KR20180106682A - Double storage tank of liquefied gas - Google Patents

Abstract

The present invention provides a double storage tank of liquefied gas. According to an embodiment of the present invention, the double storage tank of liquefied gas comprises: an internal shell in which gas is stored; an external shell surrounding and supporting the internal shell; and a support unit arranged between the internal shell and the external shell, mutually supporting the internal shell and the external shell, and having at least a portion that is made of an elastic material.

Description

{DOUBLE STORAGE TANK OF LIQUEFIED GAS}

The present invention relates to a dual storage tank for liquefied gas, and more particularly, to a supporting device for supporting between an inner shell and an outer shell of a storage tank for storing and transporting liquefied gas, so that a thermal stress generated by a cryogenic liquefied gas To prevent the inner shell from shrinking due to the rolling of the ship and to absorb the shock applied to the inner shell due to the rolling of the ship, thereby maintaining the safety of the liquefied natural gas storage tank according to the long- .

In general, natural gas is transported in a gaseous state via land or sea gas pipelines, or transported to a remote location where it is stored in an LNG carrier in the form of liquefied natural gas (LNG). Liquefied natural gas is obtained by cooling natural gas at a cryogenic temperature (approximately -163 ° C) and is very suitable for long haul through the sea because its volume is reduced to approximately 1/600 of that of natural gas.

An LNG carrier that carries LNG to the sea and carries LNG carriers for unloading LNG to the land area, or an LNG carrier that carries the LNG to the sea and reloads the LNG stored after arriving at the land- , The LNG tank is used as a fuel. Natural gas may be used as a fuel even in the case of a ship having a DFDE or ME-GI engine as well as an LNG carrier.

LNG-fueled vessels are considered to be eco-friendly marine transportation vehicles because they can reduce fuel costs compared to ships using petroleum-based fuels and have less emissions of air pollutants such as nitrogen oxides and sulfur oxides. Supply is rapidly spreading thanks to the reduction of greenhouse gas emissions.

When LNG is used as a fuel for a long time, the amount of LNG vaporized depends on the insulation performance of the fuel tank. In order to maintain the cryogenic condition of the LNG for a long time by improving the insulation performance of such a fuel tank, a double shell structure which is insulated by vacuum and perlite is used.

In the case of a double shell, it consists of an inner tank for storing LNG, an insulating layer composed of perlite and a vacuum layer, and an outer tank for supporting the insulating layer. Stainless steel and 9% nickel steel which hardly inflate by heat from the cryogenic temperature (less than about -163 ℃) to the room temperature and above are mainly used. In order to fix mutually separate inner tank and outer tank, And a method of fixing the interposed supports to each other using bolts is adopted.

However, when the inner tank is assembled with the inner tank using the bolts as described above, when the LNG head pressure and the thermal stress are applied to the upper surface of the inner wall of the inner tank, the heat insulating material having a relatively low rigidity is contracted and deformed There is a problem that the bolt having small shrinkage deformation is loosened in the initial assembled state or the nut is separated from the bolt fastening plate, so that the fastening force between the inner tub and the outer tub is lost.

In addition, in the case of a bolt-type fixing type support, a shear force is applied to a support for supporting an inner wall and an outer wall of a gas storage tank, which is a double partition wall, There is a problem that the ground bolt breaks without being able to overcome such shear force.

In order to solve the problems of the prior art, the present invention provides a support device for supporting between an inner shell and an outer shell of a storage tank for storing and transporting liquefied gas, so that contraction of an inner shell due to thermal stress generated by a cryogenic liquefied gas And to provide a dual storage tank for liquefied natural gas which maintains the safety of the liquefied natural gas storage tank due to long-term vessel navigation by absorbing the impact applied to the inner shell according to the occurrence of rolling of the ship.

According to an embodiment of the present invention, there is provided a dual storage tank for liquefied gas, comprising: an inner shell in which gas is stored; An outer shell surrounding and supporting the inner shell; And a support unit disposed between the inner shell and the outer shell and mutually supporting the inner shell and the outer shell, wherein at least a portion of the inner shell and the outer shell are made of an elastic material.

The supporting unit may further include a heat insulating block which is in close contact with the inner shell to insulate the inner shell and the outer shell from each other and a heat insulating block which supports the heat insulating block between the outer shell and the heat insulating block, And a heat insulating block support portion made of an elastic material absorbing the impact.

Further, an edge of the heat block supporting portion is formed with an inclined surface.

The heat block support portion includes an inner contact surface formed in a shape corresponding to an arc of the inner shell and an outer contact surface formed in a shape corresponding to an arc shape of the outer shell and capable of contacting the outer shell.

In addition, the heat block supporting portion is characterized in that when the inner shell is thermally shrunk and deformed by gas, the heat block block is elastically deformed.

Further, a reinforcing plate is provided between the inner shell and the heat insulating block supporting portion, one surface of which is fixed to the inner shell and the other surface is in close contact with the heat insulating block.

Further, the reinforcing plate and the heat insulating block are not bonded to each other.

Further, the heat insulating block is made of wood or a fiber reinforced plastic (FRP) material.

The support unit includes an elastic material stopper which surrounds a part of the heat insulating block supporting part and which is integrally movable with the heat insulating block supporting part.

Further, the heat insulating block support portion and the outer shell are not bonded to each other, and the heat insulating block support portion is fixed by the stopper.

The support unit includes a fixed support having one side fixed to the inner surface of the outer shell and a receiving groove capable of receiving the heat insulating block support and the stopper.

In addition, the apparatus further includes a rib for reinforcing the fixed support portion, wherein one side of the rib is attached to the inner surface of the outer shell, and the other side is attached to the fixed support portion.

Further, the stopper has a height lower than a height from the inner surface of the outer shell to the fixed support portion.

Further, the support unit is disposed at a plurality of circumferentially spaced-apart portions between the inner shell and the outer shell.

Further, on the bottom surface of the outer shell and the inner shell, a supporter for supporting a load applied in the gravity direction is provided.

The supporter may further include: a fixed supporter for fixing the outer shell and the inner shell to the hull; and a sliding supporter for supporting the inner shell to be slidable with respect to the outer shell, wherein the fixed supporter and the sliding supporter, Is formed of a non-elastic material.

A dual storage tank for liquefied gas according to an embodiment of the present invention includes a tank unit including an inner shell for storing gas and an outer shell for enclosing the inner shell with a heat insulating layer interposed therebetween; And a support unit provided on the heat insulating layer to mutually support the inner shell and the outer shell, the support unit comprising: a heat insulating block for insulating the inner shell and the outer shell; A heat-insulating block support member of an elastic material for supporting the heat-insulating block between the outer shell and the heat-insulating block and absorbing an impact applied to the inner shell; A stopper of an elastic material acting as an integral part of the heat insulating block support; And a fixing support for fixing the heat insulating block support and the stopper.

Further, the support unit is disposed at a plurality of circumferentially spaced-apart portions between the inner shell and the outer shell.

In addition, a supporter for supporting a load applied in the gravity direction is provided on the bottom surface of the tank unit.

The supporter may include a fixed supporter for fixing the tank unit to the hull and a sliding supporter for supporting the inner shell so as to be slidable with respect to the outer shell, wherein the fixed supporter and the sliding supporter are non-elastic .

Further, an edge of the heat block supporting portion is formed with an inclined surface.

The heat block support portion includes an inner contact surface formed in a shape corresponding to an arc of the inner shell and an outer contact surface formed in a shape corresponding to an arc shape of the outer shell and capable of contacting the outer shell.

The heat block supporting portion is characterized in that the inner shell is elastically deformed when heat shrinking deformation occurs due to gas.

Further, a reinforcing plate is further provided between the inner shell and the heat insulating block supporting portion, one surface of which is fixed to the inner shell.

Further, one side of the heat insulating block is adhered to the heat insulating block supporting portion, and the other side is in tight contact with the reinforcing plate.

Further, the reinforcing plate and the heat insulating block are not bonded to each other.

The fixed support portion is formed with a receiving groove capable of receiving the heat insulating block support portion and the stopper.

Further, the heat insulating block support portion and the outer shell are not bonded to each other, and the heat insulating block support portion is fixed by the stopper.

In addition, the apparatus further includes a rib for reinforcing the fixed support portion, wherein one side of the rib is attached to the inner surface of the outer shell, and the other side is attached to the fixed support portion.

Further, the stopper has a height lower than a height from the inner surface of the outer shell to the fixed support portion.

According to the present invention, there is provided a support unit for supporting between an outer shell and an inner shell of a storage tank to prevent shrinkage deformation of an inner shell due to thermal stress generated by a cryogenic liquefied gas, Therefore, it is possible to absorb the shock applied to the inner shell and to maintain the safety of the storage tank even when the ship is sailing for a long time.

Also, since the heat insulating block supporting portion for preventing heat from the outside of the storage tank from being transferred to the inner shell is provided as an elastic body, the heat insulating performance and strength can be improved, and the cryogenic fluid can be safely stored for a long time.

In addition, a stopper for restraining the heat insulating block support can be provided to prevent the heat insulating block support from moving even if it is not bonded to the outer shell.

In addition, since the heat insulating block support portion and the stopper are integrally moved during shear deformation, the heat insulating block can be prevented from being detached or damaged.

Further, since the heat insulating block support portion and the stopper are provided as an elastic body, the fluidity is improved with respect to the deformation of the inner shell, so that the problem of rupture due to an increase in stress occurrence at a portion where the fixed support portion and the heat insulating block support portion are in contact with each other can be solved.

1 is a side view of a dual storage tank of a liquefied gas according to an embodiment of the present invention.
2 is a cross-sectional view taken along the line X-X 'in FIG.
FIG. 3 is an enlarged view of the portion 'A' of FIG. 2.
4 is a view showing a heat insulating block support and a heat insulating block of a double storage tank of a liquefied gas according to an embodiment of the present invention.
5 is a view showing a top view of a supporting unit of a double storage tank of a liquefied gas according to an embodiment of the present invention.
6 (a) is a view showing a supporting unit of a double storage tank of liquefied gas according to an embodiment of the present invention.
6 (b) is a view showing a state of the support unit when a cryogenic liquefied gas flows into the inner shell of the double storage tank of the liquefied gas shown in Fig. 6 (a) to cause heat shrinkage deformation.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to such embodiments, and the spirit of the present invention may be proposed differently by adding, modifying and deleting constituent elements constituting the embodiment, .

1 is a side view of a dual storage tank of a liquefied gas according to an embodiment of the present invention.

Referring to FIG. 1, a dual storage tank 1 of liquefied gas according to an embodiment of the present invention may be a double-shell structure storage tank composed of an outer shell 10 and an inner shell 20.

The dual storage tank 1 may store gas such as liquefied natural gas (LNG) or compressed natural gas (CNG) liquefied at a cryogenic temperature of approximately -163 ° C.

The double storage tank 1 may be provided with supporters 40 and 50 which can be coupled with the hull of the ship.

The supporters 40 and 50 may include a sliding supporter 40 for allowing thermal deformation of the inner shell 20 and a fixed supporter 50 for fixing the outer shell 10 and the inner shell 20.

In this embodiment, two sliding supporters 41 and 42 capable of sliding along the transverse direction of the double storage tank 1 are provided and one fixed supporter 50 is provided. 40, and 50 may be installed in various ways.

FIG. 2 is an enlarged cross-sectional view taken along the line X-X 'of FIG. 1, and FIG. 3 is an enlarged view of a portion A of FIG. FIG. 5 is a view showing a top view of a supporting unit of a double storage tank of liquefied gas according to an embodiment of the present invention. FIG. 5 is a view showing a heat insulating block support and a heat insulating block of a dual storage tank.

2 to 5, a dual storage tank 1 for liquefied gas according to an embodiment of the present invention may include an outer shell 10, an inner shell 20, and a support unit 30.

The outer shell 10 may surround the inner shell 20 and be provided to support the inner shell 20. For example, the outer shell 10 may be formed of a stainless steel material to withstand the internal pressure.

Preferably, the outer shell 10 is provided with a stress-resistant steel material capable of withstanding the pressure inside the inner shell 20 since the stress applied from the inner side of the inner shell 20 can be transmitted. .

The inner shell 20 may be formed of a metal material that forms a space for storing gas inside and can withstand the temperature of the liquefied gas stored at a cryogenic temperature.

For example, the inner shell 20 may be formed of a composite material having a low temperature characteristic such as aluminum, stainless steel, 9% nickel steel, or a low-temperature composite material such as a glass-metal reinforced epoxy. In addition, the inner shell 20 may be formed of a metal or a material having a small thermal expansion coefficient in order to reduce the occurrence of stress due to thermal contraction due to cryogenic temperatures.

The supporting unit 30 may be installed between the outer shell 10 and the inner shell 20 in addition to the sliding supporter 40 and the fixed supporter 50. [

The support unit 30 may be provided between the outer shell 10 and the inner shell 20 to support the outer shell 10 and the inner shell 20 mutually.

In other words, the support unit 30 supports between the outer shell 10 and the inner shell 20 to prevent shrinkage deformation due to thermal stress generated by the cryogenic liquefied gas stored in the inner shell 20, It is possible to absorb the impact applied to the inner shell 20 according to the occurrence of rolling of the ship and to maintain the safety of the liquefied gas double storage tank 1 according to the sailing for a long time.

A plurality of support units 30 may be arranged at equal intervals in the circumferential direction between the outer shell 10 and the inner shell 20 (insulating layer), and preferably, each support unit 30 is arranged outside And may be installed at a position where shear deformation occurs between the shell 10 and the inner shell 20. [

In this embodiment, the support unit 30 is installed at four points where shear deformation occurs between the outer shell 10 and the inner shell 20. However, the present invention is not limited thereto and can be variously modified.

More specifically, the support unit 30 may include a heat insulating block support 310, a stopper 320, a heat insulating block 330, and a stationary support 340.

The heat insulating block support 310 may be formed of an elastic material so as to support between the outer shell 10 and the inner shell 20 and absorb the impact applied to the inner shell 20. [ For example, the heat insulating block support 310 may be formed of an elastic body such as rubber, silicon, or the like.

The heat insulating block support 310 can be formed in a substantially rectangular parallelepiped shape and has an inner contact surface 311 formed in a shape corresponding to the arc of the inner shell 20 and a shape corresponding to the arc of the outer shell 10 And an outer contact surface 312 that is in contact with the outer shell 10.

In addition, the heat insulating block 310 may be formed with an inclined surface 313 at an edge portion thereof. For example, when heat shrinkage is generated in the inner shell 20 due to the thermal stress of the cryogenic liquefied gas stored in the inner shell 20, the heat insulating block 310 is elastically moved in the heat shrinking direction of the inner shell 20 . At this time, the inclined surface 313 increases the contact area with which the inner shell 20 is in contact, thereby absorbing the impact applied to the inner shell 20.

Between the inner shell 20 and the heat insulating block support 310, a reinforcing plate 21 and a heat insulating block 330 may be provided. At this time, one surface of the reinforcing plate 21 can be fixed to the inner shell 20.

The heat insulating block 330 may serve to insulate the inner shell 20 and the outer shell 10.

More specifically, the heat insulating block 330 may have an inner surface 331 that is in close contact with the reinforcing plate 21 and an outer surface 332 that is bonded to the inner contact surface 311 of the heat insulating block support 310 . The inner surface 331 may be in contact with the reinforcing plate 21 but not adhered thereto and the outer surface 332 may be adhered to the inner contact surface 311. For example, the outer surface 332 and the inner contact surface 311 may be adhered with an adhesive or the like.

Preferably, the heat insulating block 330 may be formed of a non-elastic material. In one example, the insulating block 330 may be formed of wood or a fiber reinforced plastic (FRP) material.

On the other hand, since the heat-insulating block supporter 310 provided as an elastic body has brittle properties at a low temperature, there is a non-linear unstable problem such as cracking easily. Therefore, the heat insulating block 330 can be attached to the heat insulating block support 310 to prevent the direct influence of the low temperature.

The support unit 30 may include a stopper 320 made of an elastic material and acting as an integral part of the heat insulating block support 310. [ For example, the stopper 320 may be formed of an elastic body such as rubber, silicon, or the like, similar to the heat insulating block support 310.

The support unit 30 is fixed to the inner surface of the outer shell 10 at one side and is fixed to the fixed support 30 at a position where a receiving groove (not shown) capable of receiving the heat insulating block support 310 and the stopper 320 is formed. (340).

The stationary support 340 may include a first stationary plate 341 that is longer than the stopper 320 and a second stationary plate 342 that is the same length as the stopper 320. The first and second fixing plates 341 and 342 may surround the stopper 320. Each of the fixing plates 341 and 342 may be formed with one side of the outer shell 341, (Fixed supporting portion 340) by being fixed to the inner surface of the body 10 by welding or the like.

Meanwhile, the stopper 320 may be formed at a height lower than the height at which the fixed support 340 protrudes from the inner side of the outer shell 10 (see FIG. 3). The stopper 320 restrains the heat insulating block support 310 and prevents direct contact between the fixing support 340 and the heat insulating block support 310. When the heat shrinkage deformation occurs in the inner shell 20 It is possible to eliminate the problem that the heat insulating block supporting portion 310 or the fixing supporting portion 340 is broken due to an increase in stress at a portion where the heat insulating block supporting portion 310 and the fixing supporting portion 340 are in contact with each other.

That is, in the present invention, the stopper 320 is provided between the heat insulating block supporting part 310 and the fixed supporting part 340 to arrest the heat insulating block supporting part 310 and at the same time, There is an advantage that the heat insulating block supporting portion 310 is not detached or damaged from the fixed supporting portion 340.

The heat insulating block support 310 may be such that the inner contact surface 311 can be bonded to the heat insulating block 330 and the outer contact surface 312 is not constrained to the outer shell 10 and any device, have. In other words, the outer contact surface 312 of the heat block supporting portion 310 is not bonded to the outer shell 10 with an adhesive or the like, and can not be moved by the stopper 320.

Meanwhile, a rib 350 for supporting the stationary support part 340 may be coupled to the stationary support part 340.

The rib 350 may be attached to the inner surface of the outer shell 10 at one side and attached to the fixed support 340 at the other side. The ribs 350 may be disposed at predetermined intervals along the circumference of the stationary support 340 and may serve to reinforce the stationary support 340.

Fig. 6 (a) is a view showing a supporting unit of a double-storage tank of a liquefied gas according to an embodiment of the present invention, and Fig. 6 (b) 6 is a view showing a state of a support unit when a cryogenic liquefied gas flows into the support tank and a heat shrinkage deformation occurs. Referring to Fig. 6, the support of the liquefied gas double storage tank 1 according to an embodiment of the present invention The unit 30 can be deformed differently depending on the temperature change of the inner shell 20. [

6 (a)), the heat insulating block support portion 310 of the support unit 30 is not deformed, but remains in its original shape while being held in the outer shell (not shown) 10 and the inner shell 20. As shown in FIG.

If the cryogenic liquefied gas flows into the inner shell 20 (see Fig. 6 (b)), the inner shell 20 may undergo thermal shrinkage deformation due to thermal stress of the cryogenic liquefied gas. At this time, the heat insulating block support 310 may act to elastically move in a direction in which the heat shrinking deformation of the inner shell 20 occurs, and at the same time absorb the impact applied to the inner shell 20.

For example, before the cryogenic liquefied gas flows in, the heat insulating block support 310 can be maintained in a substantially rectangular parallelepipedal shape in its cross section, and when the cryogenic liquefied gas flows into the heat shrinkable deformation, Elastic behavior.

Hereinafter, the operation of the dual storage tank of the liquefied gas according to one embodiment of the present invention will be described.

The dual storage tank 1 of the liquefied gas according to an embodiment of the present invention may be formed in a double shell structure composed of an outer shell 10 and an inner shell 20. [ This double shell structure has an advantage that the inner shell 20, which stores various gases including a cryogenic liquefied gas, is excellent in heat insulation performance.

The outer shell 10 and the inner shell 20 can further improve the heat insulating performance and strength and can prevent thermal shrinkage deformation of the inner shell 20 due to thermal stress generated by the cryogenic liquefied gas. Unit 30 may be installed.

Unlike the conventional heat insulating block, the support unit 30 may include a plurality of heat insulating block supporting portions 310, an elastic material stopper 320, and a heat insulating block 330 ). ≪ / RTI >

Particularly, since the heat insulating block support 310 and the stopper 320 are provided as an elastic body, there is an advantage of solving the problem of rupture due to stress increase when shear deformation occurs.

The heat insulating block support 310 may be bonded to the heat insulating block 330 but may not be moved by the stopper 320 even if the heat insulating block 330 is not bonded to the outer shell 10, 310 and the stopper 320 are integrally moved, the heat insulating block support 310 is not detached or damaged.

Meanwhile, the heat insulating block 330 can prevent the influence of the temperature of the cryogenic liquefied gas adhered to the heat insulating block supporting portion 310 and flowing into the inner shell 20 from being directly applied to the heat insulating block supporting portion 310 .

Thus, the support unit 30 maintains the spacing between the outer shell 10 and the inner shell 20 of the dual storage tank 1 of the liquefied gas for storage and transportation of various gases including cryogenic liquefied gas, There is an advantage that the heat shrinkage deformation of the shell 20 or the impact applied to the inner shell 20 can be absorbed and the safety can be maintained even for a long time while the ship is sailing.

The scope of the present invention is not limited to the above-described embodiments, but may be embodied in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

1 Dual storage tank for liquefied gas
10 outer shell
20 internal shell
21 reinforcing plate
30 support unit
310 Insulation block support
320 stopper
330 Insulation block
340 Fixed Support
350 ribs

Claims (30)

An inner shell in which gas is stored;
An outer shell surrounding and supporting the inner shell; And
A support unit disposed between the inner shell and the outer shell and mutually supporting the inner shell and the outer shell, wherein at least a portion of the inner shell and the outer shell are made of an elastic material;
And a second storage tank for storing the liquefied gas.
The method according to claim 1,
The support unit includes:
A heat insulating block adhered to the inner shell to insulate the inner shell and the outer shell;
And a heat insulating block support portion of an elastic material for supporting the heat insulating block between the outer shell and the heat insulating block and absorbing an impact applied to the inner shell.
3. The method of claim 2,
And a sloped surface is formed at an edge of the heat block supporting portion.
3. The method of claim 2,
The heat block supporting portion includes:
An inner contact surface formed in a shape corresponding to an arc of the inner shell,
And an outer contact surface formed in a shape corresponding to the circular arc shape of the outer shell and capable of contacting the outer shell.
5. The method of claim 4,
The heat block supporting portion includes:
Wherein the inner shell is deformed when heat shrinkage deformation occurs due to the gas.
5. The method of claim 4,
Between the inner shell and the heat insulating block support,
A double storage tank for liquefied gas, comprising: a reinforcing plate having one surface fixed to the inner shell and the other surface closely contacting the heat insulating block.
The method according to claim 6,
Wherein the reinforcing plate and the heat insulating block are not bonded to each other.
8. The method of claim 7,
Wherein the heat insulating block is formed of wood or a fiber reinforced plastic (FRP) material.
3. The method of claim 2,
The support unit includes:
And a stopper of an elastic material which surrounds a part of the heat insulating block supporting part and which integrally moves with the heat insulating block supporting part.
10. The method of claim 9,
Wherein the heat insulating block support portion and the outer shell are not bonded to each other, and the heat insulating block support portion is fixed by the stopper.
10. The method of claim 9,
The support unit includes:
And a stationary support portion having one side fixed to an inner surface of the outer shell and a receiving groove for receiving the heat insulating block support portion and the stopper formed therein.
12. The method of claim 11,
And a rib for reinforcing the fixed support portion,
Wherein the ribs are attached to the inner surface of the outer shell at one side and the other side is attached to the stationary support.
13. The method of claim 12,
Wherein the stopper has a height lower than a height from the inner side surface of the outer shell to the fixed support portion.
The method according to claim 1,
Wherein the support unit is disposed at a plurality of circumferentially spaced apart equally spaced portions between the inner shell and the outer shell.
The method according to claim 1,
And a supporter for supporting a load applied in the gravity direction is provided on the bottom surfaces of the outer shell and the inner shell.
16. The method of claim 15,
The supporter includes:
A fixed supporter for fixing the outer shell and the inner shell to the hull,
And a sliding supporter for slidably supporting the inner shell with respect to the outer shell,
Wherein the fixed supporter and the sliding supporter are formed of a non-elastic material.
A tank unit including an inner shell for storing the gas and an outer shell surrounding the inner shell with a heat insulating layer interposed therebetween; And
A support unit provided in the heat insulating layer and supporting the inner shell and the outer shell mutually;
/ RTI >
The support unit includes:
A heat insulating block for insulating between the inner shell and the outer shell;
A heat-insulating block support member of an elastic material for supporting the heat-insulating block between the outer shell and the heat-insulating block and absorbing an impact applied to the inner shell;
A stopper of an elastic material acting as an integral part of the heat insulating block support; And
A fixing support for fixing the heat insulating block support and the stopper;
And a second storage tank for storing the liquefied gas.
18. The method of claim 17,
Wherein the support unit is disposed at a plurality of circumferentially spaced apart equally spaced portions between the inner shell and the outer shell.
18. The method of claim 17,
And a supporter for supporting a load applied in a gravity direction is provided on a bottom surface of the tank unit.
20. The method of claim 19,
The supporter includes:
A fixed supporter for fixing the tank unit to the hull,
And a sliding supporter for slidably supporting the inner shell with respect to the outer shell,
Wherein the fixed supporter and the sliding supporter are formed of a non-elastic material.
18. The method of claim 17,
And a sloped surface is formed at an edge of the heat block supporting portion.
22. The method of claim 21,
The heat block supporting portion includes:
An inner contact surface formed in a shape corresponding to an arc of the inner shell,
And an outer contact surface formed in a shape corresponding to the circular arc shape of the outer shell and capable of contacting the outer shell.
23. The method of claim 22,
The heat block supporting portion includes:
Wherein the inner shell is elastically deformed when heat shrinking deformation occurs due to gas.
24. The method of claim 23,
Between the inner shell and the heat insulating block support,
And a reinforcing plate having one surface fixed to the inner shell.
25. The method of claim 24,
Wherein the heat insulating block is adhered to one side of the heat insulating block supporting portion and the other side is in close contact with the reinforcing plate.
26. The method of claim 25,
Wherein the reinforcing plate and the heat insulating block are not bonded to each other.
18. The method of claim 17,
Wherein the fixed support portion is formed with a receiving groove capable of receiving the heat insulating block support portion and the stopper.
18. The method of claim 17,
Wherein the heat insulating block support portion and the outer shell are not bonded to each other, and the heat insulating block support portion is fixed by the stopper.
18. The method of claim 17,
And a rib for reinforcing the fixed support portion,
Wherein the ribs are attached to the inner surface of the outer shell at one side and the other side is attached to the stationary support.
18. The method of claim 17,
Wherein the stopper has a height lower than a height from the inner side surface of the outer shell to the fixed support portion.

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