, the connection part 323 was formed in only one side direction of the panel part 322, and the 3-way corner panel 320' is the area where the three inner walls of the storage tank meet. Since it is installed on the side, it is formed in the two lateral directions of the panel part 322 ′ corresponding thereto.

Specifically, the 3-way corner panel 320' includes a lower plate 321' made of plywood (or composite material), a panel part 322' disposed on the lower plate 321', and a connection part ( 323').

The lower plate 321 ′ provides a space in which the panel part 322 ′ and the connection part 323 ′ are disposed, and may be provided in the form of a plate having a rectangular cross section.

The panel part 322' is made of a heat insulator 322a' made of polyurethane foam or reinforced polyurethane foam, and a plywood (or composite material) and a first upper plate attached to the upper portion of the heat insulator 322a' ( 322b ′) may be manufactured as a hexahedral panel, and the corners in two directions are arranged to coincide with the corners of the lower plate 321 .

The connection part 323' is a support block 323a' made of hardwood or compressed wood, and a second upper plate made of plywood (or composite material) and attached or coupled to the upper portion of the support block 323a' ( 323b'). At this time, it is also possible to configure the support block 323a' and the second upper plate 323b' as an integral member, in this case, it will be preferable that the entire configuration is made of hardwood or compressed wood.

In the 3-way corner panel 320', the connection part 323' may be formed in two side directions adjacent to each other among the side surfaces of the panel part 322'. That is, the connecting portion 323 ′ may be formed in two directions orthogonal to each other, and thus the cross-section may have a bent shape in a 'L' shape. The connection part 323' is disposed so that the inner curved surface is in close contact with the panel part 322'. In addition, an inclined surface may be formed on the outer curved surface of the connection part 323 ′ in consideration of the angle formed by the inner wall of the storage tank. For example, when the inner wall of the storage tank forms an angle of 90°, the inclined surface of the connection part 323 ′ may be formed at an angle of 45° with respect to the horizontal direction. In addition, the lower end of the inclined surface of the connecting portion 323' is disposed to coincide with the edge of the lower plate 321'.

The connecting portion 323 ′ may have a height reduced by approximately the thickness of the first upper plate 322b ′ with respect to the panel portion 322 ′, and thus the 3-way corner panel 320 ′ is the panel portion 322 . '), the upper surface of the connection part 323' may be provided in a stepped form.

In addition, the lower plate 321' of the 3-way corner panel 320' is provided in a partially exposed state on the outer side of the connection part 323' provided in the 'L' shape, and the connection part 323' is bent. The lower plate 321 ′ may also be provided in a partially exposed state.

In the 3-way corner panel 320', the panel part 322' is manufactured as a panel type including a foam insulation material in consideration of thermal insulation performance, and the connection part 323' is the bending of the primary sealing wall 400'. It can be manufactured using hardwood or compressed wood with high strength to support the load. However, when the strength required through structural analysis is not large, it is also possible to manufacture the connection part 323 ′ in a panel type (a form in which polyurethane foam and plywood are compositely laminated).

The 3-way corner panel 320 ′ is, as shown in FIGS. 2 to 4 , the second fixing device S2 provided on the first fixing device S1 and the second corner box 120 described above. ) can be fixed at the corners.

At this time, the 2-way corner panel 320 has two corner parts fixed by the first fixing device S1, whereas only one corner part of the 3-way corner panel 320' is attached to the first fixing device S1. is fixed by

The portion fixed by the first fixing device S1 in the 3-way corner panel 320 ′ may be fixed simultaneously with the adjacent primary heat insulating panel 310 and the 2-way corner panel 320 . To this end, a groove portion having the same shape as that of the primary heat insulating panel 310 may be formed in the corner portion disposed toward the inner direction of the storage tank in the 3-way corner panel 320 ′.

And, in the 3-way corner panel 320 ', the corner portion disposed in the most corner portion of the storage tank is fixed alone by the second fixing device (S2), and the other two corner portions are the second fixing device (S2). It is fixed at the same time with the adjacent 2-way corner panel 320 by

At this time, in the lower plate 321' of the 3-way corner panel 320', the portion formed to be exposed to the outer part and the bent part of the connecting part 323', respectively, is on the second setting plate of the second fixing device (S2). It can be fixed by being pressed downward by the.

The 3-way corner panel 320 ′ having the above structure is fixed by the first fixing device S1 in a similar principle to the 2-way corner panel 320, while the fixing point is fixed. , the three fixing points fixed by the second fixing device S2 may be freely formed on the lower plate 321 .

That is, in the present invention, the three corner portions of the 3-way corner panel 320 ′ are exposed in a form having an area so that the fixing point of the second fixing device S2 can be moved, and the second setting plate in the form of a square plate ( As the second fixing device) occupies a portion of the area and is fixed, it is possible to freely form and install the fixing points of the three corners of the 3-way corner panel 320' even if there is an installation tolerance.

Therefore, in the present invention, there is no need to manufacture and install a special size insulating panel for arranging the corner of the storage tank as in the prior art, and the 3-way corner panel 320 ′ is used like the other primary insulating panels 310 After being pre-fabricated from the outside in a predetermined size, it can be put into the storage tank and installed together with the primary insulation panels 310 sequentially.

On the other hand, as the primary insulation panel 310 and the 3-way corner panel 320' are sequentially installed, the first insulation panel 310 and the 3-way corner panel 320' are located at the corner of the storage tank. ) occurs in manufacturing and installation, and it is possible to compensate for these installation tolerances in the following way.

8 to 10, the step surface formed on the upper part of the 3-way corner panel 320', that is, the upper surface of the connection part 323', is formed in a size sufficient to correspond to the installation tolerance. Here, the sufficient size means a size sufficient to secure the arrangement space of the 2-way corner steel 330 and the 3-way corner steel 331 to be described later even when the installation tolerance is the largest.

And, the 3-way corner panel 320' is arranged so that the connecting portion 323' faces the corner of the storage tank, and the 3-way corner panel 320' is disposed on three inner walls adjacent to each other in the storage tank The 2-way corner steel 330 and the 3-way corner steel 331 are installed to interconnect the primary insulation wall 300 .

The 2-way corner steel 330 has been described above. The 3-way corner steel 331 may be provided as a structure in which metal plates having plane directions in three directions are joined by welding corresponding to the 3-way corner portion where three inner walls of the storage tank meet. Although the drawing shows an embodiment in which the surface direction of the 3-way corner steel 331 forms 90°, respectively, the corner portion of the storage tank having a chamfered surface may be deformed at an angle corresponding to the corner portion. .

As described above, the 3-way corner panel 320' may be sequentially installed along with the installation of the primary heat insulating panel 310 on the inner wall of the storage tank. At this time, as shown in (a) of FIG. 10, the fixing point fixed by the second fixing device S2 in the 3-way corner panel 320' is within the exposed portion of the lower plate 321'. You can move freely (marked with '↔').

The installation order of the three 3-way corner panels 320' installed in the 3-way corner of the storage tank is not restricted. That is, the 3-way corner panels 320 ′ each having the same structure may be sequentially installed one by one regardless of the order.

When the installation of the 3-way corner panel 320' is completed, the 3-way corner steel 331 is installed to connect between the 3-way corner panels 320' respectively disposed on the three inner walls adjacent to each other, With this, a 2-way corner steel 330 is installed to connect between the 3-way corner panels 320' disposed on two adjacent inner walls. The 2-way corner steel 330 and the 3-way corner steel 331 may be fixed to the upper part of the connection part 323' of the 3-way corner panel 320' by fastening members such as rivets, screws, and bolts. .

The 3-way corner steel 331 may be manufactured in a predetermined size prior to installation like the 2-way corner steel 330 . Therefore, due to the tolerance resulting from the manufacture and installation of the primary insulation panels 310, a space remaining in the step portion formed on the 3-way corner panel 320' may be generated.

As shown in (b) of FIG. 10, the present invention remains in the step portion of the 3-way corner panel 320' after the installation of the 2-way corner steel 330 and the 3-way corner steel 331 By measuring the space, processing the variable plywood 340 with the measured dimensions and arranging it in the space, the installation tolerance is compensated.

That is, as in the 2-way corner panel 320, the tolerance occurring in the 3-way corner of the storage tank is easily supplemented compared to the prior art by arranging the variable plywood 340, which is easy to process, in the space remaining in the step. can do.

The space between the 3-way corner panels 320' respectively installed on the inner walls adjacent to each other in the storage tank may be left as a void space, or an insulating material such as glass wool may be inserted into the space.

The end of the primary sealing wall 400 is sealingly connected to the 3-way corner steel 331 by welding. In this case, when the primary sealing wall 400 is made of a pleated membrane including wrinkles, a pleat closing member such as an end cap or an angle piece may be additionally installed to seal and finish the pleats.

According to the present invention, it is possible to manufacture the primary corner panels 320 and 320' of the same size regardless of the installation tolerance, and the primary corner panels ( Install the corner steels 330 and 331 between 320 and 320', and in the remaining space between the corner steels 330 and 331 and the panel parts 322 and 322' of the primary corner panels 320 and 320'. It is possible to supplement the installation tolerance by a simple method of processing and arranging the variable plywood 340 .

In addition, according to the present invention, after the installation of the primary insulating panels 310 is completed, the primary corner panels 320 and 320 ′ are not installed, but first together with the other primary insulating panels 310 . The installation work of the corner panels 320 and 320' may be sequentially performed.

That is, according to the present invention, it is possible to eliminate the inefficient process of measuring the space remaining after the installation of the standard size insulating panel is completed and manufacturing and installing the insulating panel of a special size to be arranged in the space as in the prior art. Do.

The present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, it should be said that such modifications or variations belong to the claims of the present invention.

100: secondary insulation wall 110: secondary insulation panel
120: secondary corner box 130: variable insulation material
140: connecting bridge
200: secondary sealing wall
300: primary insulation wall 310: primary insulation panel
320, 320': 1st corner panel 321, 321': lower plate
322, 322': panel part 323, 323': connection part
330: 2-way corner steel 331: 3-way corner steel
340: variable plywood
400: primary sealing wall
500: cross connector 510: corner support member
600: trihedron

Claims (10)

A plurality of insulation panels constituting the insulation wall of the liquefied gas storage tank;
a 2-way corner panel installed in a 2-way corner where two inner walls of the liquefied gas storage tank meet in the insulating wall; and
A 3-way corner panel installed in a 3-way corner where three inner walls of the liquefied gas storage tank meet in the insulating wall;
The three-way corner panel has a corner portion fixed by a fixing device installed at the lower portion, and one corner portion disposed toward the inner direction of the liquefied gas storage tank is fixed with a fixed point fixed. and the remaining corner portion facing the inner wall of the liquefied gas storage tank is characterized in that the fixed point is movably fixed within a predetermined area,
Insulation system for liquefied gas storage tanks. The method according to claim 1,
The 3-way corner panel,
lower plate;
a panel portion disposed on the lower plate and configured by attaching a first upper plate to an upper portion of an insulating material made of a foam insulating material; and
It is formed in the two lateral directions of the panel part on the lower plate, has a 'L'-shaped cross-sectional shape, and includes a connection part configured by coupling a second upper plate to an upper portion of a support block made of hardwood or compressed wood ,
Insulation system for liquefied gas storage tanks. 3. The method according to claim 2,
The connection part, characterized in that the inner curved surface is arranged in close contact with the panel portion, the outer curved surface is arranged to face the inner wall of the liquefied gas storage tank,
Insulation system for liquefied gas storage tanks. 4. The method according to claim 3,
In the panel part, the other two lateral edges on which the connection part is not formed are disposed to coincide with the edge parts of the lower plate,
The lower plate is partially exposed on the outer side of the connecting portion and the bent portion of the connecting portion, and the exposed portion of the lower plate is pressed downward by the fixing device to fix the remaining corner portions of the corner panel. characterized by,
Insulation system for liquefied gas storage tanks. 5. The method according to claim 4,
As the exposed portion of the lower plate is provided to have a predetermined area, the fixing point of the fixing device is movable on the exposed portion of the lower plate,
Insulation system for liquefied gas storage tanks. 6. The method of claim 5,
In the corner panel, a sector-shaped groove portion is formed in one corner portion where the fixing point is fixed,
The lower plate portion exposed according to the formation of the groove portion is pressed downward by the fixing device, characterized in that the fixing of one corner portion of the corner panel is made,
Insulation system for liquefied gas storage tanks. 5. The method according to claim 4,
Characterized in that an inclined surface is formed on the outer curved surface of the connection part in consideration of the angle formed by the inner wall of the liquefied gas storage tank,
Insulation system for liquefied gas storage tanks. 5. The method according to claim 4,
2-way corner steel installed to connect the upper surfaces of the 3-way corner panels respectively disposed on the two inner walls of the liquefied gas storage tank adjacent to each other in the 3-way corner part; and
and a 3-way corner steel installed to connect all of the upper surfaces of the 3-way corner panels respectively disposed on the three inner walls of the liquefied gas storage tank adjacent to each other in the 3-way corner part,
The connection part is provided in a form having a height reduced than that of the panel part, and the 3-way corner panel is provided in a form in which the upper surface of the connection part is stepped from the top surface of the panel part,
The 2-way corner steel is provided in a bent form at an angle corresponding to the angle formed by the two inner walls where the installation is made, and both ends of the three-way corner panel are respectively disposed on the two inner walls of the liquefied gas storage tank adjacent to each other is fixed to the upper part of the connection
The 3-way corner steel is provided as a structure in which metal plates having plane directions in three directions are joined to correspond to the 3-way corner part, and each side is disposed on the three inner walls of the liquefied gas storage tank, respectively characterized in that it is fixed to the upper part of the connection part of the 3-way corner panel,
Insulation system for liquefied gas storage tanks. 9. The method of claim 8,
After installation of the 2-way corner steel and the 3-way corner steel, a variable plywood processed by measuring the remaining space is placed in the space remaining on the upper part of the connection part, so that the insulation panel and the 3-way corner panel characterized in that it compensates for tolerances resulting from the manufacture and installation of
Insulation system for liquefied gas storage tanks. 10. The method of claim 9,
The variable plywood has a width corresponding to the distance between the 2-way corner steel and the 3-way corner steel and the panel part, and has a thickness corresponding to the height difference between the connection part and the panel part doing,
Insulation system for liquefied gas storage tanks.

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