The present invention relates to an impermeable and thermally insulated tank, and in particular the present invention relates to tanks designed to contain cold liquids, for example tanks for storing and/or transporting liquefied gases by sea.
Impermeable and thermally insulated tanks can be used in different industries to store hot or cold products. For example, in the field of energy, liquefied natural gas (LNG) is a liquid that can be stored at atmospheric pressure at approximately −163° C. in onshore storage tanks or in tanks carried on board floating structures.
Such a tank is described, for example, in document FR-A-2724623.
According to one embodiment, the invention provides an impermeable and thermally insulated tank built into a structure that includes a load-bearing wall, said tank having a tank wall attached to said load-bearing wall, the tank wall comprising:
a thermally insulating barrier attached to the load-bearing wall and made of cuboid shaped insulating blocks, juxtaposed in parallel rows separated from one another by gaps;
an impermeable barrier supported by the thermal insulation barrier, the impermeable barrier comprising a metal membrane formed of metal sheets welded together in an impermeable manner;
each insulating block of the thermally insulating barrier carrying, on the face opposite the load-bearing wall, at least two substantially orthogonal metal connecting strips, arranged parallel to the sides of the insulating blocks, the sheets of the metal membrane carried by the insulating blocks being welded to the strips, the connecting strips being rigidly connected to the insulating blocks bearing same;
a plurality of sheets of the metal membrane each having at least two orthogonal folds parallel to the sides of the thermally insulating blocks, said folds being inserted in the gaps formed between the insulating blocks.
According to the invention, such tank may have one or more of the following features.
According to an embodiment, the sheets of the metal membrane each have at least two orthogonal folds parallel to the sides of the thermally insulating blocks, inserted in the gaps formed between the insulating blocks.
According to an embodiment, the tank wall has a primary element and a secondary element arranged between the load-bearing wail and the primary element, both the primary element and the secondary element including a thermal insulation barrier made up of cuboid insulating blocks, juxtaposed in parallel rows and an impermeable barrier arranged on the thermal insulation barrier, the thermal insulation barrier of the secondary element being rigidly connected to the load-bearing wall, the thermal insulation barrier of the primary element being rigidly connected using attaching means connected to the thermal insulation barrier of the secondary element.
According to an embodiment, the impermeable barrier of the secondary element is formed by the metal membrane comprising a plurality of sheets each having at least two orthogonal folds parallel on the sides of the thermal insulating blocks, inserted in the gaps formed between the insulating blocks of the secondary element.
According to an embodiment, the sheets of the metal membrane of the secondary element are made of an alloy of iron with nickel or manganese, having a coefficient of expansion not exceeding 7×10−6 K−1.
According to an embodiment, the folds of the metal sheets of the secondary impermeable barrier are inserted into the gaps between the insulating blocks of the thermal insulation barrier of the secondary element.
According to an embodiment, the folds of the metal sheets of the primary impermeable barrier are inserted into the gaps between the insulating blocks of the thermal insulation barrier of the primary element. According to other embodiments, the primary membrane may have a different design from the secondary membrane, for example with folds projecting into the tank. In other words, the impermeable barrier of the primary element is formed of metal sheets welded together in an impermeable manner, with folds oriented towards the inside of the tank.
According to an embodiment, an insulating block of the thermal insulation barrier has a base plate on which is arranged a foam layer, in particular a polyurethane foam, the base plate overhanging the foam. The plates may be made of plywood. The secondary element is held against the load-bearing wall using fixtures welded to the load-bearing wall and cooperating with the overhanging areas of the plates of the insulating block, optionally with the interposition of a resin bead to correct any localized imperfections in the load-bearing wall.
According to an embodiment, an insulating block of the thermal insulation barrier of the secondary element is held on the load-bearing wall by bonding.
Numerous different arrangements of the connecting strips on the insulating blocks are, possible, in particular with regard to the position and the number of connecting strips on an insulating block. In this regard, the insulating blocks are not necessarily all identical.
According to an embodiment, the connecting strips of each insulating block of the thermal insulation barrier of the secondary element carries two connecting strips that are arranged along the two axes of symmetry of a rectangle defined by the large face of said insulating block.
According to an embodiment, the connecting strips of each insulating block of the thermal insulation barrier of the primary element are arranged in the vicinity of the edges of the large face of the insulating block.
According to an embodiment, an insulating block has three connecting strips arranged on the cover plate.
According to an embodiment, the connecting strips of an insulating block are seated in recesses formed in the plate or the foam layer bearing same so as not to increase the thickness on the corresponding face of the insulating block.
According to an embodiment, a connecting strip of an insulating block is attached to the recess of same by screwing, stapling, riveting or bonding.
According to an embodiment, the attachment means of the thermal insulation barrier of the primary element include a continuous metal plate arranged at the crossing of two connecting strips of each insulating block of the secondary element, and a projecting member crossing the impermeable barrier of the secondary element without reaching the impermeable barrier of the primary element.
According to an embodiment, the adjacent metal sheets of the impermeable barriers of the primary and secondary elements are welded such as to overlap with the connecting strips carried respectively by the thermal insulation barriers of the primary and secondary elements.
According to an embodiment, the projecting members are studs, the bases of which are attached to the continuous metal plate of the insulating block of the secondary element, an intermediate part being interposed between, on the one hand, a nut cooperating with the thread provided at the free extremity of the stud and on the second hand, with the overhanging parts of the plates of the insulating blocks of the thermal insulation barrier of the primary element. The bases of the studs are attached by welding and/or screwing to the continuous metal plate of the insulating block of the secondary element.
According to an embodiment, the sheets of the metal membranes, which form the impermeable barrier, are rectangular and each have two folds formed along the axes of symmetry of the rectangle formed by the edges of same.
According to an embodiment, the two folds of a sheet and the impermeable barrier of the primary element intersect at the center of the rectangular sheet.
According to an embodiment, one of the folds of a sheet is continuous and the other is interrupted in the central portion of same.
According to an embodiment, the sheets of a first type have continuous fold along the major axis of same.
According to an embodiment, the sheets of a second type have a discontinuous fold along the major axis of same.
According to an embodiment, on one tank wall, the sheets of the first and second types are regularly alternated so that a sheet of one of the types is always adjacent to a sheet of the other type.
According to an embodiment, each insulating block of the thermal insulation barrier has two series of orthogonal slots, each of the series having slots arranged parallel to two opposing sides of the insulating block, and the sheets of the metal membrane each having two series of supplementary folds, each of the series of supplementary folds having folds orthogonal to the folds in the other series, parallel to one of the two folds inserted in the gaps, and inserted in the slots of one of the series of slots formed in the insulating block.
According to another embodiment, the metal membrane has a second plurality of sheets, each of the sheets in the second plurality having a single fold parallel to two opposing sides of the insulating blocks, said fold being inserted into a gap formed between two insulating blocks.
According to another embodiment, each insulating block of the thermal insulation barrier has a slot parallel to two opposing sides of the insulating blocks and in which the metal membrane has a second plurality of sheets, each of the sheets in the second plurality having a fold inserted in a slot formed in an insulating block and a fold inserted in a gap formed between two insulating blocks.
Such a tank may be part of an onshore storage facility, for example for storing LNG, or be installed on a coastal or deep-water floating structure, notably an LNG carrier ship, a floating storage and regasification unit (FSRU), a floating production, storage and offloading (FPSO) unit, among others.
According to an embodiment, a ship used to transport a cold liquid product has a double hull and the aforementioned tank arranged in the double hull.
According to an embodiment, the invention also provides a method for loading onto or offloading from such a ship, in which a cold liquid product is channeled through insulated, pipes to or from an onshore or floating storage facility to or from the tank on the ship
According to an embodiment, the invention also provides a transfer system for a cold liquid product, the system including the aforementioned ship, insulated pipes arranged to connect the tank installed in the hull of the ship to an onshore or floating storage facility and a pump for driving a flow of cold liquid product through the insulated pipes to or from the onshore or floating storage facility to or from the tank on the ship.
An idea at the heart of the invention is to provide an impermeable and insulating multi-layer structure that is easy to build over large surfaces. Certain aspects of the invention are based on the idea of building insulating blocks that have simple geometry and are inexpensive to manufacture. Certain aspects of the invention are based on the idea of providing an impermeable membrane, in particular a secondary membrane made of steel sheet with a low coefficient of, expansion, for example Invar® (known generically as 64FeNi) or other, of limited thickness, in particular not exceeding 0.7 mm, thereby achieving limited stiffness which enables anchoring at the edges of the tank wall using relatively small anchoring means.
The invention is further explained, along with additional objectives, details, characteristics and advantages thereof, in the detailed description below of several specific embodiments of the invention given solely as non-limiting examples, with reference to the drawings attached.
In these drawings:
In the different variants shown in the drawings, the components that perform the same function have been identified using the same reference signs, even if the implementation of same is not identical.
In the drawings, reference sign I refers, as a hole, to an insulating block of the thermal insulation barrier of the secondary element of a tank wall. The block has a length L and a width I, for example, respectively, 3 m and 1 m; it has a cuboid shape and it is made of polyurethane foam between two plywood plates. One of the plates 2a overhangs the edge of the foam and is intended to bear against the load-bearing wall 3 with the interposition of resin beads 4 designed to correct the local defects in the load-bearing wall 3. The other plate 2b of the insulating block includes, along the two axes of symmetry of same, a metal connecting strip 6, which is placed in a recess 7 and which is attached there using screws, rivets, staples or adhesive. In the crossing zone of the strips 5 and 6 there a continuous metal plate, which bears, at the center of the crossing of the strips, a stud 8 projecting above the plate 2b. The plate 2a is held on the load-bearing wall 3 by bonding using resin beads 4, as well as using studs 9 welded onto the load-bearing wall 3. A gap 10 is formed between two adjacent blocks 1, for example caused by the presence of the overhanging parts of the plate 2a, or potentially using positioning blocks.
As shown in
According to a preferred embodiment, the metal sheets 11 are made of a manganese-based alloy having a coefficient of thermal expansion substantially equal to 7×10−6 K−1 Such alloys are usually less expensive than alloys with a high nickel content, such as Invar®.
With reference to
Finally,
The connecting strip 6 is continuous at the intersection with the connecting strip 5 such as to form an impermeable zone 39 to which the corners of four sheets 11 can be welded around the stud 18. As such, there is no need to perforate a sheet 11 to enable the stud 18 to pass through towards the primary element of the tank wall. Throughout the remaining length of same, the connecting strips 5 and 6 are preferably formed of discontinuous juxtaposed segments in order to limit the stress resulting from thermal contraction, in particular stress in the welds with the sheets 11
In the figures, in particular
Conversely,
The creased sheets A to R have in each instance simple folds or simple corrugations, which facilitates the assembly of same using impermeable welds. They may be combined in multiple layouts enabling in each instance a certain elongation of the metal membrane in both directions of the plane. The preferred layouts are shown in
In a variant not shown, two types of sheet are alternated similarly to
In one embodiment shown in
Furthermore, as shown in
In
The sheets 11 welded in an overlapping manner onto four adjacent insulating blocks 1 each have orthogonal folds 12a, 12b inserted into the gaps 10 formed between the insulating blocks 1. Each of the sheets 11 welded in an overlapping manner onto to adjacent insulating blocks 1 has only one fold 12b inserted between the two adjacent insulating blocks 1 between which it extends.
At the center of the crossings between the connecting strip 6 and the connecting strips 5a, 5b, the insulating blocks 1 include a stud 18 projecting towards the inside of the tank and enabling attachment of the insulating blocks 13 of the primary thermal insulation barrier.
The embodiment shown in
Other variants of corrugated sheets and other combinations can be realized by changing the different features, in particular the spacing of the corrugations, the number of corrugations per sheet, the length of the discontinuous corrugations (number of steps), the form of the intersections between the corrugations, namely intersecting or non-intersecting, the orientation of the continuous corrugations, namely longitudinal or transverse orientation, and the orientation of the sheets themselves, namely horizontal orientation or vertical orientation (90° rotation), and the combinations of such modifications.
The tanks described above may be used in different types of facilities such as onshore facilities or in a floating structure such as an LNG carrier ship or other.
With reference, to
In a known manner, the loading/offloading pipes arranged on the upper deck of the ship can be connected, using appropriate connectors, to a sea or port terminal to transfer a cargo of LNG to or from the tank 71.
To create the pressure required to transfer the liquefied gas, pumps carried on board the ship 70 and/or pumps installed at the onshore facility 77 and/or pumps installed on the loading/offloading station 75 are used.
Although the invention has been described in relation to several specific embodiments, it is evidently in no way limited thereto and it includes all of the technical equivalents of the means described and the combinations thereof where these fall within the scope of the invention.
Use of the verb “comprise” or “include”, including when conjugated, does not exclude the presence of other elements or other steps in addition to those mentioned in a claim. Use of the indefinite article “a” or “one” for an element or a step does not exclude, unless otherwise specified, the presence of a plurality of such elements or steps.
Number | Date | Country | Kind |
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1259622 | Oct 2012 | FR | national |
This application is a continuation of U.S. application Ser. No. 14/434,634 filed Apr. 9, 2015, which is a national stage application of International Application No. PCT/FR2013/052411 filed Oct. 9, 2013, which claims priority to French Patent Application No. 1259622 filed Oct. 9, 2012, of which the disclosures are incorporated herein by reference and to which priority is claimed.
Number | Date | Country | |
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Parent | 14434634 | Apr 2015 | US |
Child | 15363337 | US |