KR20120057529A - Liquefied gas storage tank - Google Patents

Abstract

PURPOSE: A liquefied gas storage tank is provided to doubly prevent leakage of liquefied gas by sealing and insulating walls attached in an inner wall of a storage tank. CONSTITUTION: A liquefied gas storage tank comprises a tank body, a cover, an insulating wall(20), and a sealing wall. The insulating wall comprises multiple secondary insulating panels, multiple primary insulating panels, and a secondary gap. The secondary insulating panels are arranged on an inner surface of the tank body of a storage tank. The primary insulating panels are arranged on the secondary insulating panels. The secondary gap is formed between the secondary insulating panels and is covered by the primary insulating panels. Charging holes(21b) are formed on the primary insulating panels. The secondary gap is filled with insulating substance through the charging holes.

Description

LIQUEFIED GAS STORAGE TANK}

The present invention relates to an onshore liquefied gas storage tank, and more particularly, to prevent the leakage of liquefied gas by a sealing and insulating wall attached to a wall of the storage tank so that an additional secondary barrier is not required to be installed outside the storage tank. It relates to a liquefied gas storage tank for land that can be prevented double.

In general, the land liquefied gas storage tank is used to store a variety of liquefied gas, such as liquefied oxygen, liquefied nitrogen, as well as liquefied gas for fuel such as liquefied natural gas (LNG), liquefied petroleum gas (LPG), roughly bottom It has a flat cylindrical shape. The structure of such a cylindrical land liquefied gas storage tank is disclosed in French Patent No. 2398961 and Japanese Patent Laid-Open No. 9-126393.

1 shows an example of a land liquefied gas storage tank according to the prior art. As shown in FIG. 1, the land liquefied gas storage tank is formed by pouring concrete on the foundation 1 to form a cylindrical tank body 3 having a cover of a substantially dome shape.

An insulating wall 4 is installed inside the tank body 3 made of concrete, and a sealing wall 5 capable of accommodating the liquefied gas in a cryogenic state in a sealed state is sequentially provided inside the insulating wall 4. Lamination is installed.

Since the sealing wall 5 is a portion where the liquefied gas is in direct contact, the sealing wall 5 is made of a material such as stainless steel that can withstand cryogenic temperatures.

However, the conventional land liquefied gas storage tank configured in this way, even if the tank body 3 of the storage tank is damaged and accidental liquefied gas leakage accident occurs, the storage tank can be limited to the minimum, It was necessary to form a circular wall 7 on the outside. As a result, the area occupied by the storage tank is increased, so that the cost of securing the land is increased, and a lot of materials and costs are consumed in the construction of the circular wall 7.

The present invention for solving these problems, it is possible to prevent the leakage of the liquefied gas by the sealing and insulating wall attached to the inside of the storage tank of the storage tank so that there is no need to install an additional secondary barrier to the outside of the storage tank. It is to provide a liquefied gas storage tank for land.

According to an aspect of the present invention for achieving the above object, a tank body formed of concrete on the foundation, a cover for covering the tank body, a heat insulation wall installed in the tank body, and installed in the heat insulation wall And a sealing wall configured to receive the liquefied gas in a cryogenic state in a sealed state, wherein in the land liquefied gas storage tank for storing liquefied gas on land, the heat insulation wall is formed of the tank body of the storage tank. A plurality of secondary insulating panels disposed on the inner surface; A plurality of primary insulation panels disposed on the secondary insulation panels; A secondary gap formed between the secondary insulation panels and covered by the primary insulation panels; The primary insulating panel is provided with a land liquefied gas storage tank, characterized in that the filling hole is formed to penetrate through the position where the secondary gap is formed in order to inject the insulating material in the secondary gap. .

The heat insulation wall preferably includes a primary gap formed between the primary heat insulation panels.

Insulating material is preferably inserted into the primary gap.

The heat insulation wall preferably includes a glass cloth interposed between the primary heat insulation panel and the secondary heat insulation panel.

Preferably, the primary insulation panel and the secondary insulation panel are disposed so that the primary gap and the secondary gap are formed at different positions.

Preferably, the insulating material injected into the secondary gap through the filling hole is foamed in the secondary gap so that the secondary insulating panels are integrated with each other.

Insulating material injected into the secondary gap is preferably foamed directly at the construction site of the storage tank.

Preferably, the insulating material and the secondary insulating panel injected into the secondary gap and foam-molded are the same material, and the insulating material and the secondary insulating panel are polyurethane foam.

According to the present invention as described above, there is provided a land liquefied gas storage tank that can prevent the leakage of liquefied gas double by the sealing and insulating wall attached to the wall of the storage tank.

Accordingly, according to the land liquefied gas storage tank of the present invention, since there is no need to install an additional secondary barrier outside the storage tank, the space occupied by one storage tank can be reduced and more storage tanks can be stored in the same space. The construction can be advantageous to reduce the construction cost, it is possible to reduce the cost, time and effort required for the construction of the storage tank compared to the conventional.

1 is a view showing an example of a land liquefied gas storage tank manufactured according to the prior art,
2 is a partial plan view of a double barrier of the land liquefied gas storage tank according to the present invention,
3 is a partial cross-sectional view of the double barrier taken along line AA of FIG. 2, and
FIG. 4 is an enlarged view of a main part of FIG. 3 and illustrates an operation of the adhesive material applied to the sidewall surface of the secondary insulation panel.

Hereinafter, with reference to the accompanying drawings will be described in detail a land liquefied gas storage tank according to the present invention.

2 shows a partial plan view of the double barrier of the liquefied gas storage tank for land according to the present invention, and FIG. 3 shows a partial cross-sectional view of the double barrier taken along the line A-A of FIG.

As shown in Figures 2 and 3, the double barrier of the land liquefied gas storage tank according to the present invention, the sealing wall 10 as a primary barrier directly contacting the liquefied gas contained in the storage tank, and the storage tank It is installed between the tank body 3 and the sealing wall 10 of the tank to prevent heat transfer from the outside of the tank and at the same time includes a heat insulating wall 20 as a secondary barrier to prevent the leakage of liquefied gas.

The sealing wall 10 as a primary barrier is continuously formed by metal materials, such as SUS, which can withstand the cryogenic temperature of liquefied gas. In order to absorb the heat deformation when the liquefied gas is accommodated in the storage tank, it is preferable that the pleats 11 are formed in the sealing wall 10.

According to the present invention, the heat insulation wall 20 as the secondary barrier is composed of the primary heat insulation panel 21 disposed on the outer side of the sealing wall 10 (that is, the side opposite to the surface where the liquefied gas contacts), and the tank body 3. It includes a secondary insulating panel 25 disposed on). In the present specification, the inside or the inside means a direction toward the inner space of the storage tank in which the liquefied gas is accommodated, and the outside or the outside means the opposite direction.

The primary heat insulating panel 21 and the secondary heat insulating panel 25 may be made of a heat insulating material such as polyurethane foam or reinforced polyurethane foam, for example, and an inner surface of the primary heat insulating panel 21 (that is, a sealing wall). Surfaces facing the outer surface of (10) and the outer surface of the secondary insulation panel 25 (that is, the surface facing the inner surface of the tank body 3), for example, a protective layer 21a of plywood or metal material (A protective layer 21a is shown only on the inner surface of the primary thermal insulation panel 21.).

For example, a glass cloth 29 may be interposed between the primary insulation panel 21 and the secondary insulation panel 25. The glass cloth 29 may be attached to the heat insulation panel by PU bonding.

A plurality of secondary insulating panels 25 may be stacked on the inner surface of the tank body 3, the tank body 3 for the coupling of the secondary insulating panel 25 to the tank body (3) The anchor member 3a can be installed.

The secondary insulation panel 25 may be disposed to be spaced apart from each other so that a constant secondary gap 26 is formed between another neighboring secondary insulation panel 25. In the secondary gap 26 between the secondary insulation panels 25, as described later, through the filling hole 21b formed in the primary insulation panel 21, the insulation material of the polyurethane foam material directly at the construction site. It can be injected and foam molded. The filling member 27 formed by foaming the insulating material in the secondary gap 26 is leaked out of the tank of the liquefied gas through the insulating wall 20 even if the sealing wall 10 is broken and the liquefied gas leaks. To prevent the insulation wall 20 to function as a secondary barrier.

The primary insulation panel 21 is stacked inside the secondary insulation panel 25. Like the secondary insulation panel 25, the primary insulation panel 21 is adjacent to another neighboring primary insulation panel 21. It may be arranged to be spaced apart from each other so that a constant primary gap 22 is formed between. In the primary gap 22 between the primary insulation panels 21, for example, a heat insulating material 23 made of glass wool may be interposed.

Meanwhile, the secondary gap 26 between the secondary insulation panels 25 and the primary gap 22 between the primary insulation panels 21 may be formed at different positions as shown in FIG. 3. It is preferable to arrange the primary insulation panel 21 and the secondary insulation panel 25 so as to.

As shown in FIG. 2, in order to form the filling member 27 by injection molding a polyurethane insulating material into the secondary gap 26 between the secondary insulating panels 25, as shown in FIG. A plurality of filling holes 21b are formed through the primary insulation panel 21 at regular intervals along the gap 26.

When foaming the filling member 27 by injecting the insulating material into the secondary gap 26, the secondary gap (2) is formed through another filling hole 21b near one filling hole 21b for injecting the insulating material. It is possible to check the progress of the charging in 26).

As described above, in the secondary gap 26 between the secondary insulation panels 25, the polyurethane foam material is directly insulated at the construction site through the filling hole 21b formed in the primary insulation panel 21. The material can be injected and foam molded. At this time, as shown in (b) of Figure 4 by applying the adhesive material 25b to the side wall surface 25a of the secondary insulating panel 25, the filling member 21b formed by foam molding is the secondary insulating panel ( It is preferable to be able to be in close contact with the side wall surface 25a of 25).

FIG. 4A illustrates a process in which a heat insulating material is injected and foam-molded when no treatment is performed on the sidewall surface 25a of the secondary heat insulation panel 25. In FIG. 4B, When the adhesive material is applied to the side wall surface 25a of the secondary insulation panel 25, a process of injecting and foaming the insulation material is illustrated.

In general, as the secondary insulation panel 25, a panel made of a polyurethane foam material cut into a predetermined size after foam molding at a factory may be used. Since the side wall surface 25a of the secondary insulation panel is not smooth, when the foam molding is performed by injecting a heat insulating material without performing any treatment on the side wall surface, the concave portion of the rugged side wall surface 25a is insulated. There is a fear that the adhesive strength between the secondary insulation panel 25 and the foam-formed filling member 27, ie, the insulation material, may not be completely filled with the material.

In addition, since the surface of the side wall surface 25a is rough, resistance to the flow of the insulating material to be injected is high, and thus, the injection speed of the insulating material may be slowed down. If the injection of the insulating material takes a long time, it is not preferable because foaming may proceed excessively or foaming may be completed during the injection.

In addition, when the height increase rate of the heat insulating material near the side wall surface 25a is slower than the central portion of the secondary gap 26, as indicated by the dotted line, the inside of the secondary gap 26 may be incompletely filled. . At the same time, when the foaming of the insulating material is performed, the lower part has a high density, and thus, the lower part has a low density, and the upper part has a low density, which causes relatively low density and coarse foaming.

As shown in FIG. 4B, when the adhesive material is applied to the sidewall surface 25a of the secondary insulation panel 25, the sidewall surface 25a is smooth, and thus the secondary insulation panel 25 and the secondary insulation panel 25 are smooth. The adhesive strength between the foamed molded member 27, that is, the heat insulating material may be improved, and the secondary heat insulating panel 25 and the filling member 27 may be integrated.

In addition, since the surface of the side wall surface 25a is smooth, there is no resistance to the flow of the insulating material to be injected, so that the insulating material can be injected quickly. Therefore, there is no fear that foaming proceeds excessively or foam molding is completed during the injection of the insulating material, and good injection and foam molding operations can be performed.

In addition, as indicated by the dotted line, since the height increase rate of the heat insulating material near the center of the secondary gap 26 and the side wall surface 25a is the same or similar, the inside of the secondary gap 26 may be completely filled. With this, when the foaming of the insulating material is made, the density of the bottom and the top is the same or similar, so that uniform foaming can be achieved.

When the sealing wall 10 serving as the primary barrier is broken and the liquefied gas leaks, the leaked liquid is the gap between the primary gap 22 and the primary insulation panel 21 and the secondary insulation panel 25. Can flow into the secondary gap 26. However, since the temperature around the secondary insulation panel 25 is higher than the liquefaction point of the liquefied gas, the leaked liquid flowing into the secondary gap 26 is vaporized, thereby increasing the pressure in the secondary gap 26. Since the secondary gap 26 is a space closed by the primary insulation panel 21, the secondary insulation panel 25, and the tank body 3, the secondary gap 26 increases when the pressure in the secondary gap 26 rises. The flow of leaking liquid flowing into (26) can be suppressed.

In this way, even if a leak occurs and the leak liquid flows into the secondary gap 26, the leak liquid can be prevented from continuously flowing due to the pressure rise due to the vaporization of the leaked liquefied gas, and as a result, heat insulation The wall can serve as a secondary barrier.

According to the present invention as described above, in constructing one of the two insulating layers (that is, the secondary insulating layer in close proximity to the concrete tank body with a small temperature change), each of the insulating panels (that is, secondary) Between the insulation panel), the same material as the insulation panel is foam-molded at the construction site, so that the insulation panel and the insulation panel are integrated with each other, and the insulation panel and the concrete wall (that is, the tank body) can be integrated with each other. Accordingly, the integrated insulation panel and the insulation panel, and the integrated insulation panel and the concrete wall serve as secondary barriers to prevent the leakage of liquefied gas.

Furthermore, even if a crack occurs in the secondary barrier, leakage of the liquefied gas may be limited because the insulating wall (ie, the secondary insulating layer) is integrated with the concrete wall, and the leaked liquid is liquefied because the temperature of the concrete wall is higher than the liquefied point. As the gas evaporates, the pressure at the point of cracking increases, which can prevent further liquefied gas leakage. As a result, the low temperature does not propagate, thereby preventing damage to the storage tank.

As described above, the bonding between the secondary insulation panels is performed by foaming the same material as the secondary insulation panels at the construction site, and using an adhesive or the like to prevent cracking at the interface between the foamed insulation material and the insulation panel. It is preferable to apply | coat to the side of the.

As described above with reference to the accompanying drawings, a land liquefied gas storage tank according to the present invention, the present invention is not limited by the embodiments and drawings described above, the present invention within the claims Of course, various modifications and variations can be made by those skilled in the art.

3: tank body 3a: anchor member
10 sealing wall 11: wrinkles
20: insulation wall 21: primary insulation panel
21a: protective layer 21b: charging hole
22: primary gap 23: insulation
25: secondary insulation panel 25a: side wall surface of the secondary insulation panel
25b: adhesive material 26: secondary gap
27: filling member

Claims (9)

A tank body formed of concrete on a foundation, a cover for covering the tank body, a heat insulation wall installed inside the tank body, and installed inside the heat insulation wall to accommodate the liquefied gas in a cryogenic state in a sealed state. In the land liquefied gas storage tank for storing the liquefied gas in the land, comprising a sealing wall,
The heat insulation wall,
A plurality of secondary insulation panels disposed on an inner surface of the tank body of the storage tank;
A plurality of primary insulation panels disposed on the secondary insulation panels;
A secondary gap formed between the secondary insulation panels and covered by the primary insulation panels; Including;
The primary insulating panel is a liquefied gas storage tank for the land, characterized in that the filling hole is formed to penetrate through the position where the secondary gap is formed in order to inject the insulating material in the secondary gap. The method according to claim 1,
The insulation wall, the land liquefied gas storage tank, characterized in that it comprises a primary gap formed between the primary insulation panels. The method according to claim 2,
Onshore liquefied gas storage tank, characterized in that the insulating material is inserted in the primary gap. The method according to claim 1,
The insulating wall, the land liquefied gas storage tank, characterized in that it comprises a glass cloth (glass cloth) interposed between the primary insulation panel and the secondary insulation panel. The method according to claim 2,
And the primary insulation panel and the secondary insulation panel are disposed so that the primary gap and the secondary gap can be formed at different positions from each other. The method according to claim 5,
The insulating material injected into the secondary gap through the filling hole is foamed in the secondary gap, so that the secondary insulating panels are integrated with each other. The method according to claim 1,
The insulating material injected into the secondary gap is a land-based liquefied gas storage tank, characterized in that the foam directly molded at the construction site of the storage tank. The method according to claim 1,
Insulating liquefied gas storage tank for land, characterized in that the insulating material and the secondary insulating panel injected into the secondary gap and the foam molding is the same material. The method according to claim 8,
The insulating material and the secondary insulating panel is a liquefied gas storage tank for land, characterized in that the polyurethane foam.

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