OA16429A - Fluid operating tower in a body of water and associated installation method. - Google Patents

Abstract

This tower comprises a pipe (24) for transporting fluid and an element (29) for anchoring the transport pipe (24) in the bottom (14) of the body of water (12), connected to a point upstream (38) of an intermediate section (30) of the pipe. The tower comprises a buoy (26) connected to a downstream point (40) of the intermediate section to maintain the intermediate section (40) in a substantially vertical configuration. The buoy (26) has a height less than 1.5 times its maximum transverse dimension, and delimits a first through passage (78A) in which the intermediate section (30) is engaged. The buoy (26) delimits a second through passage (78B), distinct from the first through passage (78A), the second through passage (78B) receiving the upper section (34). The tower (20) comprises a connecting section (32) connecting the upper connecting section (34) to the intermediate section (30).

Description

Fluid operating tower in a body of water and associated installation method

The present invention relates to a tower for operating fluid through a body of water, of the type comprising:

- a fluid transport pipe, intended to be submerged in the body of water, the transport pipe comprising a lower section intended to be connected to a bottom assembly producing fluid, an upper flexible section intended to be connected to a surface assembly and an intermediate section placed between the upper flexible section and the lower section;

- an anchoring element of the transport pipe in the bottom of the body of water, connected to an upstream point of the intermediate section;

- a buoy intended to be completely submerged under the surface of the body of water, the buoy being connected to a downstream point of the intermediate section to maintain the intermediate section located between the downstream point and the upstream point in a substantially vertical configuration under tension, the buoy having a height, taken along a vertical axis, less than 1.5 times its maximum transverse dimension, the buoy delimiting a first crossing passage in which the intermediate section is engaged.

Such towers are intended to transport a fluid produced from the bottom of a body of water to the surface, through the body of water. This fluid consists in particular of liquid and / or gaseous hydrocarbons and water collected in production wells located at the bottom of the body of water.

Such a tower generally comprises a lower pipe connecting the production assembly arranged on the bottom of the body of water, a substantially vertical riser, a buoy for keeping the riser under tension in its vertical position, and an anchoring element of a lower point of the riser.

The tower further includes an upper flexible connecting pipe connecting the riser to a floating surface assembly.

Thus, the hydrocarbons produced by the bottom assembly are transported successively through the lower connecting pipe, the riser and the upper connecting pipe to a surface assembly such as a ship, a platform or a barge, where they can be collected or transported.

This type of tower has a relatively simple structure, since its maintenance in vertical position is ensured exclusively by the anchoring element in the bottom of the body of water, and by the tension generated by the buoyancy of the maintenance buoy connected to the upper point of the riser (jl

A tower of the aforementioned type is for example described in GB 2 024 766.

However, such towers remain difficult to install, in particular due to the depth of the body of water, as well as movements on the surface of the body of water due to swell and / or wind.

Further, the deployment of the riser and the upper flexible pipe, and their connection to the buoy, are difficult to achieve.

In particular, the upper flexible pipe is generally connected to the riser via a swan neck-shaped connection section. This connection is made in the body of water after installation and submersion of the buoy, which makes connection operations very complex.

An object of the invention is therefore to obtain a tower for transporting fluid through a body of water, of simple structure, easy to install, especially at great depths, or when the body of water is agitated.

To this end, the invention relates to a tower of the aforementioned type, characterized in that the buoy delimits a second through passage, distinct from the first through passage, the second through passage receiving the upper section, the tower comprising a connecting section connecting the upper section to the intermediate section.

The tower according to the invention can comprise one or more of the following characteristics, taken in isolation or according to any technically possible combination (s):

- Each through passage delimits a lower opening and an upper opening, the intermediate section being engaged in the first crossing passage from the lower opening towards the upper opening, the upper section being engaged through the crossing passage from the lower opening towards the upper opening, the connecting section being located above the buoy;

- The buoy has an upper surface carrying the connecting section, the connecting section being advantageously formed by a rigid pipe;

- the connecting section has a first means for fixing the intermediate section opening opposite an upper opening of the first through passage, the connecting section having a second means for fixing the upper section opening opposite an upper opening of the second crossing passage;

- the first through passage extends substantially vertically through the buoy, the second through passage extending substantially vertically through the buoy

- the first through passage extends substantially vertically through the buoy, the second through passage extending at an angle to the first through passage;

- The intermediate section is formed by a flexible pipe, the flexible pipe being able to be wound up and unwound in a reversible manner without significant plastic deformation on a drum or on a basket;

- the buoy has a first guide tube delimiting the first through passage and a second guide tube delimiting the second through passage, at least one of the first guide tube and of the second guide tube being an I-tube or a tube in J; and

- at least one of the intermediate section and the upper section is provided with at least one guide member projecting radially from said section to guide the movement of said section through a respective through passage.

The subject of the invention is also a method for mounting a fluid operating tower through a body of water, of the type comprising the following steps:

- bringing a buoy into the body of water, substantially opposite an anchoring region on the bottom of the body of water;

- connection to the buoy of a point downstream of an intermediate section of a fluid transport pipe;

- connection to the buoy at an upstream end of an upper flexible section of the fluid transport pipe, intended to be connected to a surface assembly;

- Total immersion of the buoy under the surface of the body of water, before or after the downstream point connection step;

- anchoring of an upstream point of the intermediate section on an anchoring element fixed in the bottom of the body of water in the anchoring region;

- tensioning of the intermediate section of the transport pipe between the downstream point and the upstream point under the effect of the buoyancy of the buoy, to keep the intermediate section substantially vertical in the body of water;

- connection to the intermediate section of a lower section of the fluid transport pipe intended to be connected to a bottom assembly and producing fluid;

- connection of the intermediate section and the upper section by a connecting section, the buoy having a height, taken along a vertical axis, less than 1.5 times its maximum transverse dimension taken transversely to the vertical axis, the step of, "

connection of the intermediate section comprising the engagement of the intermediate section through a first through passage formed through the buoy;

characterized in that the upper section is engaged through a second through passage distinct from the first through passage to be connected to the intermediate section via the connecting section.

The method according to the invention may include one or more of the following characteristics, taken in isolation in any technically possible combination (s):

- the step of connecting the intermediate section and the upper section through the connecting section is carried out before the step of immersing the buoy under the body of water;

- the first through passage and the second through passage each delimit a lower opening and an upper opening, the intermediate section being engaged in the first crossing passage from the lower opening to the upper opening, the upper section being engaged in the second passage traversing from the lower opening to the upper opening;

- the intermediate section is flexible over substantially its entire length between the downstream point and the upstream point, the intermediate section being gradually deployed in the body of water between the downstream point fixed on the buoy and a laying structure floating on the expanse of water during the deployment step, the intermediate section being unwound from the laying structure on which it is transported by being wound on a laying drum or on a basket; and

- The method comprises a step of progressive ballasting of the buoy, after the steps of connecting the intermediate section and the upper section on the connecting section to descend the upstream point towards the anchoring element, the method advantageously comprising the traction of the upstream point towards the anchoring element via a traction line engaged on a return member carried by the anchoring element.

The invention will be better understood on reading the following description, given solely by way of example, and made with reference to the accompanying drawings, in which:

- Figure 1 is a schematic side view, in partial section, of a first fluid exploitation tower according to the invention arranged in a body of water;

- Figure 2 is a view similar to Figure 1, during a first step of the assembly process of the Figure 1 tower

- Figure 3 is a view similar to Figure 2 of a second step of the method of mounting the tower of Figure 1.

- Figure 4 is a view similar to Figure 2 of a third step of the assembly process of Figure 1;

- Figure 5 is a view similar to Figure 2 of a fourth step of the assembly process; and

- Figure 6 is a view similar to Figure 1 of a second fluid operating tower according to the invention.

In what follows, the terms "upstream" and "downstream" are understood in relation to the normal direction of flow of a fluid in a pipe.

A first installation 10 for operating fluid in a body of water 12, installed by an installation method according to the invention, is shown schematically in Figure 1.

This installation is intended to convey a fluid collected in the bottom 14 of the body of water 12 to the surface 16 of the body of water.

The fluid collected is for example a gaseous or liquid hydrocarbon from a well (not shown) provided in the bottom 14 of the body of water.

Body of water 12 is a lake, sea, or ocean. The depth of the body of water 12, taken between the surface 16 and the bottom 14 facing the installation 10 is greater than 30 m and is for example between 30 m and 3,500 m.

The installation 10 comprises an assembly 18 for producing fluid, located on the bottom of the body of water, designated in the following by the term “bottom assembly”, a first tower 20 according to the invention, and a surface assembly 22, intended to recover and store the fluid collected in the production assembly 18 conveyed through the tower 20.

The bottom assembly 18 includes for example at least one wellhead and / or a production line (not shown) located on the bottom 14 of the body of water.

The surface assembly 22 is in this example a floating assembly. It is for example formed by a ship, a barge, a floating platform, or a floating unit for the recovery, storage and treatment of hydrocarbons, referred to by the acronym "FPSO". The surface assembly is alternatively a floating storage and regasification unit referred to by the acronym "FSRU".

The surface assembly 22 floats on the body of water in the vicinity of the bottom assembly 18.

The tower 20 according to the invention comprises a pipe 24 for transporting fluid connecting the bottom assembly 18 to the surface assembly 22, an anchoring element 25 of the pipe 24, fixed in an anchoring region on the bottom 14, and a buoy 26 for maintaining under tension at least one intermediate section of the transport pipe 24 in a substantially vertical configuration in the body of water 12.

The transport pipe 24 comprises, from bottom to top in Figure 1, a lower section 28 for connection to the bottom assembly 18, an intermediate section formed by a substantially vertical riser 30, a connecting section 32 and a section upper connection 34 to the surface assembly 22,

In this example, the transport pipe 24 is flexible over substantially its entire length, taken between the bottom assembly 18 and the surface assembly 22, possibly excepting the connection section 32.

The lower section 28 is formed for example by a lower connecting hose 36 extending in an elbow or inclined manner relative to the bottom 14 of the body of water 12. The lower hose 36 is connected upstream to the assembly of bottom 18, and is connected downstream to the riser 30.

The riser 30 extends substantially vertically along a vertical axis A-A 'in the body of water 12, between a lower upstream point 38, connected to the anchoring element 25 and an upper downstream point 40, connected to buoy 26.

In this example, the riser 30 is formed by a flexible pipe 41 over substantially its entire length.

For the purposes of the present invention, the term “flexible” or “flexible pipe” means a pipe as described in the normative documents published by the American Petroleum Institute (API), API 17J and API RP17B, well known to man. of career. This definition encompasses indifferently flexible pipes of the unbounded type, or linked ("bounded" in English).

More generally and as a variant, the flexible pipe 41 may be a composite bundle of the “bundle” type comprising at least one fluid transport tube and a set of electrical or optical cables suitable for transporting electrical or hydraulic power, or information between. the bottom 14 and the surface 16 of the body of water

An example of a flexible pipe is described in French application FR 2 911

907.

A flexible pipe has a relatively small minimum bending radius ("MBR") without damage, for example a few meters, which makes it particularly suitable for being rolled up and unwound in a reversible manner without deformation. significant plastic on a drum or basket, the drum or basket being carried by a laying vessel, as will be seen below / To »

The length of the riser 30, taken between the upper point 40 and the lower point 38 is greater than 20 m and is for example between 500 m and 3500 m.

The downstream point 40 of the riser 30 is advantageously provided with connection means on the connection section 32. These means are for example formed by a connection flange intended to be fixed on a corresponding flange of the section.

32.

The riser 30 is provided, in the vicinity of the downstream point 40, with a first guide member 42A of the upstream point in the buoy 26 and advantageously with a first stiffener 42B intended to prevent excessive twists of the riser 30 during of its engagement through buoy 26.

The guide member 42A is mounted around the riser 30. It is formed for example by at least one vertebra fixed around the flexible pipe 41 forming the riser 30.

The stiffener 42B is releasably fixed around the flexible pipe 41 forming the riser 30. As will be seen below, it is suitable for engaging on the buoy 26 and for allowing the flexible pipe to slide through the tube. stiffener 42B.

In this example, the connecting section 32 is formed by a rigid pipe section. As will be seen below, this section 32 is carried by the buoy 26. It has the general shape of an upturned U or omega. It thus has an upstream end 44A provided with an upstream means of connection to the riser 30, in particular an upstream connection flange and a downstream end 44B provided with a downstream means of connection to the upper section 34, in particular a flange downstream connection. The ends 44A, 44B are arranged opposite the buoy 26.

As a variant, the connecting section 32 is formed by a flexible pipe as described above, provided for example with curvature limiters or buoyancy elements.

In all cases, the connecting section 32 is completely submerged in the body of water 12 under the surface 16, once the tower 20 is in place.

The upper section 34 is formed by an upper hose 50 extending between the fitting 32 and the surface assembly 22.

The upper hose 50 has a catenary configuration, substantially J-shaped.

The upper flexible 50 is deformable to absorb the movements of the surface assembly 22 due to disturbances of the body of water such as swell, current or wind. The section 34 thus substantially prevents the transmission of these

movements from the surface assembly 22 to the riser 30, the downstream point 40 of which remains substantially stationary in the body of water.

The upper section 34 extends between an upstream end 51A attached to the downstream end 44B of the connection section 32 and a downstream end 51B integral with the surface assembly 22.

At its upstream end 51A, the upper section 34 carries connection means on the intermediate section 32 formed for example by a connecting flange.

In the vicinity of the upstream end 51A, the upper section 34 is provided with a second guide member 52A and a second stiffener 52B which are of structures similar respectively to the structure of the first guide member 42A and to that of the first stiffener 42B.

When they are connected together, the lower section 28, the riser 30, the connecting section 32, and the upper section 34 internally define a continuous passage 54 for the circulation of fluid extending between the bottom assembly 18 and the surface assembly 22 to allow transport of the fluid between these assemblies 18,

22.

In this example, the anchoring element 25 comprises an anchoring member 60 fixed in the anchoring region on the bottom 14 of the body of water 12 and a flexible line 62 connecting the anchoring member 60 at the upstream point 38 of the riser.

The anchoring member 60 is for example formed by a stack housed in the bottom 14 of the body of water or by a suction anchor.

The flexible line 62 extends vertically along the axis A-A 'between the anchor element 60 and the upstream point 38.

At least during the assembly of the tower 20, the anchoring element 25 is advantageously provided with a return member 64 of a flexible traction line. The return member 64 is for example formed by a pulley rotatably mounted on the anchor member 60.

According to the invention, the buoy 26 is of substantially flat shape when the tower 20 is mounted in the body of water 12.

In this example, the buoy 26 thus has a substantially horizontal lower surface 66A, a substantially horizontal upper surface 66B and a peripheral surface 66C connecting the surfaces 66A, 66B to one another.

The buoy 26 has in particular a height H, taken along the axis A-A ', less than 1.5 times its maximum transverse dimension D, taken perpendicular to the axis A-A' between the surfaces 66A, 66B. (^ T t

As illustrated in Figure 2, the buoy 26 is advantageously cylindrical in shape with axis A-A ’. The height H of the buoy is advantageously less than 1.5 times, in particular less than or equal to 1 times the maximum transverse dimension of the buoy, which is in this example the diameter D of the cylinder.

The buoy 26 comprises a buoyancy box 70 internally delimiting at least one sealed compartment 72 able to be selectively filled with gas or liquid, and means 74 for selective filling of liquid and gas in the compartment 72.

The buoy 26 further comprises, in this example, means 76 for fixing the connecting section 32 to fix the section 32 on the upper surface 66B.

In the example shown in Figures 1 and 2, the buoyancy box 70 of the buoy defines a first through passage 78A in which is engaged the riser 30 and a second through passage 78B in which is engaged the upper hose 50.

Each passage 78A, 78B, opens upwards into the upper surface 66B via a respective upper opening 80A, 80B.

Each passage 78A, 78B opens downwards through a respective lower opening 82A, 82B, situated at the level of the lower surface 66A, or below the latter.

The passages 82A, Θ2Β thus pass through the box 70 of the buoy 26 over the entire height of the buoy 26, taken between the lower surface 66A and the upper surface 66B.

The upper opening 80A of the first passage 78A opens up opposite the upstream end 44A of the connecting section 32. The upper opening 80B of the second passage 78B opens up against the downstream end 44B of the connecting section 32.

In this example, the first passage 78A extends vertically, along the axis AA 'of the riser 30, parallel to the axis of the buoy 26. The second passage 78B extends in this example along an axis B-B 'inclined relative to the axis AA' of the first passage 78A by an angle a for example between 30 ° and 65 °.

In the example shown in Figure 1, the first passage 78A and the second passage 78B are formed respectively in guide tubes 83A, 83B mounted in the box 70.

Each tube 83A, 83B has an upper part 84A, 84B of substantially constant section, in particular complementary to the section of the respective guide member 42A, 52A and a flared lower part 85A, 85B intended to receive the respective stiffener 42B, 52B.

t

In this example, the lower portion 85A, 85B protrudes under the buoy 26 away from the lower surface 66A.

The tubes 83A, 83B are commonly referred to as “I tubes” or “I Tubes” in English.

Each compartment 72 extends into the box 70 around the passages 7ΘΑ, 78B. The filling means 74 are adapted to selectively introduce gas or liquid into the or each compartment 72 in order to selectively increase or decrease the buoyancy of the buoy 26.

In the example shown in Figure 1, the upper part of the riser 30 is engaged in the first passage 78A from bottom to top. Thus, the first stiffener 42B is received in the lower flared part 85A of the tube 83A and the first guide member 42A is received in the upper part Θ4Α of the tube 83A.

The downstream point 40 protrudes beyond the upper surface 66B out of the first passage 78A to be connected to the upstream end 44A.

Likewise, the upstream part of the hose 50 is engaged from bottom to top in the second passage 78B. For this purpose, the second stiffener 52B is received in the flared lower part 85B of the tube 83B. The second guide member 52A is received in a complementary manner in the upper part 84B of the tube 83B. The upstream end 51A of the hose 50 protrudes beyond the upper surface 66B out of the second passage 7ΘΒ to be connected to the downstream end 44B of the connecting section 32.

Thus, the riser 30 passes through the buoy 26 from bottom to top between the lower opening 82A and the upper opening 80A of the first passage 78A and the hose 50 passes through the buoy 26 from the bottom up between the lower opening 82B and the 'upper opening 80B of the second passage 78B.

The riser 30 has a substantially vertical configuration along the A-A 'axis. The connecting section 32 has a U-shaped configuration directed downwards. The upper section 34 has a chain or U-shaped configuration directed upwards.

A first method of setting up the installation 10 according to the invention will now be described, with reference to Figures 2 to 5.

This method is implemented using a vessel 90 for laying the transport pipe 24, and using at least one vessel 92A, 92B for towing the buoy 26, separate from the laying vessel. 90. In the example shown in Figure 2, the method is implemented using two towing vessels 92A, 92B

"

Initially, the pipe elements 36, 42 intended to form the transport pipe 24 are brought into the vicinity of the bottom assembly 18 with the aid of the laying vessel 90 and the pipe member 50 is brought over the assembly. surface 22.

To this end, the lower flexible 36 and the flexible pipe 41 are transported by the laying vessel 90, for example being wound on a laying drum or in a basket.

The anchoring element 25 is installed in the bottom 16 of the body of water 12 in the vicinity of the bottom assembly 18. For this purpose, the anchoring member 60 is fixed in the bottom 14 of the body of water 12.

According to the invention, the buoy 26 is towed while being partially submerged, with its upper surface 66B located outside the body of water 12 and its lower surface 66A submerged, between a position remote from the anchoring element 25 and an installation position located substantially opposite and above the anchoring element 25.

During this transport, the buoy 26 extends substantially horizontally with its axis A-A 'vertical.

The buoy 26 having a substantially flat shape, it is very insensitive to the movements of the surface 16 of the body of water 12, and in particular to swells, currents or winds, so that it can be transported from safely by being only partially submerged in the body of water 12, using the towing vessels 92A, 92B. It is also a workstation thanks to its large flat top surface 66B.

The towing distance of the buoy 26, which horizontally separates the remote position from the positioning position is greater than several hundred meters, or even several hundred kilometers.

Alternatively, buoy 26 is loaded onto a partially submersible barge, then submerged in water by submerging the barge, before being towed.

Then, when the buoy 26 occupies its set-up position shown in Figure 2, it is held in a horizontal position by the towing vessels 92A, 92B with the aid of deployable mooring lines 94.

A traction device 96 is then mounted on the buoy 26, for example on its upper surface 66B. This traction device 96 comprises, for example, a winch 96 provided with a deployable traction line 98.

With reference to Figure 3, the distance separating the laying vessel 90 from the buoy being relatively high, for example greater than 50 m, the radius of curvature of the "

flexible pipe 41 in this configuration is raised to prevent damage to the flexible pipe 41.

In addition, the weight of the flexible pipe 41 being distributed between the laying vessel 90 and the buoy 26, it is not necessary to provide the buoy 26, nor the laying vessel 90 with a winch 96 of large capacity.

The pulling of the line 98 towards the winch 96 continues until the downstream point 40, the first guide member 40A and the first stiffener 42B are successively introduced into the first passage 78A from bottom to top.

The stiffener 42B is then wedged in the lower part 85A of the tube 83A.

Then, the stiffener 42B is released from the flexible pipe 30. The rise of the downstream point 40 continues by sliding the flexible pipe 30 in the stiffener 42B.

The guide member 42A and the downstream point 40 therefore go up along the first passage 78A from the lower opening 82A to the upper opening 80A of the first passage, before the downstream point 40 is extracted from the first passage 78A through the top opening 80A.

The downstream point 40 is then fixed to the upstream end of the connection section 32, either by screwing and / or bolting the flanges together, or by arranging a clamp around the flanges.

The traction line 98 is then disconnected from the downstream point 40. The winch 96 is then moved to the vicinity of the upper opening 80B of the second passage 78B. Alternatively, another winch 96 is present in the vicinity of the second passage 78B.

Then, as shown in Figure 4, the line 98 is engaged through the second passage 78B and then is attached to the upstream end 51A of the upper hose 50.

Winch 96 is then activated to move the downstream end 51A closer to buoy 26, retracting an increasing length of line 98 onto winch 96. Simultaneously, an increasing length of upper hose 50 is deployed out of the surface assembly. 22. The flexible 50 adopts a substantially catenary or U-shaped shape between the surface assembly 22 and the buoy 26.

As previously described, the pull of line 98 continues until the upstream end 51A, the second guide member 52A and the second stiffener 52B enter the second passage 78B through the lower opening 82B.

When the stiffener 52B is wedged in the lower part 85B of the tube Θ3Β, the upper hose 50 is released relative to the stiffener 52B to slide through the stiffener 52B. The end 51A and the guide member 52A go up through the second passage 78B / vl

This movement continues until the downstream end 51A is extracted out of the second passage 78B through the upper opening 80B to be connected to the downstream end 44B of the connecting section 32.

The ends 44B, 51A are then fixed one on the other, for example by screwing and / or bolting the flanges together, or by fitting a clamp.

The tightness of the passage 54 between the upper section 34 and the connection section 32 on the one hand, and between the connection section 32 and the intermediate section 30, on the other hand, is then checked.

It should be noted that the connection of the flexible 50 to the section 32 is effected directly on the buoy 26, taking advantage of the work surface offered by the upper surface 66B of the buoy 26.

Given its dimensions, the buoy 26 is also extremely stable, which makes the operations carried out on the buoy 26 very safe.

All the connection steps being carried out above the surface 16 of the body of water 12 at the surface, the assembly of the tower 20 is therefore very simple to implement. In addition, the tightness of the connection can be tested on the surface, before submersion of the buoy 26, which does not require raising the buoy 26 when the seal is not adequate.

The traction line 98 is then disconnected from the downstream end 51A and the winch 96 is advantageously dismantled away from the buoy 26.

Then, the upstream point 38 is fixed on the anchoring element 25, for example by a method of the type described in the patent application WO 2009/118467 of the Applicant.

To this end, the upstream point 38 is lowered into the body of water 12 until the intermediate section 30 occupies a substantially vertical configuration.

Then, as illustrated in Figure 4, the upstream point 38 is connected to a traction line 100 deployed from the laying vessel 90. The traction line 100 is engaged around the return member 64. It thus has a first vertical section 102 extending between the upstream point 38 and the return element 64 and a second inclined section 104 extending between the return element 64 and the laying vessel 90.

Then, the mooring lines 94 are released and the filling means 74 are activated to introduce liquid into the compartments 72 in order to decrease the buoyancy of the buoy 26.

Simultaneously, the traction line 100 is retracted into the laying vessel 90 to pull the downstream point 38 towards the anchor member 60 and thus guide the positioning of the riser 30 towards the anchor element 25Λ1 *

The buoy 26 is then lowered and completely submerged in the body of water 12 to a depth greater than several tens of meters, in a region of the body of water 12 which is not affected by the swell and waves. The buoy 26 maintains its horizontal orientation during the descent, with its axis A-A 'substantially vertical along its height.

When the upstream point 38 is located in the vicinity of the anchoring element 60, the flexible anchoring line 62 is then attached to the upstream point 38 and to the anchoring element 60. Then, the lower flexible 36 is lowered from the laying vessel 90 to be connected on the one hand to the upstream point 38, and on the other hand to the bottom assembly 18.

Then, the buoyancy of the buoy 26 is optionally modified to apply between the downstream point 40 and the upstream point 38, through the buoy 26, a tensile force directed upwards, this force being compensated by the force of retained by the anchor line 62. The riser 30 then extends vertically along the axis A-A 'between its upstream point 38 and its downstream point 40.

In this configuration, the continuous passage 54 for the circulation of hydrocarbons between the bottom assembly 18 and the surface assembly 22 is established successively through the lower section 28, the riser 30, the connecting section 32 and the section upper 34. The fluid collected by the bottom assembly 18 is then transported to the surface assembly 22 through the passage 52.

A second installation 120 according to the invention is shown in Figure 6. Unlike the tower 20 of the first installation 10, the tower 20 of the second installation 120 comprises a buoy 26 which has a second passage 78B substantially vertical through it. the buoy 26.

Thus, the second passage 78 is advantageously delimited by a tube 83A in the form of a J or “J tube” in English.

The tube 83B thus comprises an upper part 84B substantially parallel to the axis A-A 'of the first passage 78A and a lower part 85B with an axis inclined relative to the upper part 84B, in particular at an angle a of between 30 ° and 65 °.

The lower inclined portion 85B protrudes downward from the lower surface 66A of the buoy 26.

Tower 20 of second installation 120 is otherwise identical to tower 20 of first installation 10.

The method of setting up tower 20 shown in Figure 6 is analogous to the method of setting up tower 20 shown in Figure 1.

In one variant, the intermediate section 30 is devoid of stiffener 42B and of guide member 42A, and the upper section 34 is devoid of stiffener 52B and of guide member 52A.

In another variant, during the installation of the tower 20, the buoy 26 is immersed in the body of water 12 while maintaining the U-shaped configuration of the intermediate section 30, between the laying vessel 90 and the buoy. 26.

Then, the downstream point 38 is moved under the buoy 26 via a deployment line (not shown), after submersion of the buoy. "AT

Claims (14)

1.- Tower (10) for operating fluid through a body of water (12), of the type comprising; - a pipe (24) for transporting fluid, intended to be immersed in the body of water (12), the transport pipe (24) comprising a lower section (28) intended to be connected to a bottom assembly ( 18) producing fluid, an upper flexible section (34) to be connected to a surface assembly (22) and an intermediate section (30) placed between the upper flexible section (34) and the lower section (28); - an element (25) for anchoring the transport pipe (24) in the bottom (14) of the body of water (12), connected to an upstream point (38) of the intermediate section (30); - a buoy (26) intended to be completely submerged under the surface of the body of water (12), the buoy (26) being connected to a downstream point (40) of the intermediate section to maintain the intermediate section (40) located between the downstream point (40) and the upstream point (38) in a substantially vertical configuration under tension, the buoy (26) having a height, taken along a vertical axis (A-A '), less than 1.5 times its maximum transverse dimension, the buoy (26) delimiting a first through passage (78A) in which the intermediate section (30) is engaged, characterized in that the buoy (26) delimits a second through passage (78B), distinct from the first through passage (78A), the second through passage (78B) receiving the upper section (34), the tower (20) comprising a connecting section (32) connecting the upper section (34) to the intermediate section (30). 2. - Tower (20) according to claim 1, characterized in that each through passage (78A, 78B) defines a lower opening (82A, 82B) and an upper opening (80A, 80B), the intermediate section (30) being engaged in the first through passage (78A) from the lower opening (82A) to the upper opening (80A), the upper section (34) being engaged through the through passage (78B) from the lower opening (82B) towards the upper opening (80B), the connecting section (32) being located above the buoy (26). 3. - Tower (20) according to any one of the preceding claims, characterized in that the buoy has an upper surface (66B) carrying the connecting section (32), the connecting section (32) being advantageously formed by a rigid driving. 4. - Tower (30) according to any one of the preceding claims, characterized in that the connecting section (32) has a first means for fixing the intermediate section (30) opening opposite an upper opening (80A) of the first through passage (72A), the connecting section having a second means for fixing the upper section (34) opening opposite an upper opening (80B) of the second through passage (78B). 5. - Tower (20) according to any one of the preceding claims, characterized 5 in that the first through passage (78A) extends substantially vertically through the buoy (26), the second through passage (78B) extending substantially vertically through the buoy (26). 6. - Tower (20) according to any one of claims 1 to 4, characterized in that the first through passage (78A) extends substantially vertically through the 10 buoy (26), the second through passage (78B) extending inclined relative to the first through passage (78A). 7. - Tower (20) according to any one of the preceding claims, characterized in that the intermediate section (30) is formed by a flexible pipe, the flexible pipe being adapted to be wound up and unwound reversibly without deformation 15 significant plastic on a drum or basket. 8. - Tower (20) according to any one of the preceding claims, characterized in that the buoy (26) has a first guide tube (83A) defining the first through passage (78A) and a second guide tube (83B ) delimiting the second through passage (78B), at least one of the first guide tube and of the second tube 20 guide being an I-tube or a J-tube. 9. - Lathe (20) according to any one of the preceding claims, characterized in that at least one of the intermediate section (30) and of the upper section (34) is provided with at least one guide member (42A , 52A) projecting radially from said section (30, 34) to guide movement of said section through a passage 25 through (78A, 78B) respectively. 10. - A method of mounting a tower (20) for operating fluid through a body of water (12), of the type comprising the following steps: - bringing a buoy (26) into the body of water (12), substantially opposite an anchoring region on the bottom (14) of the body of water (12); 30 - connection to the buoy (26) of a downstream point (40) of an intermediate section (30) of a fluid transport pipe (24); - connection to the buoy (26) of an upstream end (51A) of an upper flexible section (34) of the fluid transport pipe (24), intended to be connected to a surface assembly (22); 35 - total immersion of the buoy (26) under the surface of the body of water (12), before or after the step of connecting the downstream point (40) r <· Z - Anchoring an upstream point (38) of the intermediate section (30) on an anchoring element (25) fixed in the bottom (14) of the body of water (12) in the anchoring region; - tensioning of the intermediate section (30) of the transport pipe (24) between the downstream point (40) and the upstream point (38) under the effect of the buoyancy of the buoy (26), to maintain the section intermediate (30) substantially vertical in the body of water (12); - connection to the intermediate section (30) of a lower section (26) of the fluid transport pipe (24) intended to be connected to a bottom assembly (12) and producing fluid; - connection of the intermediate section (30) and the upper section (34) by a connecting section (32), the buoy (26) having a height, taken along a vertical axis (A-A '), less than 1.5 times its maximum transverse dimension taken transversely to the vertical axis (A-A '), the step of connecting the intermediate section (30) comprising the engagement of the intermediate section (30) through a first through passage (78A) provided through the buoy (26); characterized in that the upper section (34) is engaged through a second through passage (78B) separate from the first through passage (78A) to be connected to the intermediate section (30) via the connection section (32). 11. A method according to claim 10, characterized in that the step of connecting the intermediate section (30) and the upper section (34) via the connecting section (32) is carried out before the step of immersion of the buoy (26) under the body of water (12). 12. - Method according to claim 10 or 11, characterized in that the first through passage (7ΘΑ) and the second through passage (78B) each define a lower opening (82A, 82B) and an upper opening (80A, 80B), the intermediate section (30) being engaged in the first through passage (78A) from the lower opening (82A) to the upper opening (Θ0Α), the upper section (34) being engaged in the second through passage (7ΘΒ) from the lower opening (82B) to the upper opening (80B). 13. - Method according to any one of claims 10 to 12, characterized in that the intermediate section (30) is flexible over substantially its entire length between the downstream point (40) and the upstream point (38), the intermediate section (30) being deployed progressively in the body of water (12) between the downstream point (40) fixed on the buoy (26) and a laying structure (90) floating on the body of water (12) during of the stage of I * • 1 deployment, the intermediate section (30) being unwound from the laying structure (90) on which it is transported by being wound on a laying drum or on a basket. 14, - Method according to any one of claims 10 to 13, characterized in that it comprises a step of progressive ballasting of the buoy (26), after the steps of 5 connecting the intermediate section (30) and the upper section (34) on the connecting section (32) to descend the upstream point (38) towards the anchoring element (25), the method advantageously comprising the traction of the upstream point (38) towards the anchoring element ( 25) via a traction line (100) engaged on a return member (64) carried by the anchoring element (25) .rd.