EP2733410A2 - LNG tank with insulation panels. - Google Patents

Abstract

The tank has a primary sealing barrier (10), a secondary sealing barrier (5) and a thermal insulation barrier, where each barrier includes a rectangular parallelepiped module provided with a plywood plate (3) covered by a thermal insulation layer (4). The layer is covered by the secondary barrier on which another thermal insulation layer (6) i.e. T-shaped thermal insulation layer, is arranged. Another plywood plate (7) is constituted of two walls (8, 9), where the first wall supports the primary barrier and the second wall. A damping layer (11) is arranged between the walls. The walls are made of a fir plywood or composite material.

Description

Improvement for waterproof and thermally insulating tank integrated into a supporting structure.

The present invention relates to an improvement for a sealed and thermally insulating tank integrated into a supporting structure.

According to the documents FR-2,527,544-A , FR-1 376 525-A , FR-1 379 651-A , FR-2,724,623-A and FR-2 798 902-A , it is known a sealed and insulating tank which is integrated into a supporting structure, including ship, and which comprises two successive sealing barriers: one primary, in contact with the product contained in the tank and the other secondary disposed between the primary sealing barrier and the supporting structure. Between these two sealing barriers, on the one hand, and between the secondary sealing barrier, on the other hand, is disposed at least one thermally insulating barrier. According to these documents, the primary sealing barrier is made of metal and the secondary metal or composite sealing barrier may comprise a metal core. The thermally insulating barriers are made in the form of modules, or panels, juxtaposed, of general polygonal shape, whose thickness is determined according to the desired insulating power. These modules include a cover and a bottom designated indistinctly by the term "plate". The term "primary thermally insulating barrier" designates that on which the primary sealing barrier rests, and the term "secondary thermal barrier" means that on which the secondary sealing barrier rests.

In use, it has been found a deterioration of the primary sealing barrier constituted by metal strakes, in particular caused by sloughing or, according to the English terminology, "sloshing" in particular on the ceiling of the tanks or in the embankment area and above them. In addition, the primary thermally insulating barrier can also undergo degradation of both the thermal insulation layer, the rigid plate constituting the support of this primary thermal insulation barrier.

But, likewise, it has sometimes been found a deterioration of the secondary sealing barrier and / or the secondary thermally insulating barrier.

It is therefore an object of the present invention to provide an improvement for such sealed and thermally insulating vessels integrated into a supporting structure such as a ship's hull, which makes it possible to avoid or at least to limit damage. of the tank as reported above.

Another object of the invention is to provide such an improvement which results in as little structural modification as possible.

An additional aim of such an improvement is not to substantially increase the cost of such a tank.

Another object of the invention is to provide such an improvement which makes it possible to improve, at an acceptable cost, the sealed insulating tanks integrated in a supporting structure.

These and other objects which will appear later are achieved by an improvement for a sealed and thermally insulating tank integrated in a supporting structure constituted by a double wall, which tank is of the kind comprising two sealing barriers, the one primary and one secondary, and at least one thermal insulation barrier secured to the supporting structure, in which is located the secondary sealing barrier and on which rests the primary sealing barrier, which improvement is, according to the present invention, characterized in that it comprises a damping device consisting of a layer of damping material disposed between two walls.

According to a first embodiment of the invention, the thermal insulation barrier is constituted by a module, which has substantially the shape of a rectangular parallelepiped and comprises a first plate, for example plywood, surmounted by a first layer thermal insulation, itself surmounted by a sealing barrier, itself attached to the upper plate of the secondary insulation, on which is disposed a second layer of thermal insulation which itself carries a second plate plywood, on which rests in a known way the primary sealing barrier constituted by strakes or metal plates, the damping device is located under the primary sealing barrier and is constituted by the second plate which is composed by the two walls between which is disposed the layer of damping material.

According to a second embodiment of the present invention, the thermal insulation barrier being constituted by a module, which has substantially the shape of a rectangular parallelepiped and comprises a first plate, for example plywood, surmounted by a first layer thermal insulation, itself surmounted by a sealing barrier on which is disposed a second layer of thermal insulation which itself carries a second plate, for example plywood, on which rests in known manner the barrier of primary sealing constituted by strakes or metal plates, the damping device is located under the secondary sealing barrier.

According to a third embodiment of the present invention, the damping device is disposed between the secondary sealing barrier and the second layer of thermal insulation.

According to a fourth embodiment of the present invention, the damping device is disposed between the first plate and the first layer of thermal insulation.

Advantageously, between the first and the second wall and passing through the layer of damping material, is disposed a deflection means depressing.

Preferably, the depression means is inserted into cavities respectively formed in the two walls, T-shaped, the free ends of the vertical bar of the T facing each other, and an H bar being disposed in the space thus delimited.

According to an alternative embodiment, the driving deflection means is inserted into cells, respectively formed in one of the walls and the other in the second layer of thermal insulation, T-shaped, the free ends of the vertical bar of the T facing each other, and an H bar being disposed in the space thus delimited.

Advantageously, the junctions between first walls are offset from those of the second.

Preferably, this junction between the first walls is identical to that between the blades of an English floor.

Advantageously, the second wall has a modulus of elasticity at least ten percent lower than that of current materials.

Preferably, the two walls have a thickness of between 9 and 21 mm.

According to a preferred embodiment of the present invention, the two walls are fir plywood or a composite material.

Advantageously, the first plate is fixed on the wall of the carrier structure with the interposition of a mastic bead having a modulus of elasticity of at most 500 MPa at a temperature of -25 ° C. and of approximately 150 MPa at a temperature of 25 ° C. ° C.

• la figure 1 représente, en coupe, perpendiculairement à la paroi d'une structure porteuse constituée par la double coque ou la double paroi transversale d'un navire, et dans une position éclatée figurant schématiquement le montage des différents éléments d'une cuve, selon l'art antérieur, dans une zone de la cuve non voisine d'un angle de la cuve ;
• la figure 2 représente, en coupe, perpendiculairement à la paroi d'une structure porteuse constituée par la double coque ou la double paroi transversale d'un navire, et dans une position éclatée figurant schématiquement le montage des différents éléments d'une cuve selon un premier mode de réalisation de la présente invention, dans une zone de la cuve non voisine d'un angle de la cuve ;
• la figure 3 représente une variante de réalisation de la présente invention selon la figure 2 ;
• la figure 4 représente un deuxième mode de réalisation de la présente invention ;
• la figure 5 représente un troisième mode de réalisation de la présente invention ; et,
• la figure 6 représente un quatrième mode de réalisation de la présente invention.

The following description, which has no limiting character, should be read with reference to the appended figures among which:

• the figure 1 represents, in section, perpendicular to the wall of a supporting structure formed by the double hull or the double transverse wall of a ship, and in an exploded position schematically showing the mounting of the different elements of a tank, according to the prior art, in a zone of the vessel not close to an angle of the tank;
• the figure 2 represents, in section, perpendicular to the wall of a supporting structure formed by the double hull or the double transverse wall of a vessel, and in an exploded position schematically showing the mounting of the various elements of a vessel according to a first embodiment of embodiment of the present invention, in a zone of the vessel not close to an angle of the vessel;
• the figure 3 represents an alternative embodiment of the present invention according to the figure 2 ;
• the figure 4 represents a second embodiment of the present invention;
• the figure 5 represents a third embodiment of the present invention; and,
• the figure 6 represents a fourth embodiment of the present invention.

The identical elements in the figures are designated by the same references.

Referring in particular to the figure 1 , denoted by the reference 1, the wall of the double hull of the ship, where is installed the tank according to the invention. It is known that a ship's hull also has transverse partitions, which cut the hull into compartments, these transverse partitions being also double: in the present description the term "double wall 1" will be designated as well the wall of the double hull than the transverse walls above, which delimit such a tank. The double walls 1 constitute the carrying structure of the tank described.

The cuvée is of the kind comprising two sealing barriers, one primary 10 and the other secondary 5, and at least one thermal insulation barrier constituted by a module, which has substantially the shape of a rectangular parallelepiped and comprises a first plywood plate 3 surmounted by a first layer of thermal insulation 4, itself surmounted by the primary sealing barrier 5 on which is disposed a second layer of thermal insulation 6 which itself carries a second plate plywood 7, on which rests in known manner the primary sealing barrier 10. The secondary and primary 5 sealing barriers 10 are constituted by strakes, preferably in invar, or metal plates which can be embossed. The assembly comprising the first plate 3 and the first thermal insulation layer 4 constitutes the module of the thermally insulating barrier secondary 2b; the assembly comprising the second plate 7 and the second layer of thermal insulation 6 constitutes the module of the primary thermally insulating barrier 2a.

As will be understood by those skilled in the art, the modules 2a and 2b have substantially the shape of a rectangular parallelepiped. The module 2a has, seen in plan, a rectangular shape whose sides are parallel to those of the module 2b: seen in plan, the two modules 2a and 2b have the form of offset rectangles, in order to limit thermal leakage and to ensure a better distribution of efforts.

• une première paroi 8 réalisée en un contreplaqué et/ou en un matériau composite et supportant la barrière d'étanchéité primaire;
• une couche 11 d'un matériau amortissant ; et,
• une seconde paroi 9 réalisée en un contreplaqué disposée au-dessus de la couche d'isolant thermique 6.

According to a first embodiment of the present invention as represented in figures 2 and 3 , the damping device is disposed under the primary sealing barrier 10 and is constituted by the second plate 7, on which rests the primary sealing barrier 10, itself constituted by a sandwich assembly which comprises:

• a first wall 8 made of a plywood and / or a composite material and supporting the primary sealing barrier;
• a layer 11 of damping material; and,
• a second wall 9 made of a plywood disposed above the thermal insulation layer 6.

The plywood constituting the first wall 8 and the second wall 9 has a thickness of between 9 and 21 mm. This second wall 9 has a modulus of elasticity in cold bending of between 10,000 and 13,000 MPa. A plywood according to the present invention is for example a fir plywood or a composite material. The modulus of elasticity of the second wall 9 is at least ten percent less than that of the walls of current materials.

As for the damping material 11 disposed between the two walls 8 and 9 above, it has a thickness of between 2 and 15 mm, and for example 8 mm: this thickness is chosen such that under the shock load considered these are damped on the one hand, and that the crushing resulting from this damping material does not lead it to ruin, on the other hand. This material may be a felt, a material based on woven or bonded fibers with or without insulating materials such as, for example, an airgel: the assembly thus produced being bonded or mechanically assembled.

According to a second embodiment of the present invention, the damping device is disposed under the secondary sealing barrier 5. It consists of two walls 8 'and 9' as previously described between which is interposed a layer 11 of damping material. In this case, one of the walls, that referenced 9 'in this case, is based on the first layer of insulating material 4, and the other wall 8' is surmounted by the secondary sealing barrier 5.

The junctions between the first walls 8 or 8 'are offset relative to those of the second walls 9 or 9' so as to ensure a better mechanical continuity of the insulating mass. This junction between the first walls 8 or 8 'is for example identical to that between the blades of an English floor.

According to an alternative embodiment of the present invention, there is disposed between the first wall 8 and the second wall 9, and thus passing through the layer of damping material 11, means of deflection depression. These comprise, according to the present embodiment, two cells, 12a and 12b respectively, T-shaped connected by the vertical bar of the T and a bar 13 H being disposed in the space thus defined.

According to an embodiment variant represented in figure 3 , the cell 12b is located, not in the second wall 9, but in the second thermal insulator layer 6 of the module 2a constituting the primary thermal insulating barrier.

It can be the same when the damping device according to the present invention is located under the secondary sealing barrier 5.

According to figure 5 relative to a third embodiment, the damping device 7 is disposed above the second sealing barrier 5 and therefore under the second layer of thermal insulation 6.

According to the fourth embodiment shown in figure 6 the damping device 7 is located between the first plate 3 of the secondary thermally insulating barrier module 2b and the first thermal insulation layer 4 of the same module 2b.

In order to further improve shock absorption, the first plate 3 is fixed on the wall 1 of the supporting structure with the interposition of a mastic bead 14 having a modulus of elasticity of at most 500 MPa at a temperature of -25. ° C and about 150MPa at a temperature of 25 ° C.

The damping of a tank comprising the improvement according to the present invention is at least three times greater than that according to the current structures, this effect being performed on the liquid side transported.

Claims (12)

Watertight and thermally insulating tank integrated in a supporting structure (1), the supporting structure being constituted by a double wall, the vessel comprising: a thermal insulation barrier secured to the supporting structure (1), a secondary sealing barrier (5) located in the thermal insulation barrier, and a primary sealing barrier (10) resting on the thermal insulation barrier, the thermal insulation barrier being made in the form of juxtaposed modules, a module having substantially the shape of a rectangular parallelepiped and comprising a first plywood plate (3) surmounted by a first layer of thermal insulation (4), itself surmounted by the secondary sealing barrier (5) on which is disposed a second layer of thermal insulation (6) which itself carries a second plywood plate, on which rests the primary sealing barrier (10). ) consisting of strakes or metal plates,
characterized in that it comprises a damping device consisting of a layer of damping material disposed between two walls, the damping device being located between the secondary sealing barrier (5) and the second layer of thermal insulation (6) . The vessel of claim 1 wherein the cushioning material is a woven or bonded fiber material. Tank according to claim 1, wherein the damping material is a felt. Tank according to one of claims 1 to 3, wherein the layer of damping material has a thickness of between 2 and 15 mm. Tank according to one of claims 1 to 4, wherein the secondary (5) and primary (10) sealing gates consist of embossed metal plates. Tank according to one of claims 1 to 5, wherein the thermal insulation barrier comprises a secondary thermally insulating barrier surmounted by the secondary sealing barrier (5) and a primary thermally insulating barrier disposed on the secondary sealing barrier (5), the primary sealing barrier (10) consisting of strakes or metal plates resting on the primary thermally insulating barrier, each of the thermally insulating barriers being made in the form of juxtaposed modules, a module of the secondary thermally insulating barrier having the shape of a rectangular parallelepiped and comprising a first plywood plate (3) surmounted by a first thermal insulation layer (4), a module of the primary thermally insulating barrier having the shape of a rectangular parallelepiped and comprising a second layer of thermal insulation (6) which itself carries a second plywood plate . A vessel according to claim 6, wherein the primary thermally insulating barrier module (2a) and the secondary thermally insulating barrier module (2b) are in the form of offset rectangles. Tank according to any one of claims 1 to 7, characterized in that a depression means is disposed between the first (8,8 ') and the second wall (9,9') of the damping device and crosses the layer of damping material (11,11 '). Tank according to any one of claims 1 to 8, characterized in that the junctions between the first walls (8,8 ') of the damping device are offset from those of the second walls (9,9') of the damping device . Tank according to any one of claims 1 to 9, characterized in that the two walls (8, 8 'and 9, 9') of the damping device have a thickness of between 9 and 21 mm. Tank according to any one of claims 1 to 10, characterized in that the two walls (8, 8 'and 9, 9') of the damping device are fir plywood or a composite material. Tank according to any one of claims 1 to 11, characterized in that the first plate (3) is fixed on the wall of the supporting structure with the interposition of a mastic bead (14) having a modulus of elasticity at maximum of 500 MPa at a temperature of -25 ° C and about 150 MPa at a temperature of 25 ° C.

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