KR102657084B1 - Rigid tank walls with sealing membrane - Google Patents

Abstract

The present invention relates to a sealed tank wall for storing a fluid, said tank wall being supported by one or more grooves (12) cut in the thickness of the tank wall and extending longitudinally, and by support surfaces (6, 11). Comprising a metal sealing membrane (50, 52), said metal sealing membrane comprising at least one metal support (16) supported by said support surfaces (6, 11), said metal support (16) in a sealing manner. comprising a first stationary wing and a second stationary wing attached to each other, each stationary wing comprising an upper portion of the support surface (11), a base supported in the groove (12), and connecting the upper portion to the base. It includes a rim, wherein the rim of the fixed wing portion can be elastically curved in the transverse direction, so that upper portions of the fixed wing portion move transversely relative to each other.

Description

Rigid tank walls with sealing membrane

The present invention relates in particular to the field of sealed tanks for the storage or transport of fluids, and in particular to sealed and insulated tanks for liquefied gases at low temperatures.

Sealed and insulated tanks are used in particular for the storage of liquefied gases, such as liquefied natural gas (LNG) or liquefied petroleum gas (LPG) stored at atmospheric pressure. This tank can be installed on land or on a floating structure.

Each sealing membrane, especially the primary sealing membrane in contact with the product loaded in the tank, is made up of thin metal sheets called metal strakes connected together in a sealed manner to ensure that the tank is sealed. Tanks are known for example from WO2012072906 or FR3054872.

The metal strakes are fixed to the insulating barrier in this type of tank. Specifically, the upper surface of the thermal insulation barrier is hollow in the thickness direction from the upper surface and has grooves extending in the longitudinal direction of the thermal insulation barrier. A welded support including a base and an arm connected to the base is slidably inserted into the groove. The base is received in the groove and holds the weld support on the insulating barrier in a direction perpendicular to the upper surface. The arms of the weld support protrude above the upper surface.

Two metal strakes are arranged on either side of the weld support. Each of these metal strakes has a flat middle portion on its upper surface. These metal strakes also have raised side edges. The protruding edges of each of the two adjacent metal strakes are welded to either side of the weld support arm. The weld support is generally thicker than the strake.

The raised edges thus form a deformable bellows with the welded support, which can absorb the forces associated with the contraction of the sealed membrane when, for example, cryogenic liquid is loaded into the tank.

Such membranes may be referred to as membranes with internal bellows, where the bellows is oriented towards the interior of the vessel.

A membrane tank is described in WO2015022473 wherein a first tank wall and an adjacent second tank wall form a corner joint, the tank further comprising a sealed corner member positioned at the corner joint. The plates adjacent to the corner joint are in this case connected to each other using two reinforcing wings of the corner elements inside the groove. Therefore, fixation takes place on the outside of the tank. However, the metal plate called corner angle iron also cannot have a deformable bellows at the connection between the two membrane plates, since it covers the fixing area of the corner joint and the reinforcing wings by fixing two plates on the support surface.

During transport of fluids loaded in sealed tanks, the fluid moves from one wall to another due to sloshing, especially if the tank is not completely filled. Sloshing of fluid therefore places stresses on the tank walls, especially on protruding parts such as raised edges. In prior art tanks, these stresses on the raised edge can cause the raised edge to bend. The bent, raised edge no longer acts as a bellows to absorb shrinkage of the membrane and can damage the membrane, compromising the tank's seal.

The idea forming the basis of the invention is to reduce or prevent the risk of bending of the raised edges in order to prevent damage to the sealed tank.

Another idea that forms the basis of the invention is to retain a deformable bellows in the sealing membrane to absorb the forces associated with contraction of the membrane.

Another idea forming the basis of the present invention is to provide a sealed membrane that can be used in sealed tanks for the transport or storage of cold products and maximizes the useful volume of the tank.

According to one embodiment, the present invention provides a sealed tank wall for fluid storage comprising:

- a support surface hollow in the direction of the thickness of the tank wall and comprising at least one groove extending longitudinally;

- a metal sealing membrane supported longitudinally by a support surface, said metal sealing membrane comprising at least one metal support, preferably a plurality of metal supports supported by a support surface, said metal supports being sealed to each other comprising a first stationary wing and a second stationary wing, each stationary wing having an upper portion extending transversely above the support surface, the upper part of the first stationary wing extending at a side of the groove, 2 upper portions of the stationary wings extend from different sides of the grooves, each stationary wing comprising a base supported in a groove of the support surface in a direction perpendicular to the support surface having a longitudinal degree of freedom, each stationary wing having an upper portion thereof; and an arm connecting the base to the base, wherein the arm of the stationary wing can be elastically deformed at a bend in the transverse direction so that upper portions of the stationary wing can move relative to each other in the transverse direction.

Due to this feature, the sealed tank wall does not have raised edges that make up the sealing membrane, but has at least one metal support, so there are no longer any protruding parts affected by the sloshing of the fluid, and no more There is no risk of the raised edges becoming curved. Furthermore, the metal support makes it possible to obtain a membrane with an external bellows, one or more bellows facing the outside of the tank, and one or more bellows capable of absorbing the forces associated with the contraction of the membrane.

According to one embodiment, the support surface includes a plurality of grooves and the sealing membrane includes a plurality of metal supports, at least one base of the stationary wing of the plurality of metal supports being held in each groove.

According to one embodiment, the at least one metal support is made of any type of metal, such as stainless steel.

According to one embodiment, the at least one metal support is made of a metal with a low coefficient of thermal expansion. For example, these metals are iron-nickel alloys with a coefficient of thermal expansion between 1.2 and 2.0 Х 10 ^-6 K ^-1 or iron with a high manganese content, which usually has a coefficient of thermal expansion of the order of 7.5 Х 10 ^-6 K ^-1 . It may be an alloy.

According to one embodiment, the groove includes a flared portion that is open. The flared portion where the groove is open can be made, for example, by using chamfers on both sides of the groove.

Accordingly, the flared portion in which the groove is open can increase the space in which the stationary wing can be deformed and improve the bellows effect by increasing the possible lateral movement of the upper part of the stationary wing.

According to one embodiment, the transverse dimension of the groove is greater than twice the thickness of the stationary wing. The transverse dimension of the groove may for example be greater than 5 times the thickness of the fixed wing.

Due to this feature, the transverse dimensions of the grooves allow to leave free space between the metal support and the grooves, leaving space for the stationary wings to deform, thereby improving the bellows effect of the membrane.

According to one embodiment, the stationary wing parts are welded to each other by primary longitudinal welds inside the grooves.

Therefore, a seal can be created between the two fixed wings through welding. Additionally, the welding takes place inside the groove because the distance between the top of the stationary wing and the primary longitudinal weld in the direction of the thickness of the wall can create and enhance a bellows effect where the membrane needs to shrink. Specifically, the greater the distance between the top of the stationary wing and the primary longitudinal weld, the greater the lateral movement of the membrane.

According to one embodiment, the primary longitudinal weld is located on the arm of the stationary wing.

According to one embodiment, the distance between the top of the fixed wing portion and the primary longitudinal weld portion in the thickness direction of the wall is 15 mm to 50 mm.

According to one embodiment, the metal support includes a connection portion that sealingly connects the bases of the stationary wings to each other within the groove.

Due to this function, the connection can create a seal between the two stationary wings. Additionally, because the base of each stationary wing is connected, the connecting portion is spaced apart from the upper part by the length of the stationary wing arm. The stationary wing arm can thus be elastically deformed in bends over its entire length, potentially allowing greater movement of the top in the transverse direction.

According to one embodiment, the metal sealing membrane comprises a plurality of metal supports arranged parallel to each other, where the upper portions of the stationary wings of two adjacent metal supports are directly or indirectly connected in a sealing manner.

According to one embodiment, the metal sealing membrane comprises a metal strip lying on a support surface, the metal strip being arranged parallel to the metal support, the first edge of the metal strip being connected to the first metal support by a first auxiliary longitudinal weld. and the second edge of the metal strip is welded to the top of the second stationary wing of the second metal support by a second auxiliary longitudinal weld.

According to one embodiment, the metal sealing membrane comprises a plurality of metal strips, one or each of the metal strips being arranged parallel to the metal support.

Accordingly, the membrane includes one or more metal strips and one or more metal supports connecting each of the strips to each other to form a fluid-tight assembly.

According to one embodiment, the thickness of the metal support is greater than or equal to the thickness of the metal strip.

According to one embodiment, the thickness of the metal support is between 0.7 and 1.5 mm and the thickness of the strip is, for example, below 0.7 mm.

According to one embodiment, the metal strip or strips are made of any type of metal, such as stainless steel.

According to one embodiment, the metal strip or strips are made of a metal with a low coefficient of thermal expansion, for example an iron-nickel alloy with a coefficient of thermal expansion between 1.2 and 2.0 Х 10 ^-6 K ^-1. Alternatively, it may be a high manganese iron alloy with an expansion coefficient typically of the order of 7.5 Х 10 ^-6 K ^-1 .

According to one embodiment, one end of the metal strip is positioned between the support surface and the top of the stationary wing, and an auxiliary longitudinal weld is formed at the top, for example at one end of the top, connecting the metal strip to the top.

Due to this feature, it is possible to easily weld metal sheets of different thicknesses by placing the upper part of the fixed wing on a metal strip.

According to one embodiment, the cross-section of the metal strip comprises a flat middle portion lying on the support surface and at least one offset portion parallel to the support surface and at a distance therefrom, the upper portion of the stationary wing being between the support surface and the offset portion. disposed, wherein an auxiliary longitudinal weld connecting the top and the edge of the metal strip is made on an offset portion of the metal strip.

This feature makes it easier to secure the stationary vanes to the strip because the overlap of the offset portion and the top facilitates welding and allows manufacturing tolerances for larger parts.

According to one embodiment, the offset portion is formed by stamping one end of a metal strip or welding a plate attached to one end of the metal strip.

According to one embodiment, the one or more metal strips have two offset portions on either side of the flat middle portion.

According to one embodiment, the distance between the support surface and the offset portion is substantially equal to or greater than, preferably substantially equal to, the thickness of the top of the stationary wing portion.

According to one embodiment, the metal support or cross-section of the top of the metal support comprises a flat portion lying on the support surface and at least one offset portion parallel to and at a distance from the support surface, wherein a portion of the metal strip is located on the support surface. An auxiliary longitudinal weld, located between the upper part and the offset part, connecting the upper part with the edge of the metal strip, is made on the upper offset part.

According to one embodiment, the groove is a main groove and the support surface is hollow in the thickness direction and comprises at least one auxiliary groove extending longitudinally close to, preferably close to, the main groove, wherein at least One portion or upper part of the stationary wing is located in the auxiliary groove. At least one part or upper part of the stationary wing located in the auxiliary groove may be for example under a metal strip.

Therefore, if the strip overlaps the top located in the auxiliary groove, it becomes easier to secure the stationary wing to the strip because it facilitates welding and allows manufacturing tolerances for larger parts.

According to one embodiment, the sealed tank wall includes an insulating layer in a secondary groove below the top of the fixed wing section.

According to one embodiment, the support surface includes two auxiliary grooves on either side of the main groove.

According to one embodiment, the dimension of the auxiliary groove in the thickness direction is substantially equal to or larger than the thickness of the top of the fixed wing portion.

According to one embodiment, the dimensions of the auxiliary groove in the transverse direction are substantially equal to or larger than the dimensions of the top of the stationary wing in the transverse direction.

According to one embodiment, the groove has an inlet region extending in the thickness direction, the groove comprising a retaining region arranged below the inlet region and extending parallel to the support surface over a greater width than the inlet region, wherein The base of at least one stationary wing of the metal support is received in the holding area.

According to one embodiment, the holding area extends parallel to the support surface on either side of the inlet area.

According to one embodiment, the base of one or each of the stationary wings is flat.

According to one embodiment, the groove comprises at least one fastener, the fastener configured to retain one of the bases of the metal support in the groove, preferably the groove comprising the base of the first stationary wing and the second stationary wing. Includes two fasteners to secure the base of the wing.

According to one embodiment, one of the bases of the metal support has a round shape and the fastener has complementary rounded parts such that the base of the metal support and the round part of the fastener fit within each other. Preferably, the two bases of the metal support each have a round shape and the two fasteners each have complementary rounded portions such that the corresponding bases of the metal support and the rounded portions of the fastener fit inside each other.

According to one embodiment, the sealed tank wall includes an insulating barrier including a top panel including a support surface. Such thermal insulating barriers can be produced in various ways, for example according to the technology described in publications FR-A-2798902, WO-A-2017103500 or WO-A-2017207938.

According to one embodiment, the thermal insulating barrier is a primary thermal insulating barrier and the sealing membrane is a primary sealing membrane, and the sealed tank wall comprises a secondary thermal insulating barrier and a secondary sealing membrane arranged below the primary thermal insulating barrier.

According to one embodiment, the present invention provides a polyhedral sealed tank comprising a plurality of sealed tank walls fixed to each other in a sealing manner to form a polyhedral internal space for fluid storage, wherein one of the sealed tank walls The above is the same as described above.

According to another advantageous embodiment, such a tank may have one or more of the following features:

According to embodiments, the tank may include one or more tank walls from the following list:

- ceiling walls,

- bottom wall,

- one or more cofferdam side walls connecting the floor wall to the ceiling wall,

- one or more side walls connecting cofferdam side walls or walls,

- one or more lower walls forming a chamfer connecting the side wall or walls to the bottom wall, and

- one or more upper walls forming a chamfer connecting said side wall or walls to the ceiling wall;

One or more of the tank walls listed may be tank walls as described above.

These tanks may form part of an onshore storage facility, for example for LNG storage, or may be installed on floating structures, offshore or deep sea, especially LNG carriers, floating storage and regasification units (FSRUs), remote floating production and storage units ( FPSO), etc. These tanks can also be used as fuel tanks on all types of carriers.

According to one embodiment, the invention also provides a vehicle for transporting liquid products, the vehicle comprising a hull and a tank according to the invention arranged on the hull.

According to one embodiment, the present invention provides a method of loading or unloading such a vehicle, wherein liquid product is transferred to or from a floating or land-based storage facility through an insulated pipeline, or to a sealed tank of the vehicle. It is transported.

According to one embodiment, the present invention also provides a transfer system for transferring liquid products, the system comprising the above-described vehicle, a sealed tank installed in the hull of the vehicle arranged to connect to a floating or land-based storage facility. It includes an insulated pipeline, and a pump for pumping a flow of cooled liquid product through the insulated pipeline to or from a floating or land-based storage facility, or to a sealed tank of the vehicle.

According to the present invention, it is possible to reduce or prevent the risk of bending of the raised edge to prevent damage to the sealed tank.

According to the invention, it is possible to retain a deformable bellows in the sealing membrane to absorb the forces associated with contraction of the membrane.

According to the present invention, it is possible to provide a sealed membrane that can be used in sealed tanks for the transport or storage of cold products and maximizes the useful volume of the tank.

The present invention will be better understood and other objects, details, features and advantages will become more apparent during the following description of several specific embodiments of the invention, which are given by way of non-limiting example only with reference to the accompanying drawings.
Figure 1 is a partial perspective view of a part of the wall of a sealed and insulated tank according to the present invention cut away.
Figure 2 is a schematic cross-sectional view of a metal support fixed to a support surface, the base of which is flat.
Figure 3 is a schematic cross-sectional view of a metal support fixed to a support surface, the base of the support being flat and the support being welded under the metal strip.
Figure 4 is a schematic cross-sectional view of a metal support fixed to a support surface, the base of the support being round and secured to a fastener/fastener and the support being welded to a metal strip.
Figure 5 is a partial perspective view of a metal support fixed to a support surface according to Figure 4;
Figure 6 is a schematic cross-sectional view of a metal support fixed to a support surface with auxiliary grooves.
Figure 7 is a schematic cross-sectional view of a metal support fixed to a support surface, the support being welded onto the metal strip.
Figure 8 schematically shows, partially cut away, a vehicle comprising sealed tanks for storing fluids and terminals for loading/unloading these tanks.

In the description below, reference is made to sealing membranes in relation to sealed tanks. Such a tank comprises an internal space formed by a plurality of tank walls intended to be filled, for example, with a flammable or non-combustible gas. The gas is liquefied natural gas (LNG), which is a gaseous mixture containing mainly methane but also one or more other hydrocarbons such as ethane, propane, n-butane, i-butane, n-pentane, i-pentane, neopentane, and small amounts of nitrogen. It can be. The gas may also be ethane or liquefied petroleum gas (LPG), which is a mixture of hydrocarbons obtained from petroleum refining including mainly propane and butane.

By convention, the longitudinal direction is defined as the longitudinal direction of the tank wall. The thickness direction is defined as the thickness direction of the tank wall. The transverse direction is defined as the width direction of the tank wall. The longitudinal direction, transverse direction and thickness direction form a three-dimensional Cartesian coordinate system.

The sealing membranes 50, 52 lie on the support surface 11 formed by the thermal insulating barriers 51, 53 of the tank 71. These sealing membranes 50, 52 are connected on the one hand to a sheet metal strip 22 arranged on the support surface 11 and on the other hand to said support surface 11 and extend at least part of the length of the sheet metal strip 22. It has a repeating structure with alternating long metal supports (16) extending parallel to the sheet metal strip (22). One end of the sheet metal strip 22 is welded to an adjacent metal support 16. This structure is used, for example, in the NO96 tank for LNG carriers sold by the applicant.

Referring to Figure 1, in this case, the support structure of the carrier ship consists of the inner wall 1 of the double hull 72 of the carrier ship 70. In a manner known per se, the tank 71 comprises a secondary insulating barrier 53 fixed to the support structure of the carrier 70 . This secondary insulating barrier 53 consists of a plurality of parallelepiped secondary insulating compartments 2 arranged side by side so as to substantially cover the inner surface of the support structure.

Each secondary insulated compartment (2) is a parallel structure made of plywood, internally containing a load-bearing bulkhead (3) and a non-load-bearing bulkhead (4) intended to ensure the relative position of the load-bearing bulkheads (3). It consists of a hexahedral box, and the partition wall is sandwiched between the plywood lower panel (5) and the plywood upper panel (6). The lower wall 5 of the compartment 2 protrudes laterally on the two smaller sides of the compartment, and battens 7 are fastened to this protrusion at each edge of the compartment to give the thickness of the protrusion. The batten 7 interacts with a member for fastening the compartment 2 to the support structure.

Each compartment 2 is filled with an insulating particulate material, for example perlite or glass wool. The lower plate 5 of each compartment 2 prevents the resin of the adhesive beads from sticking to the support structure and thus allows dynamic deformation of the support structure without the compartment 2 experiencing forces due to deformation. For this purpose, kraft paper (9) is used to place beads (8) of polymerizable resin which themselves lie on the support structure (1). The purpose of the beads 8 of polymerizable resin is to compensate for the differences between the theoretical surface provided for the support structure and the imperfect surface due to manufacturing tolerances. The upper panel 6 of the secondary insulating compartment 2 may also have a substantially inverted I, L or T shape, for example, to receive a metal support 16 of L, T or J shape. It includes a pair of parallel grooves (12).

The metal support 16 has first stationary wings 17 and second stationary wings 18 fixed to each other to form a sealed metal support 16 . The stationary wings 17, 18 each comprise an upper part 21 extending transversely above the support surface 11. The upper part 21 of the first stationary wing 17 extends on one side of the groove 12, while the upper part 21 of the second stationary wing 18 extends on the other side of the groove 12.

The stationary wings 17, 18 each include a base 19 held in a groove 12 of the support surface 11 in a direction perpendicular to the support surface 11 with a degree of freedom in the longitudinal direction. The fixed wings 17 and 18 further include arms 20 connecting the upper part 21 to the base 19, respectively.

The secondary sealing membrane 52 is composed of a plurality of metal strips 22 with a thickness of about 0.7 mm. The end of each metal strip 22 is welded to the above-described metal support at the top 21 of the stationary wings 17, 18. The metal strip 22 is made of a strong metal such as stainless steel or a metal with a low coefficient of thermal expansion, for example an iron-nickel alloy with a coefficient of thermal expansion of 1.2 to 2.0 Х 10-6 K-1, or It may be an iron alloy with a high magnesium content whose coefficient of expansion is typically 7.5 Х 10-6 K-1.

The secondary sealing membrane 52 is equipped with a primary insulating barrier 51, which also consists of a plurality of primary insulating partitions 10 having a similar structure to the secondary insulating partitions 2. Each of the primary insulating compartments 10 consists of a rectangular box made of plywood with a height smaller than the compartment 2 filled with particulate material such as perlite or glass wool. The primary insulated compartment (10) also includes a load-bearing internal bulkhead, a lower panel and an upper panel (11).

The top panel 11 is shaped, for example substantially inverted I, L or T, for receiving a metal support 16 to which the ends of the strips 22 of the primary sealing membrane 50 are welded. It has two grooves (12).

The groove 12 may have a retaining area 13 extending parallel to the support surface 11 in the thickness of the insulating barrier 51 , 53 . The holding area 13 extends at the end of the groove 12 opposite the support surface 11 in the thickness of the insulating barrier 51, 53. The groove 12 then has an L-shaped cross section, the base of which is formed by the holding area 13.

In the case of the T-shaped metal support 16, the groove 12 has a T-shaped cross section, and its base is formed by retaining areas 14 located on both sides of the entrance area 13 of the groove 12. The base 17 of the metal support 16 is received in a holding area 14 for holding the metal support 16 on the insulating barrier in a direction perpendicular to the support surface 11 .

In the case of the J-shaped metal support 16, the groove 12 has an I-shaped or L-shaped section. The groove 12 may have a holding area 14 but this is optional. Accordingly, the groove may only have an entrance area 13. The groove 12 comprises an inverted J-shaped fastener/fastener 26 with a rounded part 27 complementary to one of the bases 19 of the metal support 16, which also provides a support surface 11 ) is rounded to be fixed to the round portion 27 of the fastener 26 to hold the metal support 16 on the insulating barrier in a direction perpendicular to The groove 12 includes two fasteners 26 on both sides of the groove 12, so as to secure the base 19 of the first fixed wing 17 and the base 19 of the second fixed wing 18. It is desirable to maintain .

2 to 6 show multiple embodiments of a metal support 16 secured to a support surface 11 .

Each of the various embodiments is fixed to a metal support 16, for example the groove 12 shown in FIG. 4, with the base 17 received in the holding area 14 of the groove 12 shown in FIG. 2, for example. The complementary round part 27 of the fastener 26 is fixed to the metal support 16 with which the round part 17 interacts, respectively, or to the retaining area 14 of the groove 12. It uses a metal support (16) on which the round portion (27) and each round base (17) interact.

Figure 2 shows an embodiment of a metal support 16 fixed to a support surface 11. In this embodiment, the stationary wing parts 17, 18 of the metal support 16 are welded back to back to each other, so that the base 19 of the stationary wing parts 17, 18 is separated from the other stationary wing parts 17, 18. It faces away. The stationary wings 17, 18 are welded using primary longitudinal welds 28 inside the grooves 12 and at a distance from the top 21 of the stationary wings 17, 18. The primary longitudinal welds 28 are formed on the arms 20 of the stationary wings 17, 18. The portion of the arm 20 over the primary longitudinal weld 28 and the top 21 of the metal support 16 form a deformable bellows, wherein the metal support 16 forms part of a sealing membrane. It allows absorbing the forces associated with thermal contraction.

In the embodiment of Figure 2, the sealing membranes 50, 52 are grooved in the insulating barriers 51, 53 such that the metal supports 16 can be welded directly to each other by adjacent tops 21 to form a sealed assembly. It may be composed of a plurality of metal supports (16) each disposed at (12).

Figure 3 shows another embodiment of a metal support 16 fixed to a support surface 11. This embodiment differs from the embodiment of Figure 2 in that the metal supports 16 are not directly welded to each other. Specifically, the sealing membranes 50, 52 include a plurality of metal strips 22. The metal strips 22 are arranged parallel to each other on the support surface 11 . The upper part 21 of the first fixed wing 17 is welded to the metal strip 22 by an auxiliary longitudinal welding part 29, and the upper part 21 of the auxiliary fixed wing 18 is welded to the auxiliary longitudinal welding part 29. It is welded to the adjacent metal strip 22 by a weld 29.

Moreover, the cross-section of each metal strip 22 has a flat intermediate portion 23 lying on the support surface 11 and at least one offset portion 24 parallel and spaced from the support surface 11 . The offset portion 24 is disposed at one end of the flat middle portion 23. Accordingly, the upper part 21 of the stationary wings 17, 18 is located between the support surface 11 and the offset part 24. Accordingly, an auxiliary longitudinal weld 29 connecting one of the tops 21 and one of the metal strips 22 is formed on the offset portion 24 of the metal strip 22 . Due to the offset portion 24, the metal strip 22 overlaps the metal support 16.

4 and 5 show another embodiment of a metal support 16 fixed to a support surface 11 . This embodiment is distinguished from the embodiment of Figure 3 by the shape of the groove, the shape of the base 19 and the connection between the base 19 and the groove 12. Specifically, in this embodiment, the sealing membranes 50, 52 are metal supports having round bases 17 each interacting with complementary round parts 27 of fasteners 26 secured in grooves 12. Includes (16).

Figure 6 shows another embodiment of a metal support 16 fixed to a support surface 11. This embodiment differs from the embodiment of Figure 3 in that the stationary vanes are not fastened together by welding and the metal strip 22 has no support. Specifically, in this embodiment, the metal support 16 includes a connecting portion 30 that sealingly connects the bases 19 of the stationary wings 17 and 18 to each other within the groove 12. Therefore, there is no need to weld the arms of the fixed wing portion to each other. Moreover, the support surface 11 is hollow in the thickness direction and includes two auxiliary grooves 15 extending longitudinally close to the main groove 12 . Accordingly, the upper part 21 of the fixed wing is located in the auxiliary groove 15, and at least a part of the upper part 21 passes under the metal strip 22. Accordingly, in this embodiment, it is not the offset portion 24 but the auxiliary groove 15 that allows the overlap of the metal support 16 and the metal strip 22.

The heat insulating layer 25 is disposed in the auxiliary groove 15 below the upper part 21 of the fixed wings 17 and 18. Additionally, in the embodiment of FIG. 6, the main groove 12 includes a flared portion 31 formed at the top of the main groove 12. The flared portion 31 is formed by chamfering the wall of the main groove 12. The flare portion 31 increases the space in which the fixed wings 17 and 18 can be deformed.

The techniques described above for creating sealed tank walls can be used in other types of tanks, for example to form sealed tank walls of LNG storage tanks in land-based facilities or in floating structures such as LNG carriers.

Figure 7 shows another embodiment of a metal support 16 fixed to a support surface 11. This embodiment is also different from embodiment 3 in that the upper part 21 of the stationary wings 17 and 18 is not located between the support surface 11 and the metal. Specifically, the sealing membranes 50, 52 include a plurality of metal strips 22. The metal strips 22 are arranged parallel to each other on the support surface 11 . The upper part 21 of the first fixed wing 17 is welded to the metal strip 22 by an auxiliary longitudinal weld 29, and the upper part 21 of the auxiliary fixed wing 18 is welded to the auxiliary longitudinal weld part 29. It is welded to the adjacent metal strip (22) by (29).

Unlike in Figure 3, in this embodiment of Figure 7 the metal strip 22 does not have an offset portion. The metal strip 22 is in this case substantially flat, so that after assembly a part of the metal strip is located between the upper part 11 and the support surface 11 of the stationary wings 17 , 18 . Accordingly, the auxiliary longitudinal weld 29 is formed on one end of the upper part 21 to connect the metal strip 22 to the metal support 16.

During assembly of the sealing barrier of the tank wall, the metal support 16 is inserted into the main groove 12 and the stationary wings 17, 18 are already welded to each other by the main longitudinal weld 28. there is. Next, the metal strip 22 is inserted under the tops 21 of two adjacent metal supports 16 on the support surface 11 so that the metal strip 22 can be wedged laterally. The metal strip 22 is then welded to the top 21 of an adjacent metal support by means of an auxiliary longitudinal weld 29 to form a sealing membrane.

The auxiliary longitudinal weld 29 is formed on or at a distance from the lateral end edge of the top 21 as shown.

In an embodiment not shown, the embodiments shown in Figures 3, 6 and 7 may be combined, for example. Specifically, the metal strip 22 comprises a flat middle part lying on the support surface and an offset part 23 parallel to the support surface 11 as in Figure 3 but this time located in the auxiliary groove 15 in Figure 6. do. The metal support 16 is disposed on an offset portion 23, so that the offset portion is located between the top 21 of the fixed wings 17 and 18 and the bottom of the auxiliary groove 15. The auxiliary longitudinal weld 29 is then formed on the top 21 and the offset portion 23 to connect the metal support 16 to the metal strip 22.

Referring to Figure 8, a partially cut-away view of an LNG carrier 70 shows a generally prismatic sealed and insulated tank 71 mounted on the double hull 72 of the carrier. The walls of the tank 71 are comprised of a primary seal barrier intended to contact the LNG loaded in the tank, a secondary seal barrier disposed between the primary seal barrier of the carrier and the double hull 72, and a primary seal barrier and 2. It includes two insulating barriers disposed respectively between the primary seal barrier and between the secondary seal barrier and the double hull 72.

In a manner known per se, the loading/unloading pipeline 73 arranged on the upper deck of the carrier will be connected via suitable connectors to a sea or port terminal for transporting LNG cargo to or from the tank 71. You can.

Figure 8 shows an example of a marine terminal including loading and unloading stations 75, underwater pipes 76 and land facilities 77. The loading and unloading station 75 is a fixed marine facility comprising a movable arm 74 and a tower 78 supporting it. The movable arm 74 supports a bundle of insulated flexible pipes 79 that can be connected to a loading/unloading pipe line 73. The orientable movable arm 74 can be adjusted to fit any size LNG carrier. A connecting pipe (not shown) extends inside the tower 78. A loading and unloading station 75 allows loading and unloading of LNG carriers 70 from an onshore facility 77. This facility includes a tank 80 for storing liquefied gas and a connecting pipe 81 connected to a loading and unloading station 75 by a submerged pipe 76. The submersible pipe 76 allows liquefied gas to flow between the loading or unloading station 75 and the onshore facility 77 at a distance of, for example, 5 km, which allows to maintain the LNG carrier 70 at a distance from the floating bed during loading and unloading operations. enable it to be transported.

To generate the pressure necessary to deliver the liquefied gas, pumps mounted on the carrier vessel 70 and/or pumps mounted on the shore facility 77 and/or pumps mounted on the loading and unloading station 75 are used. .

Although the invention has been described in connection with several specific embodiments, it is clear that, if included within the scope of the invention, the invention is not limited thereto and includes all technical equivalents of the described means and combinations thereof.

The use of the verbs “comprise” or “comprise” and their conjugations do not exclude the presence of other elements or steps other than those specified in the claims.

Reference signs in parentheses in the claims should not be construed as limiting the scope of the claims.

11: support surface 12: groove
16: metal support 17: first fixed wing portion
18: second fixed wing part 21: upper part

Claims (17)

A sealed tank wall for storing a fluid, the tank wall comprising:
A support surface (11) hollow in the thickness direction of the tank and having at least one groove (12) extending longitudinally, which groove (12) extends from the support surface (11). a support surface (11) comprising an opening that opens; and
A longitudinally extending metal sealing membrane (50, 52) supported by the support surface (11), the metal sealing membrane (50, 52) comprising at least one metal support supported by the support surface (11) 16), wherein the metal support 16 includes a first fixed wing part 17 and a second fixed wing part 18 that are sealed and fixed to each other, and each fixed wing part 17, 18 is The upper part of the first stationary wing 17 is on one side of the groove 12, including a top 21 extending above the support surface 11 in a transverse direction parallel to the support surface at the opening of the groove. extending parallel to the support surface, wherein the upper part 21 of the second stationary wing 18 extends parallel to the support surface on the other side of the groove 12, and extends parallel to the support surface in the longitudinal, transverse and thickness directions. forms a three-dimensional vertical coordinate system, and each of the stationary wings 17, 18 has a base 19 received in a groove of the support surface 11 in a direction perpendicular to the support surface 11 having a degree of freedom in the longitudinal direction. ), wherein the stationary wings (17, 18) comprise a metal sealing membrane, each having an arm (20) connecting the upper part (21) to the base (19),
The arms 20 of the fixed wings 17 and 18 are elastically deformable at a bend in the transverse direction so that the upper portions 21 of the fixed wings 17 and 18 can move relative to each other in the transverse direction. Features sealed tank walls. According to claim 1,
Sealed tank wall, characterized in that the fixed wings (17, 18) are welded to each other by a primary longitudinal weld (28) inside the groove (12). The method of claim 1 or 2,
A sealed tank wall, characterized in that the metal support (16) includes a hot joint (30) that sealingly connects the bases (19) of the stationary wings (17, 18) to each other within the groove (12). The method of claim 1 or 2,
The metal sealing membranes 50 and 52 include a plurality of metal supports 16 arranged in parallel with each other, and the upper portions 21 of the fixed wings 17 and 18 of the two adjacent metal supports 16 are sealed. A sealed tank wall characterized in that it is directly or indirectly connected in a manner. According to claim 4,
The metal sealing membrane (50, 52) comprises a metal strip (22) placed on the support surface (11), wherein the metal strip (22) is arranged parallel to the metal support (16), The first edge of (22) is welded to the upper part (21) of the first stationary wing (17) of the first of the metal supports by a first auxiliary longitudinal weld (29), the first edge of the metal strip (22) Sealed tank wall, characterized in that the two edges are welded to the upper part (21) of the second stationary wing (18) of the second of the metal supports by a second auxiliary longitudinal weld (29). According to claim 5,
One end of the metal strip is disposed between the upper part 21 of the stationary wings 17, 18 and the support surface 11, and the auxiliary longitudinal weld 29 is connected to the upper part 21 by a metal strip 22. ), characterized in that it is formed on the upper part (21) to connect the tank wall. According to claim 5,
The cross-section of the metal strip (22) comprises a flat middle part (23) lying on the support surface (11) and at least one offset part (24) parallel to the support surface (11) at a distance from the support surface (11). The upper part 21 of the parts 17, 18 is disposed between the support surface 11 and the offset part 24, the auxiliary length connecting the upper part 21 and the edge of the metal strip 22. Sealed tank wall, characterized in that a directional weld (29) is formed on an offset portion (24) of the metal strip (22). According to claim 5,
The groove 12 is the main groove 12,
The support surface (11) is hollow in the thickness direction and includes at least one auxiliary groove (15) extending longitudinally adjacent to the main groove (12), wherein the upper part (21) of the stationary wing portion is Sealed tank wall, characterized in that it is arranged inside the auxiliary groove (15) and below the metal strip (22). The method of claim 1 or 2,
The groove 12 has an inflow area 13 extending in the thickness direction,
The groove (12) is disposed below the inlet area (13) and has a retaining area (14) extending parallel to the support surface (11) at a width greater than the inlet area (13),
Sealed tank wall, characterized in that the base (19) of at least one stationary wing of the metal support (16) is received in a holding area (14). The method of claim 1 or 2,
The groove (12) comprises at least one fastener (26), the fastener (26) adapted to retain one of the bases (19) of the metal support (16) within the groove (12). tank wall. According to claim 10,
At least one base 19 of the metal support 16 has a round shape, and the fastener 26 has a complementary round part 27, so that the base 19 of the metal support 16 and the fastener 26 have a round shape. Sealed tank wall, characterized in that the round portion (27) of the fastener (26) is fastened inside another. The method of claim 1 or 2,
A sealed tank wall, characterized in that the sealed tank wall comprises an insulating barrier (51, 53) comprising a top panel with the support surface (11). According to claim 12,
The thermal insulation barrier is a primary thermal insulation barrier (51), and the sealing membrane is a primary sealing membrane (50),
A sealed tank wall, characterized in that the sealed tank wall comprises a secondary thermal insulating barrier (53) and a secondary sealing membrane (52) disposed below the primary thermal insulating barrier (51). A sealed tank (71) comprising a plurality of sealed tank walls fixed to each other in a sealed manner to form a polygonal internal space for storing fluid, comprising:
Sealed tank (71), characterized in that one of the sealed tank walls is a sealed tank wall according to claim 1 or 2. A carrier (70) for the transport of liquid products, comprising a hull (72) and a sealed tank (71) according to claim 14 arranged on the hull. A method of loading or unloading a carrier (70) according to claim 15, comprising:
The liquid product is transported in insulated pipelines 73, 79, 76, 81 from or to a floating land storage facility 77 or from or to a sealed tank of the carrier 70. A method of loading or unloading a carrier, characterized in that it is transported through. A transport system for transporting liquid products, comprising:
The system comprises a carrier vessel (70) according to claim 15, insulated pipelines (73, 79, 76) arranged to connect a sealed tank (71) installed on the hull of said carrier to a floating or land-based storage facility (77). , 81), and a transport system comprising a pump for pumping a flow of liquid product through an insulated pipeline from or to a floating or land-based storage facility or to or from a sealed tank of a carrier. .