The present invention is related to a reinforcing member for a corrugated membrane of an LNG cargo tank, more specifically to a reinforcing member for improving the pressure resistance property of a membrane having corrugation, a membrane assembly having the reinforcing member and a method of constructing the membrane assembly.
LNG (liquefied natural gas) generally refers to colorless, transparent cryogenic liquid converted from natural gas (predominantly methane) that is cooled to approximately −163° C. and condensed to 1/600th the volume.
As LNG emerges as an energy source, efficient transportation means have been sought in order to transport LNG from a supply site to a demand site in a large scale so as to utilize LNG as energy. Resulted in a part of this effort is LNG carriers, which can transport a large quantity of LNG by sea.
LNG carriers need to be furnished with a cargo that can keep and store cryogenically liquefied LNG, but such carriers require intricate and difficult conditions. That is, since LNG has vapor pressure that is higher than atmospheric pressure and boiling point of approximately −163° C., the cargo that stores LNG needs to be constructed with materials that can withstand very low temperature, for example, aluminum steel, stainless steel and 33% nickel steel, and designed in a unique insulation structure that can withstand thermal stress and thermal contraction and can be protected from heat leakage, in order to keep and store LNG safely.
Particularly, membranes, which are the primary barrier of the cargo, are in direct contact with the cryogenic LNG with its temperature of −163° C., and thus are made of metallic materials, such as aluminum alloy, the Invar, 9% nickel steel, etc., which are strong against brittleness at a low temperature and can address changes in stress. Membranes also have linear corrugations, in which the center is bulged, in order to allow easier expansion and contraction in response to repeated changes in temperature and change in the weight of the stored liquid. In addition, membranes have weld zones that help keep the tank leak-proof by fold-welding edges of a plurality of membrane panels.
In the conventionally-used membranes, the membranes are made in an approximately rectangular shape, and a plurality of corrugations are formed throughout the membrane panels in order to facilitate expansion and contraction in response to heat and load. Moreover, corners and 4 sides of a single membrane panel, which encompasses the plurality of corrugations, are overlapped and connected by welding with corners and 4 sides of neighboring membrane panels to make the tank leak-proof.
However, since the corrugations of the conventional membranes are bulged, the membranes are expected to collapse easily under increased hydrostatic or dynamic pressure in the cargo as LNG carriers become increasingly bigger. For example, the hydrostatic pressure applied by liquefied gas may cause considerable plastic deformation of the corrugations, and particularly, lateral faces of the corrugations that are at a certain distance away from intersecting corrugations may be crushed.
There have been a number of efforts to reinforce the rigidity of the corrugations, for example, increasing the thickness of the membrane, but these efforts have had problems such as decreased flexibility. As illustrated in
However, as illustrated in
The present invention provides a reinforcing member for a membrane that can prevent the collapse of corrugations without increasing the facial rigidity of the corrugations by being placed inside the corrugations of the membrane, as well as a membrane assembly having the reinforcing member and a method of constructing the membrane assembly.
An aspect of the present invention features a reinforcing member for a membrane installed in an insulating structural member of an LNG cargo and having a corrugation, the reinforcing member being disposed between the insulating structural member and the corrugation and reinforcing the rigidity of the corrugation.
A material of the reinforcing member can be nonflammable foam. A sectional shape of the reinforcing member can be a circle or can be identical to a sectional shape of the corrugation.
The reinforcing member can also include a reinforcing pipe installed inside the corrugation, and the reinforcing member can be mounted in the reinforcing pipe and installed inside the corrugation. Here, a sectional shape of the pipe can be a circle or can be identical to a sectional shape of the corrugation.
Another aspect of the present invention features a reinforcing member for a membrane installed in an insulating structural member of an LNG cargo and having a corrugation, which can include a reinforcing member installed inside the corrugation so as to prevent deformation of the corrugation. The reinforcing member can be formed with a path through which gas injected for a leak test or dehumidification of the corrugation can flow.
Here, a material of the reinforcing member can be nonflammable foam or a wooden material.
A sectional shape at either end of the reinforcing member can be identical to a sectional shape of the corrugation. The path can be a hemispherical or polygonal shape depressed in a lengthwise direction of the reinforcing member. The path can include a first path formed on an upper surface of the reinforcing member and a second path formed on a lower surface of the reinforcing member.
Yet another aspect of the present invention features a reinforcing member for a membrane for reinforcing the rigidity of a corrugation furnished in a membrane coupled to an insulating structural member, the reinforcing member being disposed between the insulating structural member and the corrugation, the reinforcing member including: a bottom portion the external face of which is flat so that the bottom portion can be in contact with the insulating structural member; a supporting portion having an external face corresponding to an internal face of the corrugation so that the supporting portion can be in contact with the internal face of the corrugation; and a reinforcing body in a shape of a pipe, the pipe having a cross section of a closed curve.
The reinforcing member can also include a supplementary reinforcing means disposed inside the reinforcing body and supporting an internal face of the reinforcing member. The supplementary reinforcing means can include a reinforcing pipe the cross section of which is a circular shape. The supplementary reinforcing means can include a plurality of reinforcing spokes radially extended from a center of the reinforcing body toward an outside of the reinforcing body so that the supplementary reinforcing means can be in contact with an internal face of the reinforcing body.
The reinforcing member can also include an insulating member disposed inside the reinforcing body and improving an insulating property. A path through which gas injected for a leak test or dehumidification of the corrugation can flow can be formed inside the insulating member.
A surface hardness of the reinforcing body can be lower than that of the membrane. The reinforcing member can also include a buffering member coupled to an external face of the reinforcing body and attenuating impact loadings.
The reinforcing body can include an insertion hole for coupling with the insulating structural member. The reinforcing member can also include a pressing-in means disposed at an end of the reinforcing body so that the pressing-in means can be in contact with an internal face of the corrugation and plastically deformed to fix the reinforcing body inside the corrugation. The pressing-in means can be formed by deforming a portion of the reinforcing body so that the pressing-in means can be in contact with an inside of the corrugation and plastically deformed.
The reinforcing member can also include an extension extended from an end of the bottom portion of the reinforcing body toward an outside. The pressing-in means can include a coil portion, which is wound on the extension, and a pair of arms extended from either end of the coil portion toward an internal face of the corrugation so that the arms can be in contact with the internal face of the corrugation and plastically deformed.
Still another aspect of the present invention features a membrane assembly, which can include: an insulating structural member having a flat surface; a membrane coupled to the flat surface of the insulating structural member and having a plurality of corrugations protruded toward an outside; and a reinforcing member disposed between the insulating structural member and the corrugation and including a bottom portion, an external face of the bottom portion being flat so as to be in contact with the insulating structural member, and a supporting portion having an external face corresponding to an internal face of the corrugation so as to be in contact with the internal face of the corrugation, and a reinforcing body in a shape of a pipe, a cross section of the pipe being a closed curve.
The reinforcing member can include an insertion hole, and the membrane assembly can also include a fixing means coupled to the insulating structural member by penetrating the insertion hole in order to fix the reinforcing member to the insulating structural member.
A concavity caved in toward the insulating structural member can be formed at an end of the corrugation, and an end of the reinforcing body can be furnished with a pressing-in means being in contact with an internal face of the concavity and plastically deformed so that the reinforcing body can be fixed inside the corrugation.
Another aspect of the present invention features a method of constructing a membrane assembly including a membrane having a corrugation and an insulating structural member having a flat surface to which the membrane is couple. The method in accordance with an embodiment of the present invention can include: a) disposing a reinforcing member between an internal face of the corrugation and the surface of the insulating structural member, the reinforcing member including a bottom portion and a supporting portion, the bottom portion having an external face corresponding to the surface of the insulating structural member, the supporting portion having an external face corresponding to the internal face of the corrugation; and b) coupling the membrane to the surface of the insulating structural member so that the internal face of the corrugation is in contact with an external face of the reinforcing member.
The step of a) cab include adhering the reinforcing member to one of the internal face of the corrugation and the surface of the insulating structural member by use of an adhesive.
The step of a) can include fixing the reinforcing member to the surface of the insulating structural member by inserting a fixing means protruded from one of the insulating structural member and the reinforcing member into the other of the insulating structural member and the reinforcing member.
The step of a) can include pressing in the reinforcing member into the corrugation by allowing a portion of the reinforcing member to be in contact with the internal face of the corrugation and plastically deforming the portion of the reinforcing member.
As described above, the reinforcing member for a membrane in accordance with the present invention can prevent the collapse of the corrugation and attenuate shocks without increasing the facial rigidity of the corrugation of the membrane, and improve the insulating property by forming an additional insulating layer.
Moreover, the reinforcing member for a membrane in accordance with the present invention can allow a more accurate leak test by providing fluidity of gas injected for the purpose of a leak test or dehumidification.
Furthermore, the reinforcing member for a membrane in accordance with the present invention can improve the impact attenuation property by providing a buffering member with a polymer material on an external face of the reinforcing member.
Since there can be a variety of permutations and embodiments of the present invention, certain embodiments will be illustrated and described with reference to the accompanying drawings. This, however, is by no means to restrict the present invention to certain embodiments, and shall be construed as including all permutations, equivalents and substitutes covered by the ideas and scope of the present invention. Throughout the description of the present invention, when describing a certain technology is determined to evade the point of the present invention, the pertinent detailed description will be omitted.
Hereinafter, certain embodiments of the present invention will be described in detail with reference to the accompanying drawings. Identical or corresponding elements will be given the same terms and the same reference numerals, regardless of the figure number, and any redundant description of the identical or corresponding elements will not be repeated.
Described with reference to
Here, in accordance with the feature of the present invention, a reinforcing member 30, 31 having a particular shape is filled inside the corrugation in order to complement the rigidity of the corrugation.
While it can be preferable that the reinforcing member 30, 31 is filled in the lengthwise direction of a corrugation 25 such as the first corrugation 5 and the second corrugation 6, it is more preferable that the reinforcing member 30, 31 is filled in the second corrugation only in order to meet the required rigidity.
For the reinforcing member 30, 31, phenol foam or other nonflammable foams can be used. As illustrated in
Meanwhile, in case a greater rigidity than the reinforcing member 30, 31 made of nonflammable foam is required, the reinforcing member 30, 31 can be made of synthetic resin, which is then mounted in a pipe 70, 71, the interior of which is hollow, and installed inside the corrugations together with the pipe 70, 71.
The pipe 70, 71 made by adding, for example, glass fiber in synthetic resin can be also installed lengthwise in both the first corrugation 5 and the second corrugation 6 or in the second corrugation 6 only.
As illustrated in
The membrane of an LNG cargo with the aforementioned structured functions as described below with reference to
Here,
These diagrams show results of interpreting deformation and stress in a cryogenic condition, while it is assumed that the nonflammable foam used as the reinforcing member 30, 31 has the rigidity of 140 MPa and the coefficient of thermal expansion of 53×10−6 m/m° C. at an ultralow temperature, that its lower portion is in contact with an insulating structural member 22, and both ends of the primary barrier is symmetric.
Referring to
As described earlier, a membrane 20 forming the first barrier in an LNG carrier makes direct contact with the cryogenic LNG at the temperature of −163° C., and thus uses metallic materials such as aluminum alloy, the Invar and 9% nickel steel that are strong against brittleness at a low temperature and can handle the change in stress. Moreover, corrugations 25, the center of which is protruded, can be formed throughout a metal panel so that the membrane 10 can be readily expanded and contracted in a rectangular shape in response to the repeated change of temperature and the change in the load of the stored liquid.
The corrugations 25 are constituted by a first corrugation (see reference numeral 5 in
Here, in order to reinforce the rigidity of the corrugations 25, a reinforcing member 40 is inserted and positioned inside the first corrugation (see reference numeral 5 in
For the reinforcing member 40, nonflammable foam, such as phenol foam, and wooden material can be used. The sectional shape of the reinforcing member 40 can be a curved shape that is identical to the sectional shape of the inside of the corrugations 25 so that the reinforcing member 40 can be tightly fit in the corrugations 25. A path 50 can be formed on the reinforcing member 40.
The path 50 can be formed on an upper surface or a lower surface of the reinforcing member 40, and it is possible that a first path 51 is formed on the upper surface and the second path 52 is formed on the lower surface. Moreover, as illustrated in
The first path 51 and the second path 52 can be formed in a hemispherical concave shape or a polygonal concave shape along the lengthwise direction of the reinforcing member 40 in order to provide the fluidity of gas injected for dehumidification or leak-test of the membrane 20.
Described below is how the reinforcing member for a membrane described in the above structure works.
The hydrostatic pressure applied by liquid gas can cause a significant plastic deformation where no reinforcing member 40 is inserted in the corrugations 25. Therefore, in the present invention, the reinforcing member 40 made of nonflammable foam, such as phenol foam, or a wooden material is inserted and placed inside the first corrugation (see reference numeral 5 in
The reinforcing member 40 can be snuggly inserted inside the first corrugation (see reference numeral 5 in
Since the coefficient of thermal expansion of the reinforcing member 40 inserted inside the first corrugation (see reference numeral 5 in
Moreover, by forming flow paths that allow the gas injected for a leak test or dehumidification of the membrane 20 to flow smoothly, the first path 51 and the second path 52 formed on the reinforcing member 40 can improve the reliability of the leak test and facilitate the dehumidification. Furthermore, the first path 51 and the second path 52 can reduce the overall weight of the reinforcing member 40 without affecting the structural rigidity of the reinforcing member 40.
Therefore, by inserting and placing the reinforcing member in the corrugations, deformation of the corrugations can be prevented, and gas injected for a leak test or dehumidification can be flowed so that a more accurate leak test can be performed and the insulating efficiency can be improved through dehumidification.
As illustrated in
The membrane 20 has a flat portion 24, which is coupled to the surface 21 of the insulating structural member 22, and a plurality of corrugations 25, which are protruded to the outside of the insulating structural member 22. The membrane 20 is most commonly made of a metallic material, but can be made of other materials. The insulating structural member 22 can be made of plywood or other various materials so that it can form an insulating sealed wall together with the membrane 20.
The reinforcing member 110 functions to reinforce the rigidity of the corrugation 25, the plasticity of which can be more easily deformed than the flat portion 24 under high hydrostatic pressure or dynamic pressure. The reinforcing member 110 includes a reinforcing body 111, which includes a bottom portion 113 that is in contact with the surface 21 of the insulating structural member 22 and a supporting portion 112 that is in contact with the internal face of the corrugation 25. The external face of the bottom portion 113 is made flat so as to be tightly in contact with the surface 21 of the insulating structural member 22, and the external face of the supporting portion 112 is curved according to the shape of the internal face of the corrugation 25.
As the reinforcing member 110 is made in the shape of a pipe that has the cross-sectional shape of a closed curve, the reinforcing member 110 has a great structural rigidity and can stably support the internal face of the corrugation 25 against the pressure exerted to the corrugation 25. It is preferable that the reinforcing member 110 has lower hardness than the membrane 20 so as to reduce any damage by friction of the membrane 20.
For this, the reinforcing member 110 can be made of a material that has a lower hardness than that of the membrane 20. For example, in case the membrane 20 is made of stainless steel, the reinforcing member 110 can be made a material with lower hardness, for example, aluminum or brass. Alternatively, the surface hardness of the reinforcing member 110 can be lowered regardless of the material of the reinforcing member by coating the external face of the reinforcing member 110 with a low-hardness metal or polymer.
The reinforcing member 110 can maintain its adhesion state with the insulating structural member 22 without any additional coupling means because the reinforcing member 110 is pressed to the surface 21 of the insulating structural member 22 by the corrugation 25 when the membrane 20 is coupled to the surface 21 of the insulating structural member 22.
A membrane assembly 101 shown in
A membrane assembly 102 shown in
The supplementary reinforcing means for improving the rigidity of the reinforcing member in accordance with the present invention are not restricted to the structures illustrated in
A membrane assembly 103 shown in
Moreover, a path 141 is formed inside the insulating member 140 to allow a fluid, such as gas, injected for a leak test or dehumidification of the membrane 20 to flow through.
A membrane assembly 104 shown in
Not only does the buffering member 150 attenuate impact loadings, but the buffering member 150 reduces friction between the reinforcing member 110 and the insulating structural member 22 and between the reinforcing member 110 and the corrugation 25, thereby preventing any damage on the surface of the reinforcing member. Used for the buffering member 150 can be a polymer coating layer or other various elastic materials.
A membrane assembly 105 shown in
In a membrane assembly 106 shown in
The hook-type fixing member 160 can be coupled to the insulating structural member 22 by use of an adhesive, welding, or other mechanical methods, depending on its material. The hook-type fixing member 160 has a hook 161 that is vertically protruded from the surface 21 of the insulating structural member 22, and the reinforcing member 110 is fastened to the insulating structural member 22 by inserting the hook 161 into an insertion hole 116 formed at the bottom portion 113 of the reinforcing member 110.
A membrane assembly 107 shown in
The hook-type plug 170 has a head portion 171, which is bigger than the insertion hole 117, and a hook 173, which is inserted into the coupling hole 26 to make it difficult to disengage. The hook-type plug 170 fastens the reinforcing member 110 to the insulating structural member 22 by being inserted to the coupling hole 26 through the insertion hole 117 inside the reinforcing member 110.
By using the hook-type fixing member 160 shown in
A membrane assembly 108 shown in
As illustrated in
As illustrated in
The reinforcing members shown in
A reinforcing member 200 shown in
A pair of latches 207 protruded toward the outside are formed on either lateral side of the closed elastic deforming portion 205. The latches 207, which correspond to the pair of concave surfaces 68 of the corrugation 62, can be pressed into the concave surface 68 to be plastically deformed so as to fix the reinforcing body 201 inside the corrugation 62. Formed at either end of the reinforcing body can be slopes 203 corresponding to the undulations 66 formed at either end of the corrugation 62.
A reinforcing member 201 shown in
The closed elastic deforming portion 205 or open elastic deforming portion 215 in accordance with the present invention is not restricted to what portions of the reinforcing body 201, 211 are deformed as illustrated and described. That is, it is also possible that the closed elastic deforming portion 205 or open elastic deforming portion 215 is separately fabricated and then coupled to the reinforcing body 201, 211.
A reinforcing member 230 shown in
Since the reinforcing members 200, 210, 230 shown in
Number | Date | Country | Kind |
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10-2008-0019481 | Mar 2008 | KR | national |
10-2009-0000333 | Jan 2009 | KR | national |
10-2009-0009676 | Feb 2009 | KR | national |
This application is a continuation of U.S. application Ser. No. 14/522,757 filed on Oct. 24, 2014, which is a divisional of U.S. patent Ser. No. 12/920,446, filed Aug. 31, 2010, which is a continuation of PCT/KR09/01035, filed Mar. 3, 2009, which claims the benefit of Korean Patent Applications Nos. 10-2009-0009676 filed on Feb. 6, 2009, 10-2009-0000333 filed on Jan. 5, 2009, and 10-2008-0019481 filed on Mar. 3, 2008, the disclosures of which are incorporated herein in its entirety by reference.
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Number | Date | Country | |
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20170108169 A1 | Apr 2017 | US |
Number | Date | Country | |
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Parent | 12920446 | Aug 2010 | US |
Child | 14522757 | US |
Number | Date | Country | |
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Parent | 14522757 | Oct 2014 | US |
Child | 15336474 | US | |
Parent | PCT/KR2009/001035 | Mar 2009 | US |
Child | 12920446 | US |