KR101589118B1 - Pressurized container for liquefied gas - Google Patents

Abstract

Disclosed is a pressure container for storing liquefied gas. According to an embodiment of the present invention, the pressure container for storing liquefied gas comprises: an inner shell which stores liquefied gas therein, and maintains the inner pressure of the inner shell higher than the atmospheric pressure; an outer shell which surrounds the inner shell with an interval from the inner shell; and a heat insulation portion provided in a space between the inner shell and the outer shell, wherein the heat insulation portion includes a plurality of heat insulation materials of which both sides of the heat insulation materials connecting an outer surface facing the outer shell to an inner surface having a smaller area than the outer surface and facing the inner shell are tapered.

Description

[0001] PRESSURIZED CONTAINER FOR LIQUEFIED GAS [0002]

The present invention relates to a pressure vessel for storing a liquefied gas.

The liquefied gas is a gas which is cooled or compressed to become a liquid. Since the volume of the liquefied gas is smaller than that in a gaseous state, the liquefied gas is easily stored in a container for storage or transportation. For example, Liquefied Natural Gas (LNG), which is a typical liquefied gas, is a natural gas containing methane as a main component cooled to -163 ° C and liquefied. Only one.

As a method of liquefying the gas, there is a method of liquefying the gas by compressing the gas at room temperature and a method of liquefying the gas while being cooled to a temperature lower than the gasification temperature lower than room temperature. When the latter liquefaction method is used, the gasification temperature of the gas is determined by the pressure inside the vessel. For example, by increasing the pressure inside the vessel, the gasification temperature of the gas can be raised. As the gasification temperature of the gas is increased, the operation of the cooling device necessary to lower the internal temperature of the container can be reduced, which can reduce the cost. Further, when the latter liquefaction method is used, pressure is applied to the inside of the container, so there is an advantage that it is easy to discharge the liquefied gas from the container, and there is no need to construct an additional device for discharging the liquefied gas.

The liquefied gas may be stored in a pressure vessel capable of withstanding a certain level of pressure. The pressure vessel is formed into a cylindrical or spherical shape to effectively withstand the internal pressure, and the pressure vessel is provided with a single structure vessel composed of a single vessel and a heat insulating material wrapping the single vessel, an inner vessel, an outer vessel, There is a rescue container.

Here, the internal temperature of the single vessel or the inner vessel is determined according to the stored liquefied gas, and the single vessel or the inner vessel is made of a material that can withstand the internal temperature as described above. The thickness of a single container or inner container is determined by the material of the container, the design pressure, the size of the container, and the like. The design of these internal vessels is generally governed by the American Society of Mechanical Engineers (ASME), the International Gas Code (IGC) and the High Pressure Gas Safety Management Act.

However, when the liquefied gas is a substance that maintains a liquid state at a cryogenic temperature like liquefied natural gas, a single container or an inner container must be used as a metal that can withstand extremely low temperatures, and at the same time, . There has been a problem that the manufacturing cost of the pressure vessel for storing the liquefied gas is greatly increased by manufacturing a thick container made of metal.

In addition, in the case of a pressure vessel, the vessel is usually formed in a cylindrical shape or a spherical shape. In the case of manufacturing a conventional double structure vessel, the inner vessel and the outer vessel are separately manufactured and then the inner vessel is inserted into the outer vessel and assembled Respectively. However, there has been a problem in that it is difficult to use a manufacturing method in which the inner container is inserted and assembled as described above when the inner container is made thin or when the diameter of the container is relatively large.

Korean Patent Publication No. 10-2012-0020840 Korean Patent Publication No. 10-2012-0042187

Embodiments of the present invention are intended to provide a pressure vessel for storing liquefied gas capable of reducing the thickness of the inner vessel. Another object of the present invention is to provide a pressure vessel for storing liquefied gas, which can be easily manufactured even when the internal vessel is made thin.

According to an aspect of the present invention, there is provided an internal combustion engine comprising: an internal shell in which liquefied gas is stored, the internal pressure of which is maintained higher than atmospheric pressure; An outer shell surrounding an outer side of the inner shell to be spaced apart from the inner shell; And a heat insulating portion provided in a space between the inner shell and the outer shell, wherein the heat insulating portion has an outer surface facing the outer shell and a connecting portion having an area smaller than the outer surface and connecting the inner surface facing the inner shell There can be provided a pressure vessel for storing liquefied gas including a plurality of heat insulating members whose side surfaces are formed as tapered surfaces.

The apparatus of claim 1, further comprising a protective shell disposed between the inner shell and the outer shell to be spaced apart from the inner shell and the outer shell, wherein the plurality of heat insulating materials are provided in a space between the outer shell and the protective shell And a plurality of second insulation provided in a space between the protective shell and the inner shell may be provided.

Further, the heat insulating portion may insulate the inner shell and transfer the inner pressure of the inner shell to the outer shell.

In addition, the inner shell may be disposed with a wrinkle shape that absorbs heat shrinkage of the inner shell at a predetermined interval.

The plurality of heat insulating materials may be mounted inside the outer shell such that the tapered surfaces of two adjacent heat insulating materials face each other.

Further, the inner surface of the heat insulating material can contact at least a part of the inner shell.

The outer shell may include a curved surface, and a portion of the inner shell corresponding to a curved surface of the outer shell may be formed by assembling a plurality of flat plates bent at both ends.

Further, the plurality of flat plates can be assembled by welding along the overlapping folding lines in a state where two adjacent flat plates are overlapped so that the folding lines of the flat plates overlap each other.

In addition, the angle at which both ends of each flat plate are bent may have a size such that the assembled shape of the plurality of flat plates corresponds to the curved surface of the outer shell.

The inner surface and the outer surface of the first heat insulator are respectively directed to the outer surface of the protective shell and the outer shell, and the plurality of first heat insulators are disposed on the outer shell of the outer shell so that the tapered surfaces of the two adjacent first heat insulators face each other. As shown in FIG.

The plurality of second heat insulating materials are formed such that the inner side surfaces and the outer side surfaces of the second insulating material face the inner surfaces of the inner shell and the protective shell, respectively, and the tapered surfaces of the two adjacent second insulating materials face each other Wherein a width of the outer surface of the joint thermal insulator is equal to or greater than a width of the inner surface of the protective shell, The outer width of the space between the small, spaced apart tapered surfaces may be equal to or less than the inner width.

In addition, the connection thermal insulator may be inserted into the space between the spaced apart tapered surfaces in a direction toward the outer surface of the second insulation from the inner surface of the second insulation.

In addition, the inner surface of the first insulator may contact at least a portion of the protective shell, and the inner surface of the second insulator may contact at least a portion of the inner shell.

In addition, the protective shell may be disposed outside the lower portion of the inner shell.

In addition, the protective shell may be made of the same material as the inner shell.

In addition, a plurality of studs spaced apart from each other between the inner shell and the outer shell at predetermined intervals may be further provided to prevent movement of the first heat insulating material.

Embodiments of the present invention can reduce the thickness of the inner container of the pressure vessel. This makes it possible to reduce the production cost of the vessel while reducing the total weight of the pressure vessel while taking advantage of the pressure vessel in storing the liquefied gas.

Further, even when the thickness of the inner container of the pressure vessel is reduced, a cylindrical or spherical pressure vessel can be easily manufactured. This makes it possible to improve the production of the pressure vessel with reduced weight.

1 is a perspective view of a pressure vessel for storing liquefied gas according to an embodiment of the present invention.
2 is a cross-sectional view taken along line A-A 'of the pressure vessel for storing liquefied gas according to the embodiment of FIG.
3 is an enlarged partial view of the area B in Fig.
4 is a cross-sectional view illustrating a pressure vessel for storing liquefied gas according to another embodiment of the present invention.
5 is an enlarged view of a portion C of FIG. 4 enlarged.
6 is a perspective view illustrating a pressure vessel for storing liquefied gas according to another embodiment of the present invention.
7 is a cross-sectional view illustrating a pressure vessel for storing liquefied gas according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

In the following description, well-known functions or constructions are not described in detail since they may obscure the subject matter of the present invention.

In this specification, the inner surface refers to the surface facing the inner space of the pressure vessel among the surfaces of the member when the specific member is disposed, and the outer surface can refer to the surface facing the outside. 3, a pressure vessel for storing liquefied gas according to an embodiment of the present invention will be described.

1 is a perspective view showing a pressure vessel 100 for storing liquefied gas according to an embodiment of the present invention. 2 is a cross-sectional view taken along line A-A 'of the pressure vessel 100 for storing a liquefied gas according to the embodiment of FIG. 1, and FIG. 3 is a cross- (B) of FIG.

1 to 3, a pressure vessel 100 for storing liquefied gas according to an embodiment of the present invention includes an inner shell 110, a thermal insulation unit 120, and an outer shell 130, . ≪ / RTI > As shown in FIGS. 1 and 2, the pressure vessel 100 for storing liquefied gas may further include a support 150.

The inner shell 110 is a container in which liquefied gas can be stored, and the inner pressure of the inner shell 110 can be kept higher than the atmospheric pressure. The inner shell 110 may be made of a metal whose strength or brittleness is not weakened even when the inner shell 110 is maintained at a low temperature lower than room temperature so that liquefied gas can be stored therein. For example, natural gas (LNG) is stored at -163 ° C. Therefore, the type of metal can be determined depending on the temperature of the liquefied gas stored therein. For example, stainless steel, aluminum (Al) And the like can be used as the material of the inner shell 110.

The inner shell 110 may have a shape corresponding to the outer shell 130 so that the inner shell 110 can be uniformly supported by the outer shell 130, as described later. The specific structure and shape of the inner shell 110 will be described later in detail.

The inner shell 110 may have a corrugation 119 spaced apart at regular intervals. The wrinkle shape 119 can protrude inward of the inner shell 110 as well as protrude in the outer direction of the inner shell 110 as shown.

The corrugated shape 119 formed in the inner shell 110 can absorb heat shrinkage or thermal expansion that is issued to the inner shell 110. For example, to maintain the liquefied gas stored in the inner shell 110 in a liquid state, the internal temperature of the inner shell 110 may be maintained below the vaporization temperature of the liquefied gas. In this case, the heat shrinkage occurring in the inner shell 110 due to the lowered temperature can be absorbed by the wrinkle shape 119 of the inner shell 110. When the liquefied gas is not stored, the wrinkle shape 119 can absorb the thermal expansion generated in the inner shell 110 as the temperature of the inner shell 110 becomes higher than the temperature of the outside air. Accordingly, the wrinkle shape 119 can prevent the inner shell 110 from being damaged by heat shrinkage and thermal expansion.

The heat insulating portion 120 may be provided on the outer side of the inner shell 110 and may include a plurality of the first heat insulating materials 121. The heat insulating portion 120 is provided in a space between the inner shell 110 and the outer shell 130 to be described later so as to reduce the heat transfer between the inner shell 110 and the outside air, To the shell 130.

When the heat insulating portion 120 includes a plurality of the first heat insulating materials 121, each of the first heat insulating materials 121 may be formed of a polyurethane foam. The polyurethane foam may be formed by mixing with a volatile solvent in the space between the inner shell 110 and the outer shell 130 and foaming. Alternatively, the polyurethane foam may be manufactured in advance and inserted into the space corresponding to the space between the inner shell 110 and the outer shell 130. Further, the individual polyurethane foams may be floated so that breakage does not occur due to the deformation caused by the pressure inside the polyurethane foam.

In addition, the space in which the heat insulating portion 120 is provided, that is, the space between the inner shell 110 and the outer shell 130, may be evacuated to increase the heat insulating effect.

The outer shell 130 may wrap around the outer shell 110 such that a space is formed between the outer shell 130 and the inner shell 110. The outer shell 130 serves to support the inner pressure of the inner shell 110 transmitted through the heat insulating portion 120. As shown in Figures 1 and 2, the outer shell 130 may be cylindrical. Alternatively, although not shown, the outer shell 130 may be spherical. As described above, the inner shell 110 may have a shape corresponding to the shape of the outer shell 130 so that the outer shell 130 uniformly supports the inner pressure of the inner shell 110.

The outer shell 130 may be configured to withstand pressures in excess of atmospheric pressure. For example, it may be made of a metal having excellent strength and brittleness at room temperature, or a composite material reinforced with glass fiber or carbon fiber. As a result, the inner shell 110 can be consequently supported by the outer shell 130. Since the inner shell 110 does not have to directly withstand the internal pressure, the thickness of the inner shell 110 can be reduced, thereby reducing manufacturing costs.

On the other hand, when the outer shell 130 is cylindrical or spherical, the outer shell 130 may include a curved surface. At this time, the portion of the inner shell 110 located on the inner side of the curved portion of the outer shell 130 needs to be formed in a shape corresponding to the curved surface.

As shown in FIG. 3, in the present embodiment, the inner shell 110 may have a plurality of flat plates 111 with both ends bent. In a state where the adjacent flat plates 111 are overlapped with each other, the adjacent flat plates 111 are welded (W) to each other so that the inner shell 110 can be assembled. At this time, the adjacent two flat plates 111 can be superimposed so that the folding lines adjacent to each other among the two folding lines formed on the flat plates 111 overlap each other, and the welding W is performed along the overlapping folding lines The two flat plates 111 can be assembled.

Both ends of each flat plate 111 can be bent at a predetermined angle, and the angle can be determined according to the curved shape of the outer shell 130. For example, when the outer shell 130 is cylindrical, the angle at which both ends of each flat plate 111 are bent can be determined according to the size of the diameter of the cross-section of the cylindrical outer shell 130. Specifically, the angle may be determined such that when the plurality of flat plates 111 are assembled, the shape of the assembly corresponds to the curved surface of the outer shell 130.

The above-mentioned wrinkle shape 119 may be formed in each flat plate 111. The wrinkle shape 119 may be formed at a central portion between both bent ends of each flat plate 111. [ The corrugation 119 formed in each flat plate 111 can absorb heat shrinkage and thermal expansion that occur when the temperature of the flat plate 111 changes.

In this embodiment, the outer surface of each of the first heat insulating materials 121 is formed as a curved surface D, the inner surface having a smaller area than the outer surface is formed as a plane P1, Both side surfaces connecting the curved surface D may be formed as a tapered surface T1. That is, each of the first heat insulating materials 121 has a shape similar to a trapezoidal shape in cross section, but has a curved bottom shape.

The plurality of first heat insulators 121 are arranged such that the curved surface D of each first heat insulator 121 faces the outer shell 130 and the tapered surfaces T1 of the two adjacent first heat insulators 121 face each other. May be provided in the interior of the shell 130, that is, in the space between the inner shell 110 and the outer shell 130. The inclination angle of the tapered surface T1 of each of the first heat insulating materials 121 can be determined according to the shape of the curved surface D of the outer shell 130. [ For example, when the plurality of first heat insulating materials 121 are arranged so that the tapered surfaces T1 of the two adjacent first heat insulating materials 121 are parallel to each other, 121 may be determined such that the shape of the curved surface D of the outer shell 130 corresponds to the curved surface of the outer shell 130.

The curved surface D of the first heat insulator 121 may correspond to the inner surface of the outer shell 130. For example, the curved surface D of the first heat insulator 121 may be formed to have the same curvature as the inner surface of the outer shell 130. In this case, the curved surface D of the first heat insulator 121 can be formed with the inner surface of the curved outer shell 130, so that the first heat insulator 121 is pressed against the inner surface of the inner shell 110, Can be uniformly dispersed and delivered to the outer shell (130).

The plane P1 of the first thermal insulation material 121 can be in contact with at least a part of the inner shell 110 when the first thermal insulation material 121 is provided inside the outer shell 130. [ That is, the plane P1 of the first heat insulating material 121 can contact the flat plate 111 constituting the inner shell 110.

At this time, the center portion between the bent ends of each flat plate 111 is in contact with the plane P1 of the first heat insulating material 121 provided on the outer side thereof, and both ends of the bent portion come into contact with the amount of the first heat insulating material 121 And can come into contact with the plane P1 of the other first insulation material 121 provided on the side. For this purpose, the angle at which the both ends of each flat plate 111 are bent is set so that the plurality of first heat insulating materials 121 are bent in such a manner that the curved surface D is arranged so as to be in- May be the same as the angle formed by the plane (P1) of the heat insulating material (121). The first insulation member 121 may be formed in the space between the inner shell 110 and the outer shell 130 by being bent at both ends of each of the flat plates 111 as described above .

According to the present embodiment, the inner shell 110 can be easily manufactured by assembling the plurality of flat plates 111 with the inner shell 110. Unlike the prior art in which a dual structure pressure vessel is manufactured by separately forming an inner vessel and inserting it into an outer vessel to assemble a plurality of flat plates 111 inside the outer vessel, ) Can be produced. Accordingly, even when the thickness of the inner shell 110 is reduced or the inner shell 110 having a relatively large size is formed, the dual structure pressure vessel can be easily manufactured.

Also, since the inner shell 110 is manufactured by assembling a plurality of bent flat plates 111, the inner shell 110 may have a plurality of planes connected to each other. That is, the inner shell 110 does not include a curved surface but may be formed in such a manner that the planes are connected at a predetermined angle. As a result, even when the outer shell 130 has a shape including a curved surface, it is not necessary to form a curved surface of the inner shell 110 itself, which can improve the preparation and reduce the manufacturing cost.

The outer shell 130 is formed as a curved surface and the inner shell 110 is formed as a flat surface as described above by using the first heat insulating material 121 having the curved surface D and the other surface forming the plane P1. It is possible to efficiently provide the heat insulating part 120 in the space between the inner shell 110 and the outer shell 130. In addition, since the side surfaces of the first heat insulating material 121 are formed as the tapered surface T1, a separate connecting member is not provided between the adjacent first heat insulating materials 121, It is possible to provide a plurality of first heat insulating materials 121 in a shape corresponding to the curved surface of the outer shell 130 only by abutting the outer shells T1.

Hereinafter, a pressure vessel 100a for storing a liquefied gas according to another embodiment of the present invention will be described with reference to FIGS. 4 and 5. FIG. However, this embodiment further includes the protective shell 140 in comparison with the above-described embodiment, and the difference in that the heat insulating portion 120 further includes the second heat insulating material 122 and the connection heat insulating material 123 Therefore, differences will be mainly described, and the description of the above-described embodiment and the reference numerals will be used for the same parts.

FIG. 4 is a view showing a pressure vessel 100a for storing a liquefied gas according to another embodiment of the present invention, and FIG. 5 is an enlarged view of a portion C of FIG.

4 and 5, a pressure vessel 100a for storing a liquefied gas according to another embodiment of the present invention is disposed between an inner shell 110 and an outer shell 130, The heat insulating part 120 may include the second heat insulating material 122 and the connection heat insulating material 123 together with the first heat insulating material 121. [

The protective shell 140 may be made of the same material as that of the inner shell 110 described above or may be made of a metal or a composite material having strong strength and brittleness even at a cryogenic temperature lower than room temperature. The protective shell 140 is inserted between the inner shell 110 and the outer shell 130 and between the inner shell 110 and the protective shell 140 and between the protective shell 140 and the outer shell 130, A portion 120 may be provided.

The protective shell 140 may be formed in a shape corresponding to the outer shell 130, and may have a plurality of planes connected to each other. 5, the protective shell 140 may be formed by assembling a plurality of flat plates 111, both ends of which are bent, by referring to the description of the inner shell 110 described above, do.

In addition, like the inner shell 110, the protective shell 140 may include a wrinkle shape to absorb heat shrinkage and thermal expansion caused by a change in temperature. When the protective shell 140 is formed by assembling a plurality of flat plates 111, the corrugated shape may be formed on each flat plate 111.

In this embodiment, the heat insulating portion 120 may include the first heat insulating material 121 and the second heat insulating material 122 described above. In this case the primary insulation 121 is provided between the outer shell 130 and the protective shell 140 and the secondary insulation 122 is provided between the protective shell 140 and the inner shell 110 .

One surface of the first heat insulating material 121 is formed in a plane P1 and a surface facing the one surface is formed of a curved surface D. The surface of the first heat insulating material 121 facing the curved surface D, May each be formed as a tapered surface T1 that gradually narrows toward the plane P1. The plane P1 of the first heat insulator 121 can be in contact with at least a part of the protective shell 140. [ That is, in this embodiment, the plane P of the first heat insulator 121 can contact the protective shell 140, not the inner shell 110. [

On the other hand, the outer surface P21 and the inner surface P22 of the second heat insulating material 122 are each formed in a plane, and both side surfaces connecting the two planes P21 and P22 may be formed as a tapered surface T2 . That is, each of the second heat insulating materials 122 may have a shape having a trapezoidal cross section.

The plurality of second heat insulators 122 are arranged such that the outer surface P21 of each second heat insulator 122 faces the protective shell 140 and the tapered surfaces T2 of the two adjacent second heat insulators 122 face each other May be provided in the space between the shell 110 and the protective shell 140. In this case, the outer surface P21 of each secondary insulation 122 may be in contact with at least a portion of the protective shell 140.

When a plurality of second insulation materials 122 are provided in the space between the inner shell 110 and the protective shell 140, a joint insulation material 123 may be inserted between the two adjacent second insulation materials 122 have. The connection insulator 123 may include a tapered surface T3 formed on both sides, as shown in Fig.

When a plurality of second heat insulating materials 122 are arranged so that the tapered surfaces T2 of the two adjacent second heat insulating materials 122 face each other as shown in FIG. 5, by the tapered shapes of the respective second heat insulating materials 122, And an empty space having a shape becoming narrower toward the outer side is formed between the adjacent two second heat insulating materials 122. The connection insulator 123 can be inserted into the hollow space from the inside of the outer shell 130 in the outward direction (see the arrows in Fig. 5). At this time, the joint thermal insulator 123 can be inserted into the hollow space with the tapered surface T3 facing the outside where the size of the cross section is reduced.

The inner shell 110 may be assembled to the inside of the second heat insulating member 122 and the connection heat insulating member 123 after the connection heat insulating member 123 is inserted into the hollow space to provide the connection heat insulating member 123. The specific structure of the inner shell 110 and the method of assembly refer to the above description.

In this embodiment, since the second heat insulating member 122 and the connection heat insulating member 123 are provided just outside the inner shell 110, the angle of the both ends of the flat plate 111 forming the inner shell 110 May be determined according to the shape of the second heat insulator 122 and the connection heat insulator 123. [ Specifically, the angle at which both ends of each flat plate 111 are bent is set such that a plurality of the second heat insulating materials 122 are arranged to cooperate with the plane of the protective shell 140, and the joint thermal insulating material 123 is inserted therebetween May be the same as the angle formed by the inner surface of the second heat insulator 122 and the joint heat insulator 123 positioned adjacent to each other. In this case, the secondary insulating material 122 and the joint insulating material 123 may be formed in the space formed between the inner shell 110 and the protective shell 140.

According to the present embodiment, like the inner shell 110, the protective shell 140 can have a plurality of planes connected to each other. In other words, the protective shell 140 may be formed not to include a curved surface, and even when the outer shell 130 has a curved surface, it is not necessary to form a curved surface on the protective shell 140 itself, Making can be improved and production cost can be reduced.

In addition, by forming both side surfaces of the second heat insulating material 122 from the tapered surface T2, the shape of the space between the adjacent second heat insulating materials 122 can be formed to become narrower toward the outside. Accordingly, the entrance of the space for inserting the connection insulator 123 into the space becomes relatively large, and the connection insulator 123 can be inserted easily. As a result, the composition can be improved.

Hereinafter, a pressure vessel 100b for storing a liquefied gas according to another embodiment of the present invention will be described with reference to FIG. However, this embodiment differs from the above-described embodiment in that the protective shell 142 is disposed only at the lower portion of the pressure vessel 100b. Therefore, differences will be mainly described, and the same portions will be described with reference to the above- And reference numerals.

6 is a view showing a pressure vessel 100b for storing a liquefied gas according to another embodiment of the present invention.

Referring to FIG. 6, the protective shell 142 may be disposed between the bottom of the inner shell 110 and the bottom of the outer shell 130.

In the present embodiment, the protective shell 142 is formed not only in the case where the inner shell 110 and the outer shell 130 are arranged in the horizontal direction as shown in FIG. 9, but also in the case where the inner shell 110 And the lower portion of the outer shell 130. [0035]

Since the liquefied gas flowing into the heat insulating spaces flows downward due to the breakage of the inner shell 110, the protective shell can prevent the liquefied gas from reaching the outer shell 130 without covering the entire outer side of the inner shell 110 It is possible to effectively prevent contact. Thereby, there is an advantage that not only the material cost of the protective shell 142 can be reduced but also the total weight can be reduced.

Hereinafter, a pressure vessel 100c for storing a liquefied gas according to another embodiment of the present invention will be described with reference to FIG. However, the present embodiment differs from the above-described embodiment in that it further includes the stud 138, so that the differences are mainly described, and the description of the above-mentioned embodiment and the reference numerals are used for the same portions.

7 is a view showing a pressure vessel 100c for storing liquefied gas according to another embodiment of the present invention.

Referring to FIG. 7, a first insulation member 121 is installed between an inner shell 110 and an outer shell 130, which is applied to a pressure vessel 100c for storing liquefied gas according to another embodiment of the present invention, And a stud 138 for preventing movement between the shell 110 and the outer shell 130.

The stud 138 may be coupled to the inside of the outer shell 130 as shown. The stud 138 may be made of steel or a rigid resin. When the stud 138 is made of metal, it can be welded to the inside of the outer shell 130. When the stud 138 is made of resin, the stud 138 can be joined to the inside of the outer shell 130 using an adhesive.

In addition, the studs 138 may be plural and may be symmetrically disposed about the inner shell 110. The studs 138 may be spaced apart from one another at regular intervals.

In this embodiment, the stud 138 is provided between the first heat insulators 121 formed of a rigid polyurethane foam, so that the polyurethane foam can be prevented from moving inside the first heat insulator 121. When the pressure vessel 100c for liquefied gas storage is shaken by being transported by a transporting device such as a ship or a truck or being transported by a crane or the like, the inner shell 110 storing the liquefied gas moves in a specific direction, 121 can be prevented from being deformed.

The heat insulating material is not limited to the polyurethane foam, but may be made of a material having a certain rigidity and capable of blocking heat transfer.

On the other hand, the stud 138 can prevent the perlite from being poured into a specific space and evenly distribute the heat in the first heat insulator 121 when the heat insulator is a powder type perlite rather than a polyurethane foam.

Although the preferred embodiments of the pressure vessel for storing liquefied gas according to the embodiment of the present invention have been described above, the present invention is not limited thereto, and the present invention is not limited thereto. . Skilled artisans may implement a pattern of features that are not described in a combinatorial and / or permutational manner with the disclosed embodiments, but this is not to depart from the scope of the present invention. It will be apparent to those skilled in the art that various changes and modifications may be readily made without departing from the spirit and scope of the invention as defined by the appended claims.

110: inner shell 111: bent flat plate
120: heat insulating portion 121: first heat insulating material
122: secondary insulation 123: connection insulation
D: curved surface P1, P21, P22: plane
T1, T2, T3: Tapered surface 130: Outer shell
140: Protective shell 150: Support

Claims (16)

An inner shell in which liquefied gas is stored, the inner pressure of which is maintained above atmospheric pressure;
An outer shell surrounding the inner shell to be spaced apart from the inner shell, the outer shell including a curved surface; And
And a heat insulating portion provided in a space between the inner shell and the outer shell,
The heat-
And a plurality of heat insulating members formed on both side surfaces of the curved surface facing the outer shell and having a smaller area than the outer surface and connecting the inner side surface of the plane facing the inner shell with a tapered surface,
Wherein a portion of the inner shell corresponding to a curved surface of the outer shell is formed by assembling a plurality of flat plates bent at both ends,
Wherein the plurality of flat plates are assembled by being welded along the overlapping folding lines in a state where two adjacent flat plates are overlapped so that the folding lines of the flat plates overlap each other,
Wherein the outer surface of the heat insulating material is in close contact with the curved surface of the outer shell and the inner surface supports the flat plate. delete The method according to claim 1,
Wherein the heat insulating portion insulates the inner shell and transfers the inner pressure of the inner shell to the outer shell. The method according to claim 1,
Wherein the inner shell is disposed with a wrinkle shape for absorbing heat shrinkage of the inner shell being spaced apart at regular intervals. The method according to claim 1,
Wherein the plurality of heat insulating materials are mounted inside the outer shell such that tapered surfaces of two adjacent heat insulating materials face each other. 6. The method of claim 5,
Wherein the inner surface of the heat insulating material is in close contact with the flat plate. delete The method according to claim 1,
Wherein an angle at which both ends of each flat plate are bent has a size such that the assembled shape of the plurality of flat plates corresponds to the curved surface of the outer shell. An inner shell in which liquefied gas is stored, the inner pressure of which is maintained above atmospheric pressure;
An outer shell surrounding the inner shell to be spaced apart from the inner shell, the outer shell including a curved surface;
A protective shell disposed between the inner shell and the outer shell to be spaced apart from the inner shell and the outer shell, respectively; And
And a heat insulating portion provided in a space between the inner shell, the protective shell and the outer shell,
The heat-
Wherein both sides of the outer surface of the curved surface facing the outer shell and the inner surface of the plane facing the protective shell having a smaller area than the outer surface are provided in a space between the outer shell and the protective shell, A plurality of first heat insulators formed,
And a plurality of second insulation provided in a space between the protective shell and the inner shell,
Wherein a portion of the protective shell corresponding to a curved surface of the outer shell is formed by assembling a plurality of flat plates bent at both ends,
Wherein the outer surface of the first insulation is in close contact with the curved surface of the outer shell and the inner surface supports the flat plate. 10. The method of claim 9,
Wherein the plurality of first heat insulating materials are mounted inside the outer shell such that the tapered surfaces of two adjacent first heat insulating materials face each other. 10. The method of claim 9,
Wherein the plurality of second heat insulators are formed such that respective inner side surfaces and outer side surfaces thereof are directed to the inner side surfaces of the inner shell and the protective shell respectively and the tapered surfaces of the two adjacent second thermal insulators are spaced apart from each other, Mounted on the inside of the shell,
Wherein the heat insulating portion further includes a plurality of connection heat insulating members inserted into a space between the spaced apart tapered surfaces,
The width of the outer surface of the joint thermal insulator is equal to or smaller than the width of the inner surface,
Wherein an outer width of the space between the spaced apart tapered surfaces is equal to or less than an inner width. 12. The method of claim 11,
And the connection heat insulating material can be inserted into the space between the spaced tapered surfaces so as to be inserted in the direction from the inner surface of the second heat insulating material toward the outer surface of the second heat insulating material. 12. The method of claim 11,
Wherein the inner surface of the first heat insulator is in close contact with the flat plate,
Wherein said inner surface of said secondary insulation is in contact with at least a portion of said inner shell. 10. The method of claim 9,
Wherein the protective shell is disposed outside the lower portion of the inner shell. 15. The method of claim 14,
Wherein the protective shell is made of the same material as the inner shell. 10. The method of claim 1 or 9,
Further comprising a plurality of spaced apart spaced apart spacers between the inner shell and the outer shell to prevent movement of the heat insulating material.

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