KR20200004609A - Liquid hydrogen storage tank for ship - Google Patents

Abstract

Disclosed is a liquefied hydrogen storage tank structure for a ship. The present invention provides a liquefied hydrogen storage tank for a ship, which is provided by a dual structure having an inner wall having a space in which liquefied hydrogen is stored and an outer wall surrounding the inner wall. The liquefied hydrogen storage tank for a ship includes: an insulation unit installed on a space between the inner wall and the outer wall to prevent heat transfer; an inner wall support means supporting the space between the inner wall and the outer wall; and an outer wall support means supporting the entire load of the liquefied hydrogen storage tank by supporting the outer wall. A leakage barrier of which a receiving groove is formed in the center is installed on an inner side surface of the outer wall support means.

Description

Liquefied hydrogen storage tank for ships {LIQUID HYDROGEN STORAGE TANK FOR SHIP}

The present invention relates to a liquefied hydrogen storage tank for ships, and more particularly to a liquefied hydrogen storage tank for ships to minimize the generation and heat loss of the evaporation gas by improving the thermal insulation performance suitable for storing the liquefied hydrogen having a low boiling point characteristics will be.

Recently, due to the rapid development of industrialization and the increase of population, energy demand is continuously increasing, and as a result, the supply and demand of alternative energy due to the depletion of fossil fuel is urgently needed. Energy consumption measures are urgent as it consumes a large amount and relies on foreign imports for more than 90% of the energy used.

Hydrogen fuel is being regarded as an alternative energy that is drawing attention to solve the complex energy problems facing the world.

These hydrogen fuels are not only the most abundant elements on earth after carbon and nitrogen, but they are also a clean energy source that produces only a very small amount of nitrogen oxides during combustion and emits no other pollutants. It can be made from water as a raw material, and can be said to be an optimal alternative energy source without being depleted because it is recycled back to water after use.

The most important task for using such hydrogen fuel is the storage method of hydrogen. As the storage method of hydrogen, a method of compressing and storing hydrogen gas, a method of liquefying and storing, a storage method using a hydrogen storage alloy, and the like are known.

As the hydrogen market grows in the future, large-scale transportation of hydrogen by ships can be achieved, and a method of liquefying and storing hydrogen among the above methods is recognized as a technology suitable for large-scale storage and long-distance transportation of hydrogen.

Currently, the technology for liquefied hydrogen (LH ₂ ) storage tanks storing liquefied hydrogen is mostly for small tanks on land. There is no proven case for the technology of storage and transportation of liquefied hydrogen by ship, and most of them adopt the structure of the existing LNG storage tank or use it slightly modified.

However, since liquefied hydrogen is a lower temperature fluid than liquefied natural gas, a more stringent solution is required than the known liquefied natural gas storage technology.

Liquefied hydrogen has a low boiling point with a liquefaction temperature lower than that of cryogenic liquefied natural gas (-162 ℃) with a liquefaction temperature of -253 ℃. The boil-off rate is 10 times that of liquefied natural gas.

The liquefied hydrogen having this property is more serious than the case of liquefied natural gas because the pressure increase in the storage tank by the boil-off gas (BOG), and the amount of evaporated gas to be released to prevent the pressure increase in the tank Much more massive too. This causes a huge loss of hydrogen energy source.

Therefore, in the long-haul transportation of liquefied hydrogen, it is important to lower the evaporation rate of liquefied hydrogen in order to reduce the loss of hydrogen, and therefore, the liquefied hydrogen storage tank must have better insulation performance than the conventional liquefied natural gas storage tank. .

In addition, liquefied hydrogen has a characteristic of reducing sloshing load and loading load due to its low specific gravity characteristics, and means for ensuring stability when leaking is necessary because it is easy to diffuse and has a wide explosion limit.

The technical problem to be achieved by the present invention is to provide a liquefied hydrogen storage tank for ships to minimize the generation and heat loss of the evaporation gas by improving the thermal insulation to be suitable for storing the liquefied hydrogen having a low boiling point characteristics.

In addition, the present invention efficiently prevents the heat flow through the means for supporting between the inner and outer walls of the liquefied hydrogen storage tank provided in a dual structure, the ship's liquefied hydrogen storage tank that ensures stability even when leakage of liquefied hydrogen To provide.

In order to achieve the above object, the present invention is a marine liquefied hydrogen storage tank provided in a dual structure including an inner wall and the outer wall surrounding the inner wall is formed a space for storing liquefied hydrogen, the inner wall and the An insulation unit installed in the space between the outer walls to block heat transfer; Inner wall supporting means for supporting between the inner wall and the outer wall; And an outer wall supporting means for supporting the entire load of the liquefied hydrogen storage tank by supporting the outer wall, wherein an inner side of the outer wall supporting means is provided with a leak barrier having a receiving groove formed in the center thereof. Provide marine hydrogen storage tanks.

The leak barrier may be made of any one of stainless steel, aluminum and aluminum alloy.

The inner wall support means includes a frame made of plywood; And a heat insulating member provided in the inner space of the frame, wherein the heat insulating member includes an upper heat insulating member made of a rigid foam and a lower heat insulating material made of a non-foamable resin including a vacuum insulation panel (VIP) therein. However, it can be provided in a configuration.

The upper insulation member may be made of rigid polyurethane foam (PUF), and the lower insulation may be made of non-foamable polyurethane (PU).

The inner wall support means may be provided to be narrower from the lower end to the upper end, and installed to support the bottom of the inner wall.

The inner wall support means may further include an elastic member installed on a bottom surface of the inner wall in contact with the outer wall.

The heat insulation portion, a splash shield surrounding the outside of the inner wall; An airgel thin film layer surrounding the splash shield; And a vacuum layer formed between the airgel thin film layer and the outer wall.

The inner wall is made of aluminum or an aluminum alloy, and the splash shield is made of stainless steel, aluminum or aluminum alloy, and includes a continuous corrugation having a corrugated cross section to protect the outer wall from liquefied hydrogen leaked from the inner wall. can do.

The vacuum layer may be filled with pearlite as a core materail.

The liquefied hydrogen storage tank is a cylindrical storage tank, the inner wall support means may be installed to be spaced apart from each other along the longitudinal direction of the liquefied hydrogen storage tank.

In addition, in order to achieve the above object, the present invention, in the marine liquefied hydrogen storage tank having a dual structure including an inner wall and the outer wall surrounding the liquefied hydrogen is stored in the interior, the space between the inner wall and the outer wall In order to maintain the spaced space in which the heat insulation is provided, the inner wall support means for supporting between the inner wall and the outer wall is installed, the inner wall support means, the upper heat insulating material made of a rigid foam in the frame inner space made of plywood and A lower insulation made of a non-foamable resin including a vacuum insulation panel (VIP) is stacked in two stages, and a leakage barrier in which an accommodating groove is formed is formed at an inner side of an outer wall support on which the liquefied hydrogen storage tank is seated. It is characterized by being installed.

The present invention provides a liquefied hydrogen storage tank having a double structure including an inner wall and an outer wall, between the inner wall and the outer wall to form an airgel thin film layer having excellent thermal insulation performance and a vacuum layer to maintain a vacuum state, and thus excellent thermal insulation performance, Accordingly, the temperature loss of the liquefied hydrogen storage tank is reduced to the maximum, thereby reducing the evaporation rate.

In addition, the present invention has an effect that the inner wall support means for supporting between the inner wall and the outer wall of the liquefied hydrogen storage tank has a heat insulating performance, effectively blocking the heat flow into the storage tank through the inner wall support means.

In addition, the present invention can stably process the liquefied hydrogen leaked from the liquefied hydrogen storage tank by the leakage barrier formed in the receiving groove, there is an effect to ensure the stability of the liquefied hydrogen storage tank.

1 is a front sectional view of a marine liquefied hydrogen storage tank according to the present invention.
2 is a side cross-sectional view of a spherical liquefied hydrogen storage tank according to the present invention.
3 is a side sectional view of a cylindrical liquefied hydrogen 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 which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a front sectional view of a marine liquefied hydrogen storage tank according to the present invention.

Referring to FIG. 1, a marine liquefied hydrogen storage tank 100 according to the present invention has a double structure including an inner wall 110 and an outer wall 120 surrounding the same to maintain a cryogenic state of liquefied hydrogen stored therein. It can be seen that the heat insulating portion 130 is installed in the space between the inner wall 110 and the outer wall 120 to block heat transfer; An inner wall support means (140) installed between the inner wall (110) and the outer wall (120) to maintain a separation between the inner wall (110) and the outer wall (120) and support the load of the inner wall (110); And an outer wall supporting means 150 supporting the entire load of the liquefied hydrogen storage tank 100 by supporting the outer wall 120.

The inner wall 110 has a space for storing liquefied hydrogen inside.

Since the inner wall 110 is in direct contact with liquefied hydrogen, the inner wall 110 should be made of a metal material having excellent low-temperature characteristics capable of withstanding the cryogenic temperature of the liquefied hydrogen. Preferably, the inner wall 110 may be made of aluminum (Al) or an aluminum alloy material.

The outer wall 120 serves to support the inner pressure of the inner wall 110 evenly by sharing the inner pressure applied to the inner wall 110.

The outer wall 120 may be made of steel to withstand the stress or load transmitted from the inner side of the inner wall 110. The outer wall 120 may be provided as a general steel, unlike the inner wall 110 to directly seal the liquefied hydrogen. This is because the effect of the cryogenic temperature of the liquefied hydrogen is less than the inner wall 110 by the heat insulating portion 130 provided between the inner wall 110 and the outer wall 120 as described later, even if the liquefied hydrogen leaks splash shield (splash) This is because the liquefied hydrogen leaked by the shield 131 is blocked in advance.

The inner wall 110 and the outer wall 120 are preferably provided in a spherical type or a cylindrical type so that the internal pressure of the liquefied hydrogen stored therein can be evenly distributed.

The heat insulating part 130 is formed between the splash shield 131 surrounding the outer side of the inner wall 110, the airgel thin film layer 132 surrounding the outside of the splash shield 131, the airgel thin film layer 132 and the outer wall 120. And a vacuum layer 133 to be formed. That is, the splash shield 131, the airgel thin film layer 132, and the vacuum layer 133 are sequentially formed in the space between the inner wall 110 and the outer wall 120.

The splash shield 131 serves to protect the outer wall 120 when liquefied hydrogen leaks due to the crack of the inner wall 110.

The splash shield 131 primarily blocks liquefied hydrogen when it leaks from the inner wall 110. The splash shield 131 has a high strength and brittleness at low temperature, such as stainless steel, aluminum, or an aluminum alloy. It may be made of a material.

The splash shield 131 may include a pleat that is continuous so that the cross section has a waveform. The wrinkled portion formed in the splash shield 131 is stretched and contracted by the cryogenic temperature of the liquefied hydrogen to prevent the concentration of stress. In addition, since the pleats provide a space in which the liquefied hydrogen leaked from the inner wall 110 can be temporarily accommodated, the storage and transportation of the liquefied hydrogen can be made stable for a long time even when the liquefied hydrogen is leaked.

On the other hand, the portion supported by the inner wall support means 140 to be described later in the splash shield 131 may be provided flat to be stably supported.

The airgel thin film layer 132 blocks heat transfer between the inner wall 110 and the outer wall 120.

The airgel thin film layer 132 is formed of a thin layer of aerogel (aerogel), which is a highly porous nanostructure consisting of nanoparticles of 1 to 50nm size, and has excellent thermal insulation performance. 1 is exaggerated to help explain the invention, the airgel thin film layer 132 is formed to a thin thickness, the thickness of the thin film layer may be designed to an appropriate thickness according to the installation environment, such as the capacity of the storage tank. In addition, in order to further maximize the thermal insulation performance, a thin film layer may be formed of silica aerogel containing silica.

The vacuum layer 133 blocks heat transfer by conduction and convection between the inner wall 110 and the outer wall 120.

The vacuum layer 133 may be filled with perlite as a core material. In a state filled with perlite (perlite), the vacuum layer 133 to vacuum exhaust to form a vacuum atmosphere, wherein the degree of vacuum may be formed of about 10- ⁴ Torr.

The bottom side of the liquefied hydrogen storage tank 100 may be provided with a vacuum pump (P) and a vacuum monitoring means (not shown) to form and maintain the vacuum layer 133 in a vacuum state.

In the present invention, the heat insulation effect is greatly improved by double blocking heat transfer between the inner wall 110 and the outer wall 120 by the airgel thin film layer 132 and the vacuum layer 133. Therefore, even without using a method such as thickening the storage tank as in the prior art, it is possible to minimize the temperature loss of the liquefied hydrogen storage tank 100 and to reduce the evaporation rate as much as possible.

On the other hand, the storage tank provided in a dual structure as in the present invention is provided with support means for supporting between the inner wall and the outer wall. At this time, heat transfer may occur due to the support means for supporting the inner wall and the outer wall, which may be a factor that impairs the thermal insulation performance of the storage tank.

Accordingly, the present invention provides the inner wall support means 140 by providing the inner wall support means 140 supporting the inner wall 110 and the outer wall 120 of the liquefied hydrogen storage tank 100 to itself have a thermal insulation performance. Through this, to efficiently block the heat flowing into the storage tank.

The inner wall supporting means 140 is installed between the dual structure of the inner wall 110 and the outer wall 120 to maintain the separation between the inner wall 110 and the outer wall 120 and to support the load of the inner wall 110. The inner wall support means 140 may be installed below the liquefied hydrogen storage tank 100 to support the bottom surface of the inner wall 110.

The inner wall supporting means 140 may have a shape that becomes narrower from the lower end to the upper end. Since the liquefied hydrogen stored in the inner wall 110 has a low specific gravity characteristic, the load acting on the upper portion is smaller than the load acting on the lower portion of the inner wall supporting means 140. That is, the load does not act much on the upper portion of the inner wall support means 140 other than the sloshing load. Therefore, the shape of the inner wall support means 140 can be provided to be narrower toward the upper end as described above, thereby reducing the contact range where heat transfer can occur and can also reduce the material cost.

The inner wall supporting means 140 includes a frame 141 made of plywood having high strength and low thermal conductivity, and a heat insulating member 142 provided in an inner space of the frame 141.

The plywood constituting the frame 141 has a high strength to support the load of liquefied hydrogen stored in the inner wall 110, and a low thermal conductivity can significantly reduce the transfer of external heat to the inner wall 110. . The frame 141 may be adhesively fixed to the outside of the heat insulating member 142 by an adhesive.

The heat insulating member 142 is a two-stage configuration including an upper heat insulating member 142a disposed above the inner space of the frame 141 and a lower heat insulating member 142b disposed below the inner space of the frame 141. Can be prepared as.

The upper insulation member 142a may be made of a rigid foam, and the lower insulation member 142b may be made of a non-foamable resin including a vacuum insulation panel (VIP) therein.

Since the most easily used as a material of the insulating material is polyurethane (polyurethane), in the present invention, the upper insulating member 142b is a rigid polyurethane foam (PUF), the lower insulating member 142b is a non-foamable polyurethane (PU) Can be done. However, the present invention is not limited thereto. In addition to polyurethane, various heat insulating materials having suitable heat insulating performance may be applied.

Since the vacuum insulation panel (VIP) included in the lower insulation member (142b) has a thermal insulation performance of about 2 times or more than that of the rigid polyurethane foam, the vacuum insulation panel (VIP) inside the insulation member 142 as in the present invention. When configured to include, the heat insulating member 142 is superior to the heat insulating performance than to configure only with a rigid polyurethane foam.

In addition, by the vacuum insulation panel (VIP) included in the lower heat insulating member 142b, the vacuum insulation effect by the vacuum layer 133 may be continued without interruption even at the portion where the inner wall support member 140 is installed.

Unlike the upper insulating member 142a made of rigid polyurethane foam, the lower insulating member 142b is made of non-foamable polyurethane because the lower insulating member 142b includes a vacuum insulating panel (VIP) therein. to be. Non-foamable polyurethane can maintain the degree of vacuum of the vacuum insulation panel (VIP) semi-permanently, although the design temperature is higher than the foam.

Although not shown in FIG. 1, in order to prevent the liquefied hydrogen storage tank 100 from being conducted by rolling the hull or the like, the inner wall supporting means 140 is connected to a fastening means such as an outer wall 120 and a stud bolt. Can be fixed.

The inner wall support means 140 may further include an elastic member 143 which is installed on the bottom surface in contact with the outer wall 120.

The inner wall 110 in which liquefied hydrogen is stored may have deformation due to thermal contraction and thermal expansion because a large temperature change is caused by the dropping region of liquefied hydrogen.

At this time, if the inner wall support means 140 is fixed to the inner wall 110 and the outer wall 120, the stress is generated by the contraction or expansion of the inner wall 110, the inner wall 110 and the outer wall 120 or inner wall support means ( There is a risk of cracking or breakage at 140.

The elastic member 143 compensates the expansion and contraction of the inner wall 110 according to the loading and dropping of the liquefied hydrogen. That is, the elastic member 143 is compressed and relaxed according to the expansion and contraction of the inner wall 110 so that the inner wall 110 and the outer wall 120 is stably supported.

Outer wall support means 150 is fixed to the hull (S) and supports the entire load of the liquefied hydrogen storage tank 100 by supporting the outer wall (120).

The outer wall supporting means 150 may have a shape corresponding to the bottom of the outer wall 120 so that the liquefied hydrogen storage tank 100 can be seated. That is, the outer wall support means 150 has a concave shape to surround the outer wall 120 of the liquefied hydrogen storage tank 100.

The outer wall support means 150 may be made of a steel material to withstand the load of the liquefied hydrogen storage tank 100, but is not limited thereto and any material as long as it is capable of supporting the load of the storage tank. Can be applied.

An inner side surface of the outer wall support means 150 may be provided with a leak barrier 151 in which a receiving groove g is formed to receive the liquefied hydrogen leaked from the liquefied hydrogen storage tank 100.

While the outer wall support means 150 is sufficient to be made of a general steel material, the leak barrier 151 must be made of a metal material having excellent low temperature characteristics so that the cryogenic leakage of the liquefied hydrogen can be tolerated. Preferably it may be made of any one material of stainless steel, aluminum and aluminum alloy.

The receiving groove g formed in the leakage barrier 151 provides a receiving space for the liquefied hydrogen leaked from the liquefied hydrogen storage tank 100 and forms a flow path through which the leaked liquefied hydrogen can be smoothly discharged. When the leaked liquefied hydrogen accumulates at a certain point, localized damage to the storage tank may occur due to cryogenic liquefied hydrogen. In the present invention, the liquefied hydrogen leaked along the receiving groove g may be smoothly discharged. Even in case of leakage of hydrogen, the stability of the storage tank can be ensured.

The outer wall supporting means 150 and the leak barrier 151 may be fastened to the outer wall 120 by bolt coupling. For example, the stud bolts fixed to the outer surface of the outer wall 120 may pass through the outer wall supporting means 150 and the leak barrier 151, and then the nuts may be fastened to each other.

2 is a side cross-sectional view of a spherical liquefied hydrogen storage tank according to the present invention, Figure 3 is a side sectional view of a cylindrical liquefied hydrogen storage tank according to the present invention.

The liquefied hydrogen storage tank 100 according to the present invention may be provided in a spherical or cylindrical type, as shown in Figures 2 and 3, the inner wall in the cylindrical liquefied hydrogen storage tank 100 shown in FIG. The support means 140 and the outer wall support means 150 may be installed to be spaced apart from each other along the longitudinal direction of the storage tank. According to this configuration it is possible to reduce the heat inflow into the storage tank through the support means (140, 150) as much as possible and to reduce the material cost.

According to the present invention, in the liquefied hydrogen storage tank 100 having a dual structure including an inner wall 110 and an outer wall 120, an airgel thin film layer 132 having excellent thermal insulation performance between the inner wall 110 and the outer wall 120. And the vacuum layer 133 to maintain the vacuum state is very excellent thermal insulation performance, thereby reducing the temperature loss of the liquefied hydrogen storage tank 100 to the maximum effect to reduce the evaporation rate.

In addition, the present invention by the inner wall support means 140 for supporting between the inner wall 110 and the outer wall 120 of the liquefied hydrogen storage tank 100 has a heat insulating performance, the storage tank through the inner wall support means 140 There is an effect of effectively blocking the heat flowing into the inside.

In addition, the present invention can stably process the liquefied hydrogen leaked from the liquefied hydrogen storage tank 100 by the leakage barrier 151 formed with the receiving groove (g), thereby ensuring the stability of the liquefied hydrogen storage tank 100 It is effective.

The present invention is intended to be applied to liquefied hydrogen storage tanks that require more stringent thermal insulation performance than liquefied natural gas, but also liquefied natural gas (LNG), liquefied petroleum gas (LPG), compressed natural gas (CNG), etc. Of course, it can also be applied to the storage tank for storing the liquefied gas.

Such a present invention is not limited to the described embodiments, and various modifications and variations can be made without departing from the spirit and scope of the present invention. It will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

100: liquefied hydrogen storage tank 110: inner wall
120: outer wall 130: heat insulation
131: splash shield 132: aerogel thin film layer
133: vacuum layer 140: inner wall support means
141: frame 142: insulation member
142a: upper insulation member 142b: lower insulation member
143: elastic member 150: outer wall support means
151: leak barrier

Claims (11)

In the marine liquefied hydrogen storage tank provided in a dual structure comprising an inner wall and the outer wall surrounding the inner wall is formed a space for storing the liquefied hydrogen,
An insulation unit installed in a space between the inner wall and the outer wall to block heat transfer;
Inner wall supporting means for supporting between the inner wall and the outer wall; And
And outer wall supporting means for supporting the entire load of the liquefied hydrogen storage tank by supporting the outer wall.
On the inner surface of the outer wall supporting means is characterized in that the leakage barrier is provided with a receiving groove formed in the center,
Liquefied hydrogen storage tanks for ships. The method according to claim 1,
The leakage barrier is characterized in that it is made of any one of stainless steel, aluminum and aluminum alloy,
Liquefied hydrogen storage tanks for ships. The method according to claim 2,
The inner wall support means,
A frame made of plywood;
And a heat insulating member provided in the inner space of the frame.
The heat insulating member is characterized in that it is provided in a two-stage configuration comprising an upper heat insulating member made of a rigid foam and a lower heat insulating material made of a non-foamable resin including a vacuum insulation panel (VIP) therein,
Liquefied hydrogen storage tanks for ships. The method according to claim 3,
The upper insulation member is made of a rigid polyurethane foam (PUF), the lower insulation is characterized in that made of a non-foamable polyurethane (PU),
Liquefied hydrogen storage tanks for ships. The method according to claim 4,
The inner wall support means is provided so as to narrow the width from the lower end to the upper end, characterized in that installed to support the bottom of the inner wall,
Liquefied hydrogen storage tanks for ships. The method according to claim 5,
The inner wall support means,
Characterized in that it further comprises; an elastic member installed on the bottom surface in contact with the outer wall
Liquefied hydrogen storage tanks for ships. The method according to claim 4,
The heat insulation unit,
A splash shield surrounding an outer side of the inner wall;
An airgel thin film layer surrounding the splash shield; And
It includes; a vacuum layer formed between the airgel thin film layer and the outer wall,
Liquefied hydrogen storage tanks for ships. The method according to claim 7,
The inner wall is made of aluminum or aluminum alloy,
The splash shield is made of stainless steel, aluminum, or aluminum alloy, characterized in that to protect the outer wall from liquefied hydrogen leaking from the inner wall, including a continuous corrugated portion of the cross-section waveform,
Liquefied hydrogen storage tanks for ships. The method according to claim 8,
The vacuum layer is characterized in that the pearlite is filled with a core (mate materail),
Liquefied hydrogen storage tanks for ships. The method according to any one of claims 1 to 9,
The liquefied hydrogen storage tank is a cylindrical type storage tank,
The inner wall support means is installed so that a plurality of spaced apart from each other along the longitudinal direction of the liquefied hydrogen storage tank,
Liquefied hydrogen storage tanks for ships. In the marine liquefied hydrogen storage tank provided in a dual structure including an inner wall and the outer wall surrounding the liquefied hydrogen is stored in the inside,
In order to maintain the separation space in which the heat insulation is provided in the space between the inner wall and the outer wall, inner wall support means for supporting between the inner wall and the outer wall is installed,
The inner wall supporting means is laminated in two stages in a frame inner space made of plywood, an upper heat insulating material made of a rigid foam, and a lower heat insulating material made of a non-foamable resin including a vacuum insulation panel (VIP) therein.
The inner surface of the outer wall support on which the liquefied hydrogen storage tank is seated, characterized in that the leakage barrier is provided with a receiving groove formed in the center,
Liquefied hydrogen storage tanks for ships.

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