WO2019048788A1

WO2019048788A1 - Floating structure comprising a tank suitable for containing liquefied combustible gas

Info

Publication number: WO2019048788A1
Application number: PCT/FR2018/052181
Authority: WO
Inventors: Alexandre Tocatlian; Abdoulaye DIOUF
Original assignee: Gaztransport Et Technigaz
Priority date: 2017-09-07
Filing date: 2018-09-06
Publication date: 2019-03-14
Also published as: FR3070673A1; EP3678928B1; CN111212780A; RU2020108813A3; JP7159301B2; JP2020533225A; CN111212780B; KR20200051707A; RU2759454C2; FR3070673B1; RU2020108813A; EP3678928A1; KR102601132B1

Abstract

Floating structure comprising at least a first bridge (11) and an intermediate load-bearing wall (12), the floating structure comprising a tank (1) suitable for containing liquefied combustible gas and arranged below the intermediate load-bearing wall (12), at least one pipe (2, 3) connecting the tank (1) to the management device (7) and a connection device (5) comprising one or more isolation valves (4) arranged on the one or more pipes (2, 3) and an enclosure (6) enveloping the one or more isolation valves (4) in a sealed manner, in which the tank (1) is a tank with a membrane integrated into the shell and the connection device (5) is arranged above the intermediate load-bearing wall (12) and at least partially under the first bridge (11) in a space set up as a cofferdam.

Description

FLOATING OPENING COMPRISING A TANK CAPABLE OF CONTAINING LIQUEFIED COMBUSTIBLE GAS

Technical area

The present invention relates to a tank system for liquefied gas, of the type on board a ship or other floating structure.

Liquefied natural gas or LNG is mainly composed of methane. The invention also applies to liquefied petroleum gas, and any combustible liquefied gas.

Technological background

Liquefied natural gas can be shipped aboard a ship to be transported, it is called LNG carrier or LNG carrier. Alternatively, the liquefied natural gas can be shipped to form the, or at least one of the fuel propelling ships of any type, for example container carriers. This is called an LNG fueled ship or LFS. The invention applies more particularly to floating structures of this second category.

Liquefied natural gas, in that it has complete combustion, is much less polluting than conventional fuels such as gasoline or gas oil. Liquefied natural gas has a high mass energy and because of its liquefaction, providing a high compression, a large volume energy. Also, liquefied natural gas is becoming an advantageous alternative for the propulsion of ships.

However, gas, mainly because of its liquefaction, induces safety constraints related to its confinement and to the dangers accompanying a possible leak. These constraints lead to precautionary measures, such as, for example, those recommended by the international regulation "IGF Code" published by the International Maritime Organization, London.

As illustrated in FIG. 4, a ship 10 comprises, in a known manner, a first bridge 11 or an upper deck, which may notably be designed to carry a payload C and / or cabins and living spaces for passengers.

It is still known to have a tank 1, which contains the liquefied natural gas, below the first bridge 11. As schematically illustrated in FIG. 1, a tank 1 intended to contain combustible liquefied gas comprises at least one incoming pipe 2 (loading or filling) and at least one outgoing pipe 3 (unloading or drawing). These pipes 2, 3 typically connect the tank 1 to a management device 7 which interfaces with both gas suppliers and consumers / users. A typical consumer is the propulsion motor 45 of the ship. An example of the management device 7 is described in the publication FR-A-3004513.

In order to be able to isolate said tank 1, it is desirable to equip each of these incoming pipes 2 or outgoing 3, an isolation valve 4, advantageously arranged closer to the tank 1, in order to close as close as possible of the tank 1 in case of leakage in a pipe.

The "IGF code" regulation recommends placing these isolation valves 4 in a sealed chamber that is called connection device 5 or "Tank Connection Space" in English or TCS.

The "IGF code" regulation still recommends the presence of a cofferdam of at least 900 mm between the vessel 1 and the management device 7. A cofferdam or dry mesh is a confined volume, substantially empty, allowing a physical segregation between a zone presenting a risk of fire such as the management device 7 and an area to be protected such as the tank 1.

summary

An idea underlying the invention is to provide a structure that meets these various constraints, while facilitating installation.

For this, the invention proposes a floating structure comprising a shell, at least a first bridge and an intermediate support wall disposed below the first bridge, the floating structure comprising a vessel adapted to contain gas liquefied fuel and disposed below the intermediate carrier wall, at least one pipe connecting the vessel to a management device, in particular at least one filling pipe and at least one draw pipe, and a connecting device comprising at least one valve isolation device disposed on said at least one pipe, in particular an isolation valve disposed on each of said pipes, and an enclosure enclosing the one or more isolation valves in a sealed manner, in which the tank is a diaphragm tank integrated into said hull, the walls of the tank comprising, successively from the outside to the inside of the tank, at least one thermal insulation layer carried by, and preferably anchored to, an inner surface of said shell and by a lower surface of the intermediate carrier wall and at least one sealed membrane disposed on an inner surface of said insulation layer th in which the connecting device is disposed above the intermediate carrier wall and at least partially under the first bridge.

Such a membrane tank is formed of a multilayer structure built directly on the load-bearing walls provided by the ship's structure, unlike a self-supporting tank, which makes it possible to optimize the useful volume.

According to embodiments, such a floating structure may include one or more of the following features.

According to one embodiment, a space between the first bridge and the intermediate carrier wall is arranged in cofferdam, preferably around the connection device.

According to one embodiment, the connection device is supported above the intermediate bearing wall by said or each pipe, in particular by the filling pipe and / or the drain pipe.

According to one embodiment, the connection device is supported by the intermediate carrier wall.

According to one embodiment, the or each pipe comprises a primary pipe having one end immersed in the vessel and a secondary pipe having one end connected to said isolation valve, the other end of the primary pipe being joined to the other end of the secondary pipe.

According to embodiments, the assembly of the primary pipe to the secondary pipe can be achieved by an assembly means which comprises a flange or a sleeve, or by welding the two pipes end to end.

The assembly means may be disposed outside or inside the sealed enclosure. For example, the assembly means may be wrapped in an independent sealed enclosure and separated from the sealed enclosure which contains the isolation valves. The advantage of this second sealed enclosure is to improve the protection of the vessel against the risk of fire in case of leakage of the assembly means or hoses.

According to one embodiment, the ceiling wall of the tank and the intermediate bearing wall comprise a wall penetration through which said at least one pipe, for example the primary pipes, pass (s) sealingly.

According to one embodiment, the wall penetration is performed in a portion of the intermediate carrier wall made of a material resistant to liquefied natural gas, preferably stainless steel.

According to another feature, the length of a pipe between the bushing and the isolation valve is as short as possible. Preferably, the isolation valve is located immediately above the intermediate carrier wall.

According to one embodiment, the connection device is arranged in a hopper made in the first bridge and comprises, facing the hopper, a sealing means attached to the periphery of the hopper, which is preferably capable of allowing a catch-up of play, between the enclosure and the edge of the hopper.

According to one embodiment, said at least one filling line comprises a gas phase filling pipe and a liquid phase filling pipe, and said at least one drawing pipe comprises a gas phase draw pipe and a liquid phase draw pipe, one or each pipe in the liquid phase, gaseous phase opening at the top of the tank and one or each line in the liquid phase opening at the bottom of the tank.

According to one embodiment, the enclosure is made of a material resistant to liquefied natural gas, preferably stainless steel.

According to one embodiment, the enclosure comprises a trapdoor.

According to one embodiment, the walls of the tank comprise, successively from the outside towards the inside of the tank, a secondary thermal insulation layer, a secondary waterproof membrane, a primary thermal insulation layer and a primary waterproof membrane. intended to be in contact with the product contained in the tank.

In one embodiment, metal stiffeners are attached to an upper surface of the intermediate support wall opposite the vessel wall. Thus, the intermediate support wall may offer greater rigidity while having a regular lower surface to carry the ceiling wall of the tank. Similarly metal stiffeners may be attached to a lower surface of the first bridge.

The metal membrane (s) may have a thickness of, for example, between 0.5 mm and 3 mm, preferably between 0.7 and 1.5 mm. Examples of such metal membranes are known for example in the applicant's N096® and Mark III® technologies.

The space between the first bridge and the intermediate support wall can be designed in a fairly compact manner, in order to maximize the useful volume of the tank. For example, this space has a height less than 1m80, preferably less than 1m60, or even less than 1m30. Preferably, the intermediate bearing wall is located immediately below the first bridge, without being separated from it by other horizontal metal partitions or by another bridge.

According to one embodiment, the intermediate bearing wall comprises a recessed portion offset downward with respect to a remaining portion of the intermediate carrier wall and the connecting device is disposed in line with said recessed portion.

Thanks to these characteristics, the connecting device disposed in line with said recessed portion is located in an area where the distance between the first bridge and the intermediate bearing wall is greater than that of the remaining portion. The height of the space between the first bridge and the intermediate carrier wall may thus be smaller, especially less than 1 m, for example close to 0.9 m.

According to one embodiment, the invention also relates to a method of filling the vessel of a vessel or other floating structure as mentioned above in which a fluid is conveyed through isolated pipes from a floating storage facility or to the tank of the vessel or other floating structure.

According to one embodiment, the invention also relates to a system comprising a ship or other floating structure as mentioned above, insulated pipes arranged to connect the vessel installed in the hull of the ship or other floating structure to an installation floating or ground storage tank and a pump for driving fluid flow through the isolated pipelines from the floating or land storage facility to the vessel tank or other floating structure. The shell may be a double shell, having an inner shell and an outer shell.

Other preferred characteristics of the sealed enclosure are:

- All the connections of the tank and the corresponding isolation valves are in the enclosure waterproof.

the enclosure is gastight to reliably contain any leakage of the pipes connected to the tank. In particular, the sealed enclosure contains the connectors of the pipes such as flanges.

- A ventilation of the sealed enclosure to a degassing mast of the ship may be provided, controlled by a pressure relief valve.

- The enclosure is designed to reliably withstand the most extreme temperature conditions to which it may be subjected during operation.

- The enclosure is provided with a forced ventilation device by extraction, for example with a flow rate greater than 30 times its internal volume per hour.

- The enclosure may contain a vaporization unit connected to a pipe, including a drawing pipe, and configured to vaporize a flow of liquefied gas pumped into the tank to a gas consuming member.

- A gas compressor for conveying gas to the consumer member may be provided in the management device, preferably outside the sealed enclosure.

Brief description of the figures

Other characteristics, details and advantages of the invention will emerge more clearly from the detailed description given below as an indication in relation to drawings in which:

FIG. 1, already described, presents the general organization of the different equipment of a ship in which the invention can be implemented,

FIG. 2 is a diagrammatic cross-sectional view showing an area of the ship situated above the tank in a first embodiment of the invention,

- Figure 3 is a schematic cross-sectional view showing an area of the vessel located above the vessel in a second embodiment of the invention. - Figure 4 illustrates a vessel equipped with a gas storage tank and natural gas-fired power generation equipment for the propulsion of the ship.

FIG. 5 is a view similar to FIG. 2 in a variant of the first embodiment,

- Figure 6 is a view similar to Figure 3 in a variant of the second embodiment.

- Figure 7 is a schematic perspective view which shows an intermediate support wall surmounted by a sealed enclosure according to one embodiment.

Detailed description of embodiments

The invention takes advantage of the presence of at least a first bridge 11 or upper bridge and an intermediate carrier wall 12. A judicious use of the upper bridge 11 and the carrier wall 12 and mainly the space between them advantageously makes it possible to produce the required cofferdam.

The carrier wall 12 is preferably a steel wall provided with stiffeners 47 on the upper side facing the cofferdam. The presence of the stiffeners 47 on the top of the carrier wall 12 makes it possible to leave the lower surface substantially flat and free of obstacles in order to be coated with a multilayer structure forming the sealed and thermally insulating tank wall.

Similarly, the first bridge 11 may be provided with stiffeners

46 on the lower side facing the cofferdam. The presence of stiffeners 46 under the first bridge 11 allows to leave the upper surface substantially flat and free of obstacles for the movement or storage of goods.

Thus, as illustrated in FIGS. 2 and 3, a vessel 1 capable of containing liquefied natural gas is placed in a vessel 10. This vessel 1 is connected to a management device 7 by at least one filling pipe 2 and by at least one drawing pipe 3. Between the tank 1 and the management device 7 is arranged a connection device 5. This connection device 5 comprises, on each of the pipes 2, 3, an isolation valve 4. The device connection 5 is completed by an enclosure 6 enveloping said isolation valves 4 in a sealed manner.

The tank 1 is a diaphragm tank integrated in the shell 10. The walls of the tank, of which only the ceiling wall 50 is shown, comprise, successively from the outside to the inside of the tank, an insulation layer. secondary heat exchanger 41 anchored on an inner surface of the shell 10 or the intermediate carrier wall 12, a secondary waterproof membrane 42 anchored to the secondary thermal insulation layer 41, a primary thermal insulation layer 43 anchored to the secondary waterproof membrane 42 and a primary waterproof membrane 44 anchored on the primary thermal insulation layer 43. Thus, the vessel 1 is disposed below the intermediate carrier wall 12 and the connecting device 5 is disposed above the intermediate carrier wall 12 and at least partly under the first bridge 11.

Thus, according to the embodiment illustrated in FIG. 2, the connection device 5 is placed completely under the first bridge. Such a configuration corresponds to an arrangement where the management device 7 is below the first bridge 11, typically because the motor 14 is also below the first bridge 11.

According to a second alternative embodiment, illustrated in Figure 3, the connection device 5 is disposed in the first bridge 11, for example in a hopper 13 in the first bridge 11. Such a configuration allows to have the management device 7 at least partially above the first bridge 11.

As a result, the inter-bridge between the first bridge 11 and the intermediate carrier wall 12 constitutes a volume separating the vessel 1 from the management device 7 and advantageously sealed to form a cofferdam, as recommended by the "IGF Code" regulation. ".

This inter-deck space can thus advantageously be converted into cofferdam, by supplementing where appropriate as if necessary sealing, for example by means of watertight partitions. According to a preferred embodiment the cofferdam is made around the connection device 5, in order to secure said connection device 5.

According to an advantageous characteristic, facilitating the realization and integration of the tank system in a ship 10, each pipe 2, 3, between the end 25, 35 which plunges into the tank 1 and the end connected to the isolation valve 4, is decomposed into a primary pipe 21, 31 and a secondary pipe 22, 32. A primary pipe 21, 31 is terminated, at the end opposite the end 25, 35, by a primary assembly means 23, 33. Similarly, a secondary pipe 22, 32 is terminated, at the end opposite the end connected to the isolation valve 4, by a secondary assembly means 24, 34. Secondary assembly means 24, 34 is complementary in order to be able to be assembled with a primary assembly means 23, 33. For each of the pipes 2, 3, the primary assembly means 23, 33 is arranged so that it can be jointly arranged facing and substantially in contact with the means of assemb secondary 24, 34 corresponding counterpart.

An assembly means 23, 24, 33, 34 comprises any means for assembling two pipes, typically end-to-end. Thus an assembly means 23, 24, 33, 34 may be a flange or a sleeve that can be assembled in pairs, by screwing, by clamping, or by welding or any other means making it possible to connect two pipes 21, 22, 31, 32 for producing a pipe 2, 3.

This feature is particularly advantageous in that it allows to assemble the connection device 5 and its secondary pipes 22, 32 with the primary pipes 21, 31 from the vessel 1 and thus to make a modular assembly of the tank 1 with the connection device 5.

The assembly can be carried out according to the following method: the connecting device 5 is presented close to the tank 1 so that each secondary assembly means 24, 34 comes into view, and possibly in contact, with its means. primary assembly 23, 33 homologous. Then the assembly is performed for each pipe 2, 3 by screwing, clamping, or welding. During the assembly, the connection device 5 is thus advantageously placed, the secondary assembly means 24, 34 resting on the primary assembly means 23, 33 of the primary pipes 21, 31 and thus on the vessel 1. This facilitates the establishment of the connection device 5 and helps reduce the clearances between the assembly means 23, 24, 33, 34, thus ensuring an optimal fit, then frozen by the assembly.

Thus, in the assembled state, the connection device 5 is supported by the secondary pipes 22, 32.

Alternatively, the connection device 5 can be supported in different ways. For example, the connection device 5, and more particularly its enclosure 6, can be fixed to stiffeners 46 or 47 or to a wall 36 extending in the space between the first bridge 11 and the intermediate supporting wall 12 as outlined in FIG. The connection between the wall 36 and the enclosure 6 may comprise one or more fasteners 37, for example fastening lugs as sketched in phantom in FIG.

So that the pipes 2, 3, at the primary pipes 21, 31, can connect the inside of the tank 1 with the outside, the ceiling wall 50 of the tank 1 and the intermediate support wall 12 advantageously comprise a crossing 8 of wall. This crossing 8 allows a sealed passage of the primary pipes 21, 31. An embodiment of such a crossing is described in the French patent application No. 1653076 filed April 7, 2016, published under No. FR-A-3050009.

As indicated, the ceiling wall 50 of the tank 1 is directly carried by the lower surface of the intermediate carrier wall 12. The crossing 8 is thus also carried out through the intermediate bearing wall 12. According to a preferred embodiment, the crossing is made in a wall portion 18 which closes a corresponding hopper performed in the intermediate carrier wall 12. The wall portion 18 may advantageously be prefabricated and / or be integrated into the vessel 1 during its manufacture.

The wall portion 18 may be brought, particularly in case of leakage, to be in contact with the gas. Also the wall portion 18 is preferably made of a material resistant to liquefied natural gas and in particular at low temperatures that it can cause. According to a preferred embodiment, the wall portion 18 is made of stainless steel.

The wall penetration 8 is preferably made in a flat wall, as illustrated, which makes it possible to dispense with a more bulky structure such as the projecting liquid dome usually employed in a LNG tanker.

The primary function of the isolation valves 4 is to allow, in case of leakage in a pipe 2, 3, to close the circuit between the leak and the vessel 1. Also, the length of a pipe 2, 3 between the portion 18 and the isolation valve 4 is as short as possible, in terms of length of pipe.

If we now consider the configuration of Figure 3, everything is substantially identical, with the exception of the mounting characteristic of the connection device in the thickness of the first bridge 11. This assembly is effected for example by means of a hopper 13 pierced in the first bridge 11, substantially to the outer shape of the enclosure 6 of the connection device 5.

As in the previous configuration, priority is given to the assembly of the pipes 2, 3 by means of the primary assembly means 23, 33 and secondary 24, 34. This assembly is performed first to reproduce the advantages of quality and quality. previously described game reduction. This assembly precisely sets up the connection device 5 relative to the tank 1 and thus roughly in place the connection device 5 relative to the first bridge 11. Then a closure of the hopper 13 around the connection device 5 allows to realize the watertightness first bridge 11 and confirm the attachment of the connection device 5.

In view of the above considerations, a relatively large clearance is advantageously provided between the hopper 13 and the connection device 5. A support and fixing means 51 is advantageously used. This fastening means 51 comprises for example a peripheral frame fixed to the connection device 5 so as to come opposite and / or resting on the contour of the hopper 13. A sealing seal is then made between the fixing means 51 and the first bridge 11.

The position of the connection device 5 relative to the first bridge 11 having been imposed by the assembly of the primary pipes 21, 31 and secondary 22, 32, the fastening means 51 is advantageously able to allow a clearance clearance. This can be achieved by means of a deformable component, such as a bellows. This can still be achieved by welding, the fastening means 51 being shaped to accommodate a larger or smaller weld bead depending on the need.

According to a preferred embodiment and illustrated in FIGS. 2 and 3, said at least one filling pipe, generically designated 2, comprises a gas phase filling pipe 2G and a liquid phase filling pipe 2L. Similarly, said at least one draw pipe, generically referred to as 3, comprises a 3G gas-phase draw pipe and a liquid-phase draw pipe 3L. A 2G, 3G gas phase pipeline advantageously opens at the top of the vessel 1. A liquid phase conduit 2L, 3L advantageously opens at the bottom of the vessel 1.

It has been seen that an enclosure 6 confines the isolation valves 4. Its role is to contain the gas in the event of a leak in the isolation valves 4. Also, this enclosure 6 is preferably made of a material resistant to liquefied natural gas, such as for example stainless steel.

It must be possible to access the valves isolation 4, whether for their operation or for any control or maintenance operation. Also the enclosure 6 advantageously comprises a trap door.

In an embodiment not shown, a bottom wall of the enclosure 6 is constituted by a portion of the intermediate support wall 12.

In an embodiment shown in FIG. 7, a bottom wall of the enclosure 6 is constituted by the wall portion 18. The stiffeners 47 are here formed of mutually perpendicular walls arranged so as to form a substantially square mesh grid. protruding on the intermediate wall 12. These stiffeners 47 are interrupted at the wall portion 18 traversed by the pipes 2, 3, which here has a rectangular shape. The enclosure 6 here has the shape of a rectangular parallelepiped whose length and width are substantially equal to the length and width of the wall portion 18, so that the wall portion 18 forms the bottom wall of the parallelepiped enclosure . The wall portion 18 may be traversed by a greater or smaller number of pipes.

FIGS. 5 and 6 illustrate two embodiments in which the intermediate bearing wall 12 does not have a planar shape but instead has a recessed portion 16, which is offset downwards with respect to the remainder of the intermediate support wall 12 Elements similar or identical to those of Figures 2 and 3 bear the same reference numeral as in Figures 2 and 3.

The wall penetration 8 is made in the recessed portion 16, for example in the form of a wall portion 18. The connection device 5 is disposed in line with the recessed portion 16 so as to be housed in a zone 17 where the height of the space between the first bridge 11 and the intermediate bearing wall 12 is higher than elsewhere. The zone 17 is delimited by connecting portions 15 of the intermediate support wall 12, which extend on either side of the recessed portion 16, or perpendicular to the recessed portion 16. ci as illustrated, either obliquely.

The connection device 5 can be fixed in different ways as described above. FIG. 5 illustrates a connection device 5 resting directly on the intermediate carrier wall 12, at the right of the recessed portion 16. FIG. 6 illustrates fasteners, for example welded, which support the connection device 5 above of the intermediate bearing wall 12, at the right of the recessed portion 16.

In a manner known per se, as shown in FIG.

4, loading / unloading lines may be connected, by means of appropriate connectors, to a marine or port terminal to transfer a cargo of LNG to or from vessel 1.

FIG. 4 shows an example of a marine terminal comprising a liquefied natural gas supply station 82, an underwater pipe 83 and an onshore installation 81. The liquefied natural gas supply station 82 is a fixed installation providing shore comprising a movable arm 84 and a tower 85 which supports the movable arm 84. The movable arm 84 carries insulated flexible pipes 80 that can connect to the loading pipes. The swiveling arm 84 adapts to all ship sizes. A link pipe (not shown) extends inside the tower 85. The liquefied natural gas supply station 82 allows the tank 10 of the vessel to be filled from the shore installation 81. liquefied gas storage tanks 86 and connecting pipes 87 connected by the underwater pipe 83 to the liquefied natural gas supply station 82. The underwater pipe 83 allows the transfer of the liquefied gas between the supply station in liquefied natural gas 82 and onshore installation 81.

In order to generate the pressure necessary for the transfer of the liquefied gas, pumps on board the ship 10 and / or pumps equipping the shore installation 81 and / or pumps equipping the loading and unloading station are used. 82.

To load the tank of the ship 10, the marine or port terminal can also be replaced by a supply vessel equipped with an LNG storage tank.

Although the invention has been described in connection with several particular embodiments, it is obvious that it is not limited thereto and that it comprises all the technical equivalents of the means described and their combinations if they are within the scope of the invention.

The use of the verb "to include", "to understand" or "to include" and its conjugate forms does not exclude the presence of other elements or steps other than those set out in a claim.

In the claims, any reference sign in parentheses can not be interpreted as a limitation of the claim.

Claims

Floating structure comprising a shell (10), at least a first bridge (11) and an intermediate support wall (12) disposed below the first bridge (11), the floating structure comprising a vessel (1) adapted to contain a liquefied fuel gas disposed below the intermediate carrier wall (12), at least one pipe (2, 3) connecting the tank (1) to a management device (7) and a connection device (5) comprising at least one at least one isolation valve (4) disposed on said at least one pipe (2, 3) and an enclosure (6) enclosing said at least one isolation valve (4) in a sealed manner, wherein the vessel (1) is a diaphragm tank integrated in said shell (10), the walls of the tank comprising, successively from the outside to the inside of the tank, at least one layer of thermal insulation carried by an inner surface of said shell and by a lower surface of the intermediate carrier wall (12) and at least one waterproof membrane disposed on an inner surface of said thermal insulation layer, wherein the connecting device (5) is disposed above the intermediate carrier wall (12) and at least partly under the first bridge (11) and wherein a space between the first bridge (11) and the intermediate bearing wall (12) containing all or part of the connecting device (5) is arranged in cofferdam.

2. Floating structure according to claim 1, wherein the connecting device (5) is supported above the intermediate bearing wall (12) by said at least one pipe (2, 3).

3. Floating structure according to claim 1, wherein the connecting device (5) is supported by the intermediate bearing wall (12).

Floating structure according to claim 2, wherein a bottom wall of the enclosure (6) is constituted by a portion (18) of the intermediate carrier wall (12).

Floating structure according to any one of claims 1 to 4, wherein said at least one pipe (2, 3) comprises a primary pipe (21, 31), one end (25, 35) of which is immersed in the tank ( 1) and a secondary pipe (22, 32) having one end connected to said isolation valve (4), the other end of the primary pipe being joined to the other end of the secondary pipe.

6. Floating structure according to claim 5, wherein the assembly of the primary pipe to the secondary pipe is formed by an assembly means (23, 24, 33, 34) comprising a flange or a sleeve.

The floating structure according to any one of claims 1 to 6, wherein a ceiling wall (50) of the vessel (1) and the intermediate support wall (12) comprise a wall penetration (8) through which said at least one pipe (2, 3) passes sealingly.

8. Floating structure according to claim 7, wherein the wall penetration (8) is formed in a portion (18) of the intermediate bearing wall (12) made of stainless steel.

9. Floating structure according to any one of claims 1 to 8, wherein metal stiffeners (47) are attached to an upper surface of the intermediate support wall (12) opposite the wall of the tank.

10. Floating structure according to any one of claims 1 to 9, wherein the connecting device (5) is disposed in a hopper (13) formed in the first bridge (11) and comprises, facing the hopper (13). ), a fastening means (51) sealed to the periphery of the hopper (13).

11. Floating structure according to claim 10, wherein the fixing means (51) is adapted to allow a clearance clearance between the enclosure (6) and the edge of the hopper (13).

12. Floating structure according to any one of claims 1 to 11, wherein the intermediate bearing wall (12) comprises a recessed portion (16) offset downwardly relative to a remaining portion of the intermediate bearing wall (12). and wherein the connecting device (5) is disposed in line with said recessed portion (16).

13. Floating structure according to any one of claims 1 to 12, wherein said at least one pipe comprises a gas phase filling pipe (2G), a liquid phase filling pipe (2L), a drawing pipe in gas phase (3G) and a liquid phase drawing pipe (3L), in which one or each gas phase pipe (2G, 3G) opens at the top of the tank (1) and one or each pipe in the liquid phase ( 2L, 3L) opens at the bottom of the tank (1).

14. Floating structure according to any one of claims 1 to 13, wherein the enclosure (6) is a material resistant to liquefied natural gas, preferably stainless steel.

15. Floating structure according to any one of claims 1 to 14, wherein the enclosure (6) comprises a manhole.

16. Transfer system for a fluid, the system comprising a floating structure according to any one of claims 1 to 15, insulated pipes (80) arranged to connect the vessel (1) of the floating structure to an installation floating or ground storage (81) and a pump for driving a flow of fluid through the isolated pipes from the floating or ground storage facility to the tank (1) of the floating structure.

17. A method of filling the vessel of a floating structure according to any one of claims 1 to 15, wherein a fluid is conveyed through isolated pipes (80) from a floating or land storage facility (81) to the tank (1) of the floating structure.