RU2802560C1 - Lower wall of liquefied gas storage tank - Google Patents

Abstract

FIELD: gas transportation.

SUBSTANCE: tank for transportation and/or storage of liquefied gas. The tank contains a group of walls, each of which contains, in the direction along the wall thickness, a heat-insulating barrier and one sealed membrane located close to the heat-insulating barrier and in contact with the liquefied gas inside the tank (21). The heat-insulating barrier contains a group of self-supporting heat-insulating plates, each of which contains a polymer foam block and one sheet, while the bottom wall (27) from the group of walls contains one first part (29) and a partially encircling second part (31) of the bottom wall (27). The second part (31) contains one drain channel. The polymer foam blocks of the second part (31) have a density higher than the density of the polymer foam blocks of the first part (29).

EFFECT: increased the strength of the tank.

17 cl, 6 dwg

Description

[1] The present invention relates to the field of tanks configured to contain liquefied gas. In particular, the invention relates to the bottom wall of a tank, for example as part of a gravity platform, for storing liquefied gas, in particular, for example, liquefied natural gas (LNG).

[2] Gravity platforms are typically offshore structures used in oil or gas production. These structures in many cases contain a concrete foundation, designated by the concept of “GBS” (gravity-type foundation); The term “SKGT” (steel gravity structure) is also used to denote a base structure made of steel, in which the present invention can also be used.

[3] Gravity platforms can simultaneously perform the functions of bunding, gas storage, liquefaction plant placement and loading rack in field conditions for the production of liquefied gas, in particular, for example, liquefied natural gas or ethane.

[4] There is a need to optimize storage tanks as part of gravity platforms for liquefied gas storage. On the one hand, they do not provide sufficient thermal insulation between the tank walls and the concrete base structure of the gravity platform for proper storage of liquefied gas. On the other hand, the volume of gravity platform tanks is significantly larger than that of ship tanks, and their ability to withstand the operating loads and accidental loads encountered when loading and unloading liquefied gas into the tank is limited and, in some cases, insufficient .

[5] One of the objectives of the present invention is to overcome at least one of the above disadvantages, as well as to achieve other advantages due to the proposed new type of wall for a tank for storing and/or transporting liquefied gas, in particular for a gravity platform.

[6] The second object of the invention is to achieve optimum efficiency in pumping liquefied gas at the bottom of the tank by minimizing the level of residual liquefied gas.

[7] The third purpose of the invention is to minimize cost while reducing the complexity of manufacturing such a tank.

[8] The present invention proposes a tank for transporting and/or storing liquefied gas, containing a group of walls, each of which contains, in the direction along the wall thickness, a heat-insulating barrier and at least one sealed membrane located adjacent to the heat-insulating barrier and in contact with the liquefied gas inside the tank, wherein the heat-insulating barrier contains a group of self-supporting heat-insulating slabs, each of which contains a foam block and at least one sheet, and the lower wall of the group of walls contains at least one first part, at least partially encircling the second part the lower wall, wherein the second part contains at least one drain channel. The polymer foam blocks of the second part have a density that exceeds the density of the polymer foam blocks of the first part.

[9] The encircling of the second part of the lower wall, at least partially by the first part of the lower wall, can be seen in projection in a plane perpendicular to the direction along the thickness of the lower wall.

[10] In other words, the tank for transporting and/or storing liquefied gas contains a bottom wall containing at least one drain channel. The drain channel is a recess designed to accommodate the suction element of the pump to suck in the liquefied gas contained in the tank. The drain channel is therefore a part of the bottom wall, and therefore of the tank, that is particularly susceptible to stress during tank operation. Therefore, increasing the density of the foam polymer blocks of self-supporting thermal insulation slabs in the part containing the drain channel relative to the rest of the lower wall makes it possible to improve thermal insulation and at the same time increase the mechanical strength of the wall.

[11] In this case, as in all other parts of the application, the concept of “self-supporting slab” should be understood in the sense that a self-supporting insulating slab is capable of supporting the weight of an object placed on top of it, for example, liquefied natural gas, without significant deformation and within the limits its mechanical strength.

[12] In one embodiment, the first portion of the bottom wall lies in a major plane of passage perpendicular to the thickness direction of the bottom wall.

[13] In one embodiment, the second portion of the bottom wall includes a first portion extending in a major plane of passage perpendicular to the thickness direction of the bottom wall, and a second portion extending from the outline of the first portion to the first portion.

[14] In one embodiment, the drain channel is shaped like a cylinder with a square base or a circular cross-section.

[15] In one embodiment, the second part of the bottom wall includes a group of bleed channels.

[16] In one embodiment, the bottom wall includes a group of second parts.

[17] In one embodiment, the wall group includes a top wall and side walls connecting the bottom wall to the top wall, wherein the density of the polymer foam blocks of the self-supporting thermal insulation boards decreases in the direction from the bottom wall to the top wall.

[18] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the first part is substantially equal to the density of the polymer foam blocks of the self-supporting thermal insulation boards of the side walls and is substantially equal to the density of the polymer foam blocks of the self-supporting thermal insulation boards of the top wall.

[19] The concept “substantially” hereinafter should be understood as meaning that it is necessary to take into account both permissible deviations during production and possible permissible deviations during installation.

[20] In one embodiment, the tank contains a first zone formed by a bottom wall and the bottom of the side walls, and a second zone formed by the top wall and the top of the side walls, wherein the density of the polymer foam blocks of the self-supporting thermal insulation boards of the first zone exceeds the density of the polymer foam blocks of the self-supporting thermal insulation boards slabs of the second zone.

[21] In one embodiment, the reservoir contains at least one third zone located between the first zone and the second zone, and the density of the foam blocks of self-supporting thermal insulation boards of the third zone is in the range from the density of the foam blocks of self-supporting thermal insulation boards of the first zone to the density of the foam blocks of self-supporting thermal insulation boards of the first zone thermal insulation boards of the second zone.

[22] In one embodiment, the tank contains a group of third zones, wherein the third zones are located one above the other in a direction from the bottom wall to the top wall, and the foam blocks of self-supporting thermal insulation boards of a separate third zone of the specified group of third zones have substantially the same density , while the density of the foam polymer blocks of self-supporting heat-insulating slabs of the specified group of third zones decreases in the direction from the bottom wall to the top wall. In other words, the reservoir contains at least two third zones located one above the other in the direction from the lower wall to the upper wall. Thus, the tank can contain any required number of third zones, in particular, for example, to accommodate different tank sizes. For example, a zoned tank may contain four, five, or six third zones. In addition, the density of the foam polymer blocks of self-supporting thermal insulation boards is uniform within a single third zone, while the density of the foam polymer blocks of self-supporting thermal insulation boards in one third zone is different from their density in another third zone.

[23] In one embodiment, the reservoir contains three third zones. Thus, the reservoir contains three zones: a first zone, a second zone and the three third zones.

[24] In one embodiment, the density of the foam blocks of the self-supporting thermal insulation boards of the third zone closest to the bottom wall is greater than the density of the foam blocks of the self-supporting thermal insulation boards of the third zone closest to the top wall.

[25] In one embodiment, the seal membrane is a primary seal membrane and the thermal barrier is a primary thermal barrier, the bottom wall comprising a secondary seal membrane and a secondary thermal barrier comprising a group of self-supporting thermal insulating blocks including foam tiles and at least at least one sheet, wherein the auxiliary sealed membrane is located adjacent to the auxiliary heat-insulating barrier, while the main heat-insulating barrier is located adjacent to the auxiliary sealed membrane, while the main sealed membrane is located adjacent to the main heat-insulating barrier.

[26] Here, as in all other parts of the application, the concept of “self-supporting block” should be understood in the sense that a self-supporting thermal insulating block is capable of supporting the weight of an object placed on top of it, for example, liquefied natural gas, without significant deformation and within its mechanical limits. strength.

[27] In one embodiment, the foam tiles of the self-supporting insulating blocks of the first part, side walls and top wall have a density substantially equal to the density of the foam blocks of the self-supporting insulating slabs of the first part, side walls and top wall, and the foam tiles of the self-supporting insulating blocks of the second part have a density essentially equal to the density of the foam polymer blocks of the self-supporting thermal insulation boards of the second part. It is understood that the foam tiles and foam blocks within a single wall or portion are of substantially equal density, and that the foam tiles of the first portion, side walls, and top wall are of substantially equal density, and that that the polymer foam blocks of the first part, side walls and top wall have substantially equal density.

[28] In one embodiment, the polymer foam tiles of the self-supporting insulating blocks of the second bottom wall portion have a higher density than the polymer foam tiles of the self-supporting insulating blocks of the first bottom wall portion.

[29] In one embodiment, the foam tiles of the self-supporting thermal insulation blocks of the first bottom wall portion have a density substantially equal to the density of the foam polymer blocks of the self-supporting thermal insulating tiles of the first bottom wall portion.

[30] In one embodiment, the polymer foam tiles of the self-supporting thermal insulation blocks of the second bottom wall portion have a density substantially equal to the density of the polymer foam blocks of the self-supporting thermal insulating tiles of the second bottom wall portion.

[31] In one embodiment, the density of the foam tiles of the self-supporting insulating blocks of the first part is substantially equal to the density of the foam tiles of the self-supporting insulating blocks of the side walls and is substantially equal to the density of the foam tiles of the self-supporting insulating blocks of the top wall.

[32] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the first part of the bottom wall is no more than 110 kg/m ³ .

[33] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the second part of the bottom wall is not less than 115 kg/m ³ .

[34] In one embodiment, the group of walls includes a top wall and side walls connecting the bottom wall to the top wall, the top wall and side walls each comprising a secondary seal membrane and a secondary thermal insulating barrier comprising a group of self-supporting thermal insulating blocks including: foam tiles and at least one sheet, wherein the auxiliary sealed membrane is located adjacent to the auxiliary heat-insulating barrier, while the main heat-insulating barrier is located adjacent to the auxiliary sealed membrane, and the main sealed membrane is located adjacent to the main heat-insulating barrier, wherein the density of the foam polymer tiles self-supporting heat-insulating blocks decreases in the direction from the bottom wall to the top wall.

[35] In one embodiment, the tank includes a first zone formed by a bottom wall and the bottom portion of the side walls, and a second zone formed by the top wall and the top portion of the side walls, wherein the density of the polymer foam tiles of the self-supporting thermal insulating blocks of the first zone exceeds the density of the polymer foam tiles of the self-supporting thermal insulating blocks blocks of the second zone.

[36] In one embodiment, the reservoir contains at least one third zone located between the first zone and the second zone, and the density of the foam tiles of the self-supporting insulating blocks of the third zone is in the range from the density of the foam tiles of the self-supporting insulating blocks of the first zone to the density of the foam tiles of the self-supporting insulating blocks heat-insulating blocks of the second zone.

[37] In one embodiment, the tank contains a group of third zones, wherein the third zones are located one above the other in a direction from the bottom wall to the top wall, and the foam tiles of the self-supporting insulating blocks of a separate third zone of the specified group of third zones have substantially the same density , while the density of the foam polymer tiles of the self-supporting heat-insulating blocks of the specified group of third zones decreases in the direction from the bottom wall to the top wall. In other words, the reservoir contains at least two third zones located one above the other in the direction from the lower wall to the upper wall. Thus, the tank can contain any required number of third zones, in particular, for example, to accommodate different tank sizes. For example, a zoned tank may contain four, five, or six third zones. In addition, the density of the foam polymer tiles of the self-supporting heat-insulating blocks is uniform within a single third zone, while the density of the foam polymer tiles of the self-supporting heat-insulating blocks in one third zone is different from their density in another third zone.

[38] In one embodiment, the reservoir contains three third zones. Thus, the reservoir contains three zones: a first zone, a second zone and three third zones.

[39] In one embodiment, the density of the polymer foam tiles of the self-supporting thermal insulating blocks of the third zone closest to the bottom wall is greater than the density of the polymer foam tiles of the self-supporting thermal insulating blocks of the third zone closest to the upper wall.

[40] In one embodiment, the density of the polymer foam tiles of the self-supporting insulating blocks of the first part of the bottom wall is no more than 110 kg/m ³ .

[41] In one embodiment, the density of the polymer foam tiles of the self-supporting thermal insulating blocks of the second part of the bottom wall is not less than 115 kg/m ³ .

[42] In one embodiment, the density of the polymer foam tiles of the self-supporting insulating blocks of the first zone is greater than 70 kg/m ³ .

[43] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the first zone is greater than 70 kg/m ³ .

[44] In one embodiment, the density of the polymer foam tiles of the self-supporting insulating blocks of the second zone is less than 70 kg/m ³ .

[45] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the second zone is less than 70 kg/m ³ .

[46] In one embodiment, the density of the polymer foam blocks of the self-supporting thermal insulation boards of the third zone is in the range of 65 kg/m ³ to 90 kg/m ³ .

[47] In one embodiment, the density of the polymer foam tiles of the third zone self-supporting insulating blocks is in the range of 65 kg/m ³ to 90 kg/m ³ .

[48] Here and further it should be understood that it is necessary to take into account any permissible deviations during production from the numerical values established for the densities of polymer foam blocks of self-supporting thermal insulation slabs and polymer foam tiles of self-supporting thermal insulating blocks. So, you can accept a permissible deviation of +/- 5 kg/m ³ from the value established for density.

[49] In one embodiment, the at least one self-supporting insulation board includes a polymer foam block made of rigid polyurethane and a plywood sheet located on top of the polymer foam block. It should be understood that one, or more, or all of the self-supporting thermal insulation boards comprise a polymer foam block made of rigid polyurethane and a plywood sheet on which the polymer foam block is supported.

[50] In one embodiment, the at least one self-supporting insulating unit comprises a foam tile made of rigid polyurethane and a plywood sheet located on top of the foam tile. It should be understood that one, or more, or all of the self-supporting insulating blocks comprise a foam tile made of rigid polyurethane and a plywood panel on which the foam tile is supported.

[51] The invention also relates to a gravity platform, in particular for liquefied gas storage, comprising a liquefied gas storage tank with one or more of the above features and a pump suction element configured to discharge the liquefied gas contained within the tank from a discharge channel. In other words, the gravity platform contains a loading and/or unloading tower equipped with at least one pumping element connected to the drain channel.

[52] In one embodiment, the tank includes a tank support structure, wherein the support structure is made of concrete.

[53] The invention also provides a system for moving liquefied gas, the system comprising a gravity platform with one or more of the above features, insulated pipes arranged to create a connection between a tank mounted in the support structure of the gravity platform and the vessel, and a pump for driving the flow of liquefied gas product through insulated pipes from the gravity platform tank to the ship.

[54] The invention also provides a method of loading or unloading a gravity platform with one or more of the above features, in which liquefied gas is transferred through insulated pipes from a reservoir of the gravity platform to a ship.

[55] Other features and advantages of the invention will become apparent from the following description and several exemplary embodiments, given for illustrative purposes but by way of limitation, with reference to the accompanying schematic drawings, in which:

[Fig. 1] Fig. 1 is a schematic perspective view of a liquefied gas storage tank for a gravity platform containing the proposed bottom wall;

[Fig. 2] Fig. 2 is a schematic axonometric sectional view along the transverse and vertical plane of the tank from FIG. 1;

[Fig. 3] Fig. 3 is a schematic view of the tank wall structure of FIG. 1 in the wall thickness direction in the first embodiment;

[Fig. 4] Fig. 4 is a schematic view of the bottom wall drain channel of FIG. 1 along the transverse and vertical cutting plane;

[Fig. 5] Fig. 5 is a schematic view of the tank wall structure of FIG. 1 in the wall thickness direction in the second embodiment;

[Fig. 6] Fig. 6 is a schematic representation of a gas tanker tank and a gravity loading and unloading platform containing the proposed tank.

[56] First of all, it should be noted that the figures, in which the invention is disclosed in detail for its implementation, can, if necessary, also serve to more precisely define the scope of the invention. It should also be noted that in all figures, similar elements and/or elements performing the same function are designated by the same numbers.

[57] In the following description, the direction of the longitudinal axis L, the direction of the transverse axis T and the direction of the vertical axis V are designated in the figures by a triple of unit vectors (L, V, T). A horizontal plane is a plane perpendicular to the vertical axis, a longitudinal plane is a plane perpendicular to the transverse axis, and a transverse plane is a plane perpendicular to the longitudinal axis.

[58] The concepts “external” and “internal” are used to denote the location of one element relative to another in relation to the space inside and outside the tank.

[59] In the embodiment of FIG. 1 gravity platform 1 contains a concrete base structure 3 forming a support structure for a sealed and heat-insulating tank 21 for transporting and/or storing liquefied gas. Hereinafter, the terms “base structure” and “support structure” are used interchangeably and are designated by the same position number.

[60] Liquefied gas is a substance or mixture of substances that is in a gaseous state under conditions of normal temperature and pressure. The liquefied gas may be, for example, liquefied petroleum gas, liquefied natural gas or an alkane, in particular ethane.

[61] In the examples of FIGS. 1 and Fig. 2, the base structure 3 contains a double lower bulkhead 5, an upper bulkhead 9 and double side bulkheads 7 connecting the double lower bulkhead 5 with an upper bulkhead 9. Each double bulkhead 5, 7 includes an external bulkhead 11 and an internal bulkhead 13, made of concrete. The internal bulkheads 13 and the upper bulkhead 9 define the overall shape of the tank 21. External bulkheads 11 and internal bulkheads 13 are connected to each other by concrete struts 15.

[62] In FIG. 2 - a cross-section of the tank 21 along the secant plane 150 - shows that the lower part of the base structure 3 contains ballast compartments 17. The ballast compartments 17 are located between the inner bulkhead 13 and the outer bulkhead 11 of the double lower bulkhead 5. The ballast compartments 17 are filled with sea water, when the gravity platform 1 is located at the place of its operation, to submerge the gravity platform 1 due to ballasting. As a result, gravity platform 1 is partially supported on the seabed.

[63] The tank 21 contains a group of walls 23, 25, 27, each of which is located adjacent to the internal bulkhead 13 and the upper bulkhead 9 of the base structure 3. Thus, the tank 21 includes an upper wall 23 located on the inner edge of the upper bulkhead 9, and a lower wall 27 located on the inner edge of the inner bulkhead 13. The upper wall 23 and the lower wall 27 extend in the main plane substantially parallel to the horizontal plane described above. The upper wall 23 is substantially parallel to the lower wall 27 and does not intersect it.

[64] The upper wall 23 and the lower wall 27 are connected to each other by side walls 25 located on the inner edge of the other internal bulkheads 13. Each of the side walls 25 extends in a plane substantially perpendicular to the horizontal plane from one end of the lower wall 27 to one the end of the upper wall 23. The reservoir 21 is generally made in the shape of a rectangular parallelepiped.

[65] In the example of FIG. 1, the bottom wall 27 includes at least one first part 29 at least partially surrounding the second part 31 of the bottom wall 27. In the embodiment of FIG. 1, the first part 29 encircles a group of second parts 31.

[66] FIG. 4 schematically shows a second part 31 of a group of second parts 31. The second part 31 of the bottom wall 27 is thus encircled by the first part 29 along a cutting plane 200, as can be seen in FIG. 1. The second part 31 contains a drain channel 33 surrounded by a support 35 extending from the edge of the drain channel 33 to the first part 29. The drain channel 33 is designed to accommodate the suction element of a pump (not shown) for sucking or filling liquefied gas. The drain channel 33 includes a bottom 38 where, for example, a guide device 79 is located, configured to receive a tower (not shown) for loading and/or unloading liquefied gas contained in the tank 21. Alternatively, the bottom 38 may not contain specified guiding device.

[67] In one embodiment not shown, the second portion includes a group of bleeders.

[68] In the examples of FIGS. 1 and Fig. 4, the first part 29 of the lower wall 27 lies in the main plane of passage of the lower wall 27. Namely, in the example of FIG. 4, the support 35 runs in the main plane of passage of the bottom wall 27. The drain channel 33 is made in the form of a straight cylinder with a square base, limited by the side walls 37 passing in a plane perpendicular to the plane of passage of the bottom wall 27. Thus, the entrance 39 of the drain channel 33, that is the opening through which the liquefied gas contained in the tank 21 can enter the drainage channel 33 is located so that it is flush with the first part 29 of the lower wall 27.

[69] The first part 29 and the second parts 31 are continuously connected to form the bottom wall 27. In other words, the first part 29, the supports 35 and the drain channel 33 are connected so as to provide continuous thermal insulation and a continuous sealing of the bottom wall 27.

[70] In the examples of FIGS. 3 and Fig. 4, each wall 23, 25, 27 contains, in the direction along the thickness E of the walls 23, 25, 27, an auxiliary heat-insulating barrier 41, enclosed in the corresponding bulkhead of the base structure 3, an auxiliary sealed membrane 51 located adjacent to the auxiliary heat-insulating barrier 41, the main heat-insulating a barrier 61 located adjacent to the auxiliary sealed membrane 51, and a main sealed membrane 71 in contact with the liquefied natural gas contained in the tank 21 and located adjacent to the main thermal insulating barrier 61.

[71] The auxiliary thermal insulating barriers 41 of the walls 23, 25, 27 of the tank 21 are connected to each other to form, between the base structure 3 and the auxiliary sealing membrane 51, a continuous and sealed auxiliary thermal insulating space. Likewise, the main thermal insulating barriers 61 of the walls 23, 25, 27 of the tank 21 are connected to each other to form, between the auxiliary sealed membrane 51 and the main sealed membrane 71, a continuous and sealed main thermal insulating space.

[72] In the examples of FIGS. 3 and Fig. 4, the auxiliary heat-insulating barrier 41 contains a group of self-supporting heat-insulating blocks 43. The self-supporting heat-insulating blocks 43 are made in the shape of an essentially rectangular parallelepiped. Self-supporting heat-insulating blocks 43 may have other shapes, in particular, for example, the shape of a parallelepiped, in particular with a square or rectangular base, or the shape of a straight prism with a hexagonal base. Self-supporting thermal insulating blocks 43 are arranged side by side in parallel rows.

[73] In one not shown embodiment, the self-supporting thermal insulating blocks 43 of the group of self-supporting thermal insulating blocks 43 may include a corner structure located at the joint 34 between the support 35 and the drain channel 33. The corner structure includes two grooves parallel, respectively, to the plane of passage of the support 35 and the plane passing the side walls 37. These two grooves form a dihedral angle of 45° or 90°.

[74] Each of the self-supporting thermal insulating blocks 43 includes a thermally insulating foam tile 45 supported on an outer rigid sheet 47. The rigid outer sheet 47 is, for example, a plywood sheet. The outer rigid sheet 47 is bonded to said insulating polyurethane foam tile 45. The insulating polymer foam may be, in particular, rigid polyurethane foam. Glass fibers can be embedded in polyurethane foam to increase the mechanical strength of the polymer foam and to reduce the coefficient of thermal expansion of the polymer foam. In one embodiment not shown, the rigid outer sheet 47 is made of at least one composite.

[75] The self-supporting thermal insulating blocks 43 have a thickness ranging from 100 mm to 350 mm, preferably from 150 mm to 300 mm, and the thickness of the self-supporting thermal insulating blocks 43 is measured parallel to the thickness direction E of the wall 23, 25, 27. Density of the thermal insulating foam tiles 45 is different in different self-supporting thermal insulating blocks 43 depending on their location in the tank 21 to optimize their mechanical strength and cost. The differences in density of thermal insulating foam polymer tiles 45 will be discussed in detail below.

[76] There may be significant deviation of the inner edge of the internal bulkheads 13 and the inner edge of the upper bulkhead 9 from the theoretical surface provided for the base structure, due, for example, to manufacturing errors. These deviations are compensated by pressing the self-supporting thermal insulating blocks 43 to the base structure using strips of polymerizable resin 40. The self-supporting thermal insulating blocks 43 are attached to the internal bulkheads 13 and to the upper bulkhead 9 by pins not shown, welded on the inner edge of the internal bulkheads 13.

[77] The auxiliary sealed membrane 51 contains a group of rigid sealed partitions 53 made of 0.07 mm thick aluminum sheet placed between two sheets of glass fabric impregnated with a polyamide resin. Rigid compacted partitions 53 are attached to foam polymer tiles 45 of self-supporting thermal insulating blocks 43, for example, using two-component polyurethane adhesive.

[78] To provide some flexibility to the secondary membrane and provide continuity between two adjacent rigid seal sheets 53, a flexible sealed partition 55 is installed, attached to the adjacent peripheral edges of the two adjacent rigid seal sheets 53. The flexible sealed partition 55 is made of a composite containing three layers. : two outer layers, which are fiberglass sheets, and an intermediate layer, which is a thin sheet of metal, for example, aluminum foil about 0.1 mm thick. This sheet metal provides continuity to the secondary sealing membrane.

[79] The main thermal insulating barrier 61 contains a group of self-supporting thermal insulating boards 63, made in the shape of a substantially rectangular parallelepiped. Self-supporting thermal insulation boards 63 may have other shapes, in particular, for example, a cubic shape. In the first embodiment in FIG. 3, self-supporting thermal insulation slabs 63 are offset relative to the self-supporting thermal insulating blocks 43 of the auxiliary thermal insulating barrier 41 so that each self-supporting thermal insulating slab 63 passes over at least two self-supporting thermal insulating blocks 43.

[80] Each self-supporting thermal insulation board 63 contains a thermally insulating polymer foam block 65, for example, based on rigid polyurethane. The first side of the foam block 65 is bonded to the auxiliary sealing membrane 51, and the second side opposite the first side is covered with an inner rigid sheet 69. The inner rigid sheet 69 of the self-supporting thermal insulation board 63 is made, for example, of plywood. Glass fibers can be embedded into the polymer foam to reinforce it in order to increase the mechanical strength of the polymer foam and reduce the coefficient of thermal expansion of the polymer foam. In one embodiment not shown, the inner rigid sheet 69 is made of at least one composite.

[81] The self-supporting thermal insulation boards 63 have a thickness ranging from 100 mm to 200 mm, preferably from 100 mm to 150 mm, and the thickness of the self-supporting thermal insulating boards 63 is measured parallel to the thickness direction E of the wall 23, 25, 27.

[82] In the second embodiment shown in FIG. 5, the self-supporting thermal insulation boards 63 are arranged differently from those in the first embodiment. In other words, in the second embodiment, the elements of the tank are identical to the elements in the first embodiment, with only the location of the self-supporting heat-insulating boards 63 relative to the self-supporting heat-insulating blocks 43 being changed.

[83] Thus, part of the self-supporting thermal insulation boards 63 is fastened to the central part of the self-supporting thermal insulating blocks 43 during preliminary manufacturing. Said portion of the self-supporting insulating boards 63 covers a portion of the auxiliary sealed membrane 51. Another portion of the self-supporting insulating boards 63 is secured to the edge of the self-supporting insulating blocks 43. The remainder of the self-supporting insulating boards 63, in turn, extends over at least two self-supporting insulating blocks 43.

[84] In FIG. 4 shows that the main thermal insulating barrier 61 may additionally contain corner reinforcing elements 62, which serve to fill any spaces between the self-supporting thermal insulation boards 63 and the main sealed membrane 71, in particular at the joint 34 between the support 35 and the drain channel 33. Corner reinforcing elements 62 are, for example, blocks of solid wood or plywood.

[85] The main seal membrane 71 contains a group of metal sheets welded to each other. In the embodiment of FIG. 3 and Fig. 4, the main sealed membrane 71 contains corrugations 75 on metal sheets, allowing it to deform under the influence of thermal and mechanical stresses created by liquefied gas in the tank 21. The main sealed membrane 71 contains two rows of corrugations 75 perpendicular to each other. The corrugations 75 protrude inside the tank 21. The inner rigid sheet 69 of each self-supporting thermal insulation board 63 is provided with metal plates (not shown) for attaching the corrugated metal sheets of the main sealing membrane 71. The mounting plates may be assembled together, for example, by welding.

[86] Depending on their location in the tank, the foam tiles 45 of the self-supporting thermal insulation blocks 43 and/or the foam polymer blocks 65 of the self-supporting thermal insulation boards 63 may have different densities depending on their location in the tank 21. This makes it possible to strengthen the areas of the tank 21 that are subject to exposure to strong mechanical stress, while simultaneously reducing the cost of the tank.

[87] Thus, the density of the polymer foam tiles 45 and the density of the polymer foam blocks 65 of the second part 31 of the lower wall 27 exceeds the density of the polymer foam tiles 45 and the density of the polymer foam blocks 65 of the first part 29 of the lower wall 27.

[88] In the embodiment shown in these figures, the density of the polymer foam tiles 45 of the drainage channel 33 and support 35 and the density of the polymer foam blocks 65 of the drainage channel 33 and support 35 are essentially equal to 130 kg/m ³ . That is, the density of the polymer foam tiles 45 of the second part 31 is essentially equal to the density of the polymer foam blocks 65 of the second part 31. The density of the polymer foam tiles 45 and the density of the polymer foam blocks 65 of the first part 29 is 90 kg/m ³ . It should be understood that the density of the polymer foam tiles 45 of the first part 29 is substantially equal to the density of the polymer foam blocks 65 of the first part 29.

[89] In one not shown embodiment, the polymer foam tiles 45 of the first part 29 have a different density than the polymer foam blocks 65 of the first part 29. In one not shown embodiment, the polymer foam tiles 45 of the second part 31 have a different density than the polymer foam blocks 65 of the second part 31 .

[90] In the examples of FIGS. 2 and Fig. 4, the density of the foam polymer blocks 65 of the self-supporting heat-insulating slabs 63 decreases in the direction from the bottom wall 27 to the top wall 23. In addition, the density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 decreases in the direction from the bottom wall 27 to the top wall 23.

[91] Namely, the tank 21 includes a first zone 81, a second zone 83, and at least one third zone 85. The first zone 81 includes a bottom wall 27 and a lower portion of side walls 25. The second zone 83 includes a top wall 23 and the top of the side walls 25. The third zone 85 includes the central portion of the side walls 25. The third zone 85 is located directly between the first zone 81 and the second zone 83.

[92] Polymer foam tiles 45 and polymer foam blocks 65 of the first zone 81 have a density of at least 90 kg/m ³ . The foam tiles 45 and foam blocks 65 of the lower portion of the side walls 25 have a density substantially equal to 90 kg/m ³ . As disclosed above, the foam tiles 45 and foam blocks 65 of the first portion 29 have a density substantially equal to 90 kg/m ³ . The foam tiles 45 and foam blocks 65 of the second part 31 have a density substantially equal to 130 kg/m ³ .

[93] The density of the foam tiles 45 and the density of the foam blocks 65 of the second zone 83 are substantially equal to 65 kg/m ³ . Thus, the density of the polymer foam tiles 45 of the second zone 83 and the density of the polymer foam blocks 65 of the second zone 83 are below 70 kg/m ³ .

[94] The density of the foam tiles 45 and the density of the foam blocks 65 of the third zone 85 are substantially equal to 75 kg/m ³ . Thus, the density of the polymer foam tiles 45 and the density of the polymer foam blocks 65 of the third zone 85 are in the range from 65 kg/m ³ to 90 kg/m ³ . In other words, the density of the polymer foam tiles 45 of the third zone 85 is in the range from the density values of the polymer foam tiles 45 of the second zone 83 to the density values of the polymer foam tiles 45 of the first zone 81. In addition, the density of the polymer foam blocks 65 of the third zone 85 is in the range from the density values of the polymer foam blocks 65 of the second zone 83 to the density values of the foam polymer blocks 65 of the first zone 81.

[95] In one embodiment not shown, the reservoir includes a group of third zones 85 located immediately between the first zone 81 and the second zone 83. The third zones 85, in turn, are located one above the other in a direction from the bottom wall 27 to the top wall 23.

[96] The polymer foam blocks 65 of the self-supporting thermal insulation boards 63 of a single third zone of said group of third zones 85 have substantially the same density. In other words, the density of the foam polymer blocks 65 of the self-supporting thermal insulation boards 63 is uniform within a single third zone 85.

[97] The density of the polymer foam blocks 65 of the self-supporting thermal insulation slabs 63 of the specified group of third zones 85 decreases in the direction from the lower wall 27 to the upper wall 23. Thus, the density of the polymer foam blocks 65 of the self-supporting thermal insulation slabs 63 in one third zone is different from their density in the other third zone. The density of the foam polymer blocks 65 of the self-supporting heat-insulating boards 63 of the third zone 85, closest to the bottom wall 27, exceeds the density of the foam polymer blocks 65 of the self-supporting heat-insulating boards 63 of the third zone 85, closest to the top wall 23.

[98] In this not shown embodiment, the polymer foam tiles 45 of the self-supporting insulating blocks 43 of a single third zone of said group of third zones 85 have substantially the same density. In other words, the density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 is uniform within a single third zone 85.

[99] The density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 of the specified group of third zones 85 decreases in the direction from the bottom wall 27 to the top wall 23. Thus, the density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 in one third zone is different from their density in the other third zone. The density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 of the third zone 85, closest to the bottom wall 27, exceeds the density of the foam polymer tiles 45 of the self-supporting heat-insulating blocks 43 of the third zone 85, closest to the top wall 23.

[100] The reservoir 21 preferably contains three third zones 85, that is, the reservoir 21 contains five zones 81, 83, 85.

[101] FIG. 6 shows a transport and/or storage tank 21 generally parallelepiped-shaped and installed in the base structure 3 of a gravity platform 1. Gravity platforms 1 are typically offshore structures used in the field of oil or gas production. These structures in many cases contain a concrete foundation, designated by the concept of “GBS” (gravity-type foundation); The term “SKGT” (steel gravity structure) is also used to denote a base structure made of steel, in which the present invention can also be used.

[102] The gravity platforms 1 can simultaneously perform the functions of bunding, gas storage, liquefaction plant placement and loading rack in field conditions for the production of liquefied gas, in particular, for example, liquefied natural gas or ethane.

[103] The wall of the tank 21 includes a main seal membrane in contact with the LNG contained in the tank 21, an auxiliary seal membrane located between the main seal barrier and the base structure 3 of the gravity platform 1, and two thermal insulating barriers located between the main seal barrier and the auxiliary seal barrier and between the auxiliary sealed barrier and the base structure 3, respectively. It is known that the loading and unloading pipes 103 located on the upper deck of the gas tanker 100 can be connected by any suitable connectors to the gravity platform 1 to move the LNG cargo from or into the tank 21.

[104] FIG. 6 also shows a gravity platform 1 including a loading and unloading station 105, an underwater pipe 107 and a gravity platform 1. The loading and unloading station 105 is a fixed offshore installation containing a movable boom 111 and a tower 113 on which the movable boom 111 is supported. The movable boom 111 carries a bundle of insulated flexible hoses 115, which can be connected to loading and unloading pipes 103. The adjustable movable boom 111 is suitable for gas tankers of any size. A connecting pipe, not shown, extends within the tower 113. The loading and unloading station 105 allows the at least one tank 22 of the gas tanker 100 to be loaded and unloaded from or onto the gravity platform 1. The reservoir 22 of the gas tanker 100 may be a reservoir according to the invention. The gravity platform 1 contains at least one proposed liquefied gas storage tank 21 and connecting pipes 109 connected by an underwater pipe 107 to a loading and unloading station 105. The underwater pipe 107 allows the liquefied gas to be transported over a long distance between the loading and unloading station 105 and the gravity platform 1, for example, 5 km, thanks to which the gas tanker 100 can remain at a long distance from the shore during loading and unloading operations. To create the pressure necessary to move the liquefied gas, pumps are used on board the gas tanker 100, and/or pumps equipped with the gravity platform 1, and/or pumps equipped with the loading and unloading point 105.

[105] Thus, the invention makes it possible to simply manufacture a tank 21 for storing and/or transporting liquefied gas for a gravity platform 1 with increased mechanical strength, in particular at the drain channel 33, made in the lower wall 27 of the tank 21, through the use of foam polymer tiles 45 self-supporting heat-insulating blocks 43 and foam polymer blocks 65 self-supporting heat-insulating slabs 63 of different densities within the bottom wall 27. In addition, due to the use of different densities of foam polymer tiles 45 self-supporting heat-insulating blocks 43 and different foam polymer blocks 65 self-supporting heat-insulating slabs 63 depending on the height tank 21, the cost of tank 21 can be minimized.

[106] The invention is, of course, not limited to the examples disclosed above, to which numerous modifications can be made without departing from the scope of the invention.

Claims (17)

1. A tank (21) for transportation and/or storage of liquefied gas, containing a group of walls (23, 25, 27), each of which contains, in the direction along the thickness (E) of the wall, a heat-insulating barrier (61) and at least one a sealed membrane (71) located adjacent to the heat-insulating barrier (61) and in contact with liquefied gas inside the tank (21), while the heat-insulating barrier (61) contains a group of self-supporting heat-insulating slabs (63), each of which contains a polymer foam block (65) and at least one sheet (69), wherein the lower wall (27) of the group of walls (23, 25, 27) contains at least one first part (29) at least partially surrounding the second part (31) of the lower walls (27), while the second part (31) contains at least one drain channel (33), characterized in that the polymer foam blocks (65) of the second part (31) have a density exceeding the density of the polymer foam blocks (65) of the first part ( 29). 2. Reservoir (21) according to the previous paragraph, characterized in that the group of walls (23, 25, 27) includes an upper wall (23) and side walls (25) connecting the lower wall (27) with the upper wall (23), with In this case, the density of the foam polymer blocks (65) of the self-supporting heat-insulating slabs (63) decreases in the direction from the lower wall (27) to the upper wall (23). 3. Reservoir (21) according to claim 1, characterized in that the group of walls (23, 25, 27) includes an upper wall (23) and side walls (25) connecting the lower wall (27) with the upper wall (23), wherein the density of the foam polymer blocks (65) of the self-supporting heat-insulating slabs (63) of the first part (29) is essentially equal to the density of the foam polymer blocks (65) of the self-supporting heat-insulating slabs (63) of the side walls (25) and is essentially equal to the density of the self-supporting foam polymer blocks (65) thermal insulation boards (63) of the upper wall (23). 4. Reservoir (21) according to claim 2, characterized in that it contains a first zone (81) formed by the lower wall (27) and the lower part of the side walls (25), as well as a second zone (83) formed by the upper wall (23 ) and the upper part of the side walls (25), while the density of polymer foam blocks (65) of self-supporting heat-insulating slabs (63) of the first zone (81) exceeds the density of polymer foam blocks (65) of self-supporting heat-insulating slabs (63) of the second zone (83). 5. The tank (21) according to the previous paragraph, characterized in that it contains at least one third zone (85) located between the first zone (81) and the second zone (83), while the density of the polymer foam blocks (65) of self-supporting thermal insulation boards (63) of the third zone (85) ranges from the density of polymer foam blocks (65) of self-supporting heat-insulating slabs (63) of the first zone (81) to the density of polymer foam blocks (65) of self-supporting heat-insulating slabs (63) of the second zone (83). 6. Reservoir (21) according to the previous paragraph, characterized in that it contains a group of third zones (85), with the third zones (85) located one above the other in the direction from the lower wall (27) to the upper wall (23), while foam polymer blocks (65) of self-supporting heat-insulating boards (63) of a separate third zone (85) of the specified group of third zones (85) have essentially the same density, while the density of foam polymer blocks (65) of self-supporting heat-insulating boards (63) of the specified group of third zones ( 85) decreases in the direction from the lower wall (27) to the upper wall (23). 7. Reservoir (21) according to any of the previous paragraphs, characterized in that the sealed membrane (71) is a main sealed membrane (71), and the heat-insulating barrier (61) is the main heat-insulating barrier (61), and the bottom wall (27) contains an auxiliary sealed membrane (51) and an auxiliary heat-insulating barrier (41), containing a group of self-supporting heat-insulating blocks (43), including foam polymer tiles (45) and at least one sheet (47), while the auxiliary sealed membrane (51 ) is located adjacent to the auxiliary heat-insulating barrier (41), while the main heat-insulating barrier (61) is located adjacent to the auxiliary sealed membrane (51), while the main sealed membrane (71) is located adjacent to the main heat-insulating barrier (61). 8. Reservoir (21) according to the previous paragraph, characterized in that the foam polymer tiles (45) of the self-supporting heat-insulating blocks (43) of the second part (31) of the bottom wall (27) have a higher density than the foam polymer tiles (45) of the self-supporting heat-insulating blocks (43 ) the first part (29) of the lower wall (27). 9. Reservoir (21) according to any one of paragraphs. 7, 8, characterized in that the foam polymer tiles (45) of the self-supporting heat-insulating blocks (43) of the second part (31) of the bottom wall (27) have a density essentially equal to the density of the foam polymer blocks (65) of the self-supporting heat-insulating slabs (63) of the second part ( 31) bottom wall (27). 10. Reservoir (21) according to any one of paragraphs. 7-9, characterized in that the density of foam polymer tiles (45) of self-supporting heat-insulating blocks (43) of the first part (29) of the bottom wall (27) is no more than 110 kg/m ³ , while the density of foam polymer tiles (45) of self-supporting heat-insulating blocks (43) of the second part (31) of the lower wall (27) is at least 115 kg/m ³ . 11. Reservoir according to any one of paragraphs. 7-10, characterized in that the group of walls (23, 25, 27) includes an upper wall (23) and side walls (25) connecting the lower wall (27) with the upper wall (23), with each of the upper wall ( 23) and side walls (25) contains an auxiliary sealed membrane (51) and an auxiliary heat-insulating barrier (41), containing a group of self-supporting heat-insulating blocks (43), including foam polymer tiles (45) and at least one sheet (47), while the auxiliary sealed membrane (51) is located adjacent to the auxiliary heat-insulating barrier (41), while the main heat-insulating barrier (61) is located adjacent to the auxiliary sealed membrane (51), while the main sealed membrane (71) is located adjacent to the main heat-insulating barrier (61 ), while the density of foam polymer tiles (45) of self-supporting heat-insulating blocks (43) decreases in the direction from the bottom wall (27) to the top wall (23). 12. Reservoir (21) according to any one of paragraphs. 7-11, characterized in that the foam polymer tiles (45) of the self-supporting heat-insulating blocks (43) of the first part (29), the side walls (25) and the top wall (23) have a density essentially equal to the density of the foam polymer blocks (65) of the self-supporting heat-insulating plates (63) of the first part (29), side walls (25) and the top wall (23), while the foam polymer tiles (45) of the self-supporting heat-insulating blocks (43) of the second part (31) have a density essentially equal to the density of the foam polymer blocks ( 65) self-supporting heat-insulating slabs (63) of the second part (31). 13. Reservoir (21) according to any of the previous paragraphs, characterized in that the lower wall (27) contains a group of second parts (31). 14. Gravity platform (1) containing a liquefied gas storage tank (21) according to any of the previous paragraphs and a pump suction element configured to discharge the liquefied gas contained inside the tank from the drain channel (33). 15. Gravity platform (1) according to the previous paragraph, containing a support structure (3) of the tank (21), wherein the support structure is made of concrete. 16. A system for moving liquefied gas, containing a gravity platform (1) according to any one of paragraphs. 14, 15, insulated pipes (103, 107, 109, 115), placed with the possibility of creating a connection between the tank (21), installed in the supporting structure (3) of the gravity platform (1), and the vessel (100), and a pump for driving into the movement of the flow of liquefied gas through insulated pipes (103, 107, 109, 115) from the tank (21) of the gravity platform (1) to the ship (100). 17. Method for loading or unloading a gravity platform (1) according to any one of paragraphs. 14, 15, characterized in that liquefied gas is transported through insulated pipes (103, 107, 109, 115) from the tank (21) of the gravity platform (1) to the vessel (100).