WO2015052450A1

WO2015052450A1 - Method for installing underwater foundations for an offshore device and corresponding installation assembly

Info

Publication number: WO2015052450A1
Application number: PCT/FR2014/052573
Authority: WO
Inventors: Didier VERROUIL; Nicolas PICH; Jean Michel JEANTY; Vincent RABARON
Original assignee: Soletanche Freyssinet
Priority date: 2013-10-11
Filing date: 2014-10-10
Publication date: 2015-04-16
Also published as: FR3011856B1; FR3011856A1

Abstract

The invention relates to a method for installing underwater foundations (10) for an offshore device, said foundations comprising a support (20), notably of the jacket-leg type, for the device. The method involves a step of placing the support (20) on the seabed (S) and a step of definitively anchoring the support (20) to the seabed (S), said method further involving a step stabilizing the support prior to the step of definitively anchoring, by virtue of which the support (20) is stabilized while definitive anchoring is being performed.

Description

METHOD FOR INSTALLING AN UNDERWATER FOUNDATION FOR OFFSHORE DEVICE AND INSTALLATION ASSEMBLY

CORRESPONDING

Background of the invention

The present invention relates to the field of submarine foundations for offshore devices, such as offshore wind turbines.

More specifically, the invention relates to an underwater foundation for offshore device comprising a base for the offshore device, which base is intended to rest on the submarine ground.

The invention is particularly suitable for the installation of underwater foundations comprising a base in the form of a tower generally having three or four tubular metal feet connected by wire mesh, also called "jacket".

Throughout the present application, underwater foundations comprising a jacket-type base are called, for the sake of brevity, jacket type foundations.

A first method currently used for the installation of such foundations is to achieve deep foundation elements, including piles, in the ground located at the locations provided for the feet of the base, to set up the base, then to secure the base to said elements.

Another known method is to set up the base before making the elements of deep foundation and to secure the whole.

These methods have the disadvantage of requiring heavy and rare nautical means, so expensive. They are also strongly constrained by weather conditions, which can lengthen the time required for their implementation, and significantly increase their cost.

Obiet and summary of the invention

An object of the invention is to propose a method of installing an underwater foundation for an offshore device which greatly reduces the need for nautical means, both in terms of their capacity and on that of their duration of use, and which allows a flexible phasing and little dependent on the meteorological conditions.

The invention achieves its goal thanks to such a method of installing an underwater foundation for an offshore device, said foundation comprising a base, in particular of jacket type, for the device, the method comprising a step of setting up the base on the underwater ground, a step of definitive anchoring of the base to the submarine ground, and, after the step of placing the base on the submarine soil and before the definitive anchoring step , a stabilization step of the base on the underwater ground, whereby the base is stabilized during the realization of the final anchorage.

The immersed portion of the base once in place is subject to the forces of the swell and its emerged part, to the forces of the wind. The resulting horizontal and / or traction forces may tend to tilt the base, or to translate it horizontally.

The stabilization step provided by the method according to the present invention is intended to strengthen the base against tilting and / or lateral translation, before and during the realization of the final anchoring of the base.

By realization of the final anchoring here is meant, in particular, the realization of the drilling operations necessary for this anchoring.

The stabilization means implemented during this step are sized to take a first envelope of forecast efforts. Prior to the stabilization stage, the predicted efforts to which the basement will be subjected once it has been put in place and in the absence of the offshore device, in particular the stresses due to waves and wind, are generally evaluated, and the characteristics of the baselines are determined. means of stabilization (nature, position, dimensions, number) so that once put in place, they are able to resume these efforts.

The first envelope of planned efforts therefore corresponds, for example, to the horizontal forces and tensile-compressive forces to which the base is subjected, independently of the offshore device that it is intended to support thereafter. In this case, the stabilizing means are not able to take up, by themselves, the traction-compression forces and the horizontal forces to which is subjected, in operation, the assembly formed by the base and the offshore device that it supports.

The final anchors of the base are sized to take a second envelope of forecasting efforts greater than those of the first envelope. The second envelope of planned efforts corresponds, for example, traction forces and horizontal forces applied to the assembly formed by the base and the offshore device that it supports, and the compression efforts transmitted by this set.

Thus, advantageously, the stabilization step uses dimensioned stabilization means to take up a first envelope of predictive forces to be applied to the base once set up on the subsea ground, to stabilize said base, and the final anchoring implements anchoring means sized to take up a second envelope of forces greater than those of the first envelope.

Achieving the final anchoring of the base typically involves heavy and precise work.

Pre-stabilization of the base allows greater flexibility of work. As the base is stable, the realization of the permanent anchorage can take place even in adverse weather conditions. The duration of this work is therefore reduced, as is their cost.

The offshore device can be fixed on the base after completion of the final anchoring.

According to one embodiment of the invention, the stabilization step comprises the application of a stabilizing force on the upper part of the base, so as to urge said base towards the subsea ground.

In the present description, unless otherwise stated, the adjectives above and below are used with reference to the direction of the main axis of the pedestal which is generally perpendicular to the ground surface, once the pedestal is in place, the lower end the base is then oriented towards the ground and its upper end towards the surface of the water.

In some cases, we can define the main axis of the base as an axis of symmetry of the base. By "upper part of the base" is meant that part of the base extending axially from the upper end of the base over a distance of 40%, preferably 20%, of the total height of the base measured along its axial direction.

Generally, the upper part of the base corresponds to a part of the base that emerges at least occasionally from the water, when the base is in its final position at sea.

In one example, the stabilizing force is directed substantially along the main axis of the base. Once the base is in place, its main axis generally extends substantially vertically. The stabilizing force can therefore, for example, be directed substantially vertically.

According to one example, the stabilizing force extends along a straight line passing through the center of gravity of the base.

In one example, the stabilizing force is obtained, during the stabilization step, by tending at least one armature between the upper part of the base and the ground. The armature being locked with respect to the upper end of the base on the one hand and relative to the ground on the other hand, the base is prevented from deforming when it is subjected to horizontal forces and / or traction.

By reinforcement is meant here any elongate element adapted to withstand tensile stresses, including a bar or a cable consisting of a plurality of strands.

The frame can be passive or active. A passive frame is not stretched, at rest, but tends when shear or horizontal forces are applied to the base. An active armature is, on the contrary, stretched over its entire length between its two attachment points, respectively positioned in the upper part of the base and at its lower end, prior to loading the base. In this case, at rest, the base is prestressed.

In one example, the frame extends between the legs of the base, for example along the main axis of the base.

Generally, the frame is fixed to a mounting bracket itself fixed to the ground.

The fixing support, which may for example take the form of a metal template or a concrete sole, may be fixed to the ground of various ways, including its own weight, or by means of anchoring in the ground. It can for example be fixed by means of at least one anchor or being secured to a deep foundation element made in the ground.

By deep foundation element is meant here any geotechnical work placed in the ground to transfer actions and limit deformations, and in particular, adapted to take compression efforts, traction, and shear forces. A pile or a micropile are examples of deep foundation elements.

As is well known per se, a anchor consists of a frame sealed in a borehole and tensioned, the frame may be including a cable or a bar. Unlike the aforementioned deep foundation elements, the anchor pulls only tensile forces.

To reduce the time of establishment of the stabilization means, it is advantageous to use, for the realization of the deep foundation elements and tie rods, the vibrating drilling technique. This technique, known from French Patent Applications Nos. 1259,134, 1259,136 and 1259,137 filed by the Applicant, comprises carrying out a drilling in the ground and injecting a grout into said borehole. performing said drilling comprising vibrating a drill pipe and introducing said vibrating tube into the ground.

According to another embodiment of the invention, during the stabilization step, the base is ballasted by means of at least one load disposed on its upper part.

In this case, for example, the load comprises at least one container, in particular a compartmentalized container, and the container is filled with water during the stabilization step. According to another embodiment of the invention, the stabilization step comprises the securing of the base to at least one deep foundation element made in the ground and adapted to take up and distribute in the ground the forces transmitted by the base, for example a pile or a micropile.

In this case, the deep foundation element or elements form stabilization means sized to take up the first aforementioned force envelope. These elements are realized before setting up the base. More particularly, the drilling operations necessary for their realization are carried out before installation of the base. Stabilization of the base is obtained afterwards, by securing the base to said element (s).

Drilling operations related to the realization of the final anchorage

(sized to take the second envelope of aforementioned efforts) are, they after the stabilization of the base.

According to an example of implementation, before the stabilization step, is installed on the subsea ground, in the vicinity of the location provided for a foot of the base, at least one sole adapted to distribute forces transmitted by the base .

According to one example, the soleplate is installed on the submarine floor before the step of placing the base, and during the placing step, the base is installed so that a foot rests on said soleplate. .

In another example, the sole is secured to a foot of the base and is installed jointly with said base during the step of placing the base, whereby once the base installed, the foot of the base rests on said sole.

According to an example, the method may comprise, prior to the step of producing the final anchoring, a step of adjusting the verticality of the base.

The final anchoring of the base can take different forms.

In cases where stabilization is achieved by applying a stabilizing force to the top of the pedestal, the final anchoring of the pedestal may include increasing the intensity of the stabilizing force.

In cases where, during the stabilization step, a reinforcement is attached between the upper part of the base and the ground, it is possible, during the final anchoring, to apply to said reinforcement a tensile force greater than that applied during the stabilization stage.

It is also possible, during the final anchoring, to add a load in the vicinity of the upper end of the base. According to an exemplary embodiment, the additional load may be constituted by the offshore device, which is fixed to the upper end of the base.

We can also increase the weight of a load implemented during the stabilization of the base. For example, you can add water to volume already contained in a container fixed on the upper part of the base during the stabilization step.

According to other examples, the definitive anchoring can be obtained by means independent of those allowing the provisional stabilization.

In this case, the stabilizing force can indifferently be maintained or eliminated after completion of the final anchoring of the base.

For example, one or more tie rods can be made between the underwater ground located in the vicinity of a foot of the base and the upper end or a foot of the base.

According to another example, it is possible to make one or more deep foundation elements in the ground and to secure the base to said deep foundation element.

To achieve the deep foundation element or tie rods, one can use the technique of vibrating drilling, that is to say drill a hole in the ground and inject a grout in said drilling, the realization of said drilling comprising vibrating a drill pipe and introducing said vibrating tube into the ground.

Advantageously, and particularly in the case where the final anchors are made by tie rods or micropiles, the final anchoring step of the base can be performed from a platform provided in the upper part of the base.

The present invention also relates to a set of installation of a submarine foundation for an offshore device, comprising a base, in particular of the jacket type, means for placing the base on the submarine ground, stabilization means for stabilize the base after it has been placed on the submarine soil and before it is permanently anchored to the submarine soil.

In one example, the stabilizing means comprise a holding member configured to apply on the upper part of the base a force directed towards the lower end of the base.

In one example, the upper part of the base comprises a platform, and the holding member comprises at least one frame fixed to the platform and extending substantially vertically from the platform to the lower end of the base.

For example, the frame extends between the feet of the base. According to another embodiment, the holding member comprises at least one load adapted to be disposed at the upper end of the base. In one example, the upper part of the base comprises a platform, and said load is disposed on said platform and / or arranged to extend said platform.

Several embodiments and implementations are described in this disclosure. However, unless otherwise specified, the features described in connection with any embodiment or implementation may be applied to another embodiment or implementation.

Brief description of the drawings

The invention will be better understood on reading the following description of embodiments of the invention given as non-limiting examples, with reference to the accompanying drawings, in which:

- Figures 1 to 6 illustrate different steps of the method of installation of a subsea foundation for offshore device, according to a first embodiment of the invention;

FIG. 7 illustrates a variant of the embodiment of FIGS. 1 to 6;

FIG. 8 illustrates the step of stabilizing a method of installing an underwater foundation according to a second embodiment of the invention; and

- Figures 9 to 12 illustrate different steps of the method of installation of a subsea foundation for offshore device, according to a third embodiment of the invention.

Detailed description of the invention

The figures described below illustrate the steps of installation of foundations 10, 110, 210 for offshore wind turbine EL, according to various embodiments of the present invention, described by way of illustration.

The foundations 10, 110, 210 implemented in the examples which follow are of the jacket type. They comprise at least one base 20 of jacket type and anchoring means 80 of this base 20 on the subsea soil S. The base 20 illustrated in the examples comprises four hollow tubular metal legs 22 distributed around a main axis A, connected by reinforcing wire meshes 24, and terminated respectively at their lower end by a foot 26.

The legs 22 of the base 20 are all slightly inclined relative to the main axis A, their respective directions meeting at the axis A.

As is apparent in particular from Figures 3 or 4, the base 20 comprises at its upper end, a PLS horizontal upper platform adapted to receive the foot of the wind turbine EL.

In the example, it further comprises an intermediate platform PLI, spaced from the upper platform PLS by a distance DP equal for example to 30% or less of the total height H of the base 20.

It should be noted that the method according to the invention would be equally applicable to a jacket-type pedestal arranged differently, comprising in particular a different number of legs, or without an intermediate platform, or to a base of different type, in particular a structure with solid walls, metallic or not.

In operation, the assembly formed by the base 20 and the EL wind turbine that it supports is subjected to tensile forces and to horizontal forces related to wind and waves, which tend to tilt or to translate it. horizontally.

The final anchoring of the base 20 in the ground S makes it possible to resume these efforts. Given the efforts involved, this anchoring usually involves a plurality of deep foundation elements of large dimensions, such as piles or micropiles, or tie rods, or a combination of these means, connected to the base .

The work of realizing this permanent anchorage therefore involves heavy resources and monopolizes a large workforce. They also require some precision that prevents their continuation when weather conditions are too unfavorable. In the latter case, the costs of the work can be increased considerably.

The method according to the present invention makes it possible to limit the overall duration of this work, by allowing their continuation even in adverse weather conditions. For this, it comprises a step of stabilizing the base 20, prior to the final anchoring, intended to prevent tilting under the effect of the swell or wind, during the work of realization of the final anchor.

Generally, and as will be described hereinafter, the method will comprise a preliminary step of evaluating a first envelope of forces corresponding, for example, to the horizontal forces and to the tensile-compressive forces to which the base alone is subjected (without a wind turbine). ), and a step of dimensioning the stabilization means to be implemented during the stabilization step, taking into account the result of this evaluation.

In the same manner, the method will generally comprise a separate step of evaluating a second envelope of forces corresponding to the forces applied to the assembly formed by the base and the wind turbine and the forces transmitted by this assembly, and a step sizing the final anchoring means to implement to resume these efforts.

The prior stabilization of the base 20 may in particular be obtained by means of stabilizing means applying on said base 20 a prestressing or stabilizing force FS acting axially towards the subsea ground S. The prestressing force FS is, according to a first embodiment of the invention, obtained by means of a holding member 60 stretched between the upper part of the base 20 and the subsea ground S. This holding member 60 is typically a frame, in particular a bar, or a cable as in the example shown.

The steps of installing a jacket type foundation 10 according to this first embodiment will be described hereinafter with reference to FIGS. 1 to 6.

Upstream of the installation of the EL wind turbine and its foundation 10, there is generally a prospecting stage at sea, and numerous studies to evaluate the meteorological conditions of the site and the geological and geotechnical characteristics of the submarine soil. S.

In a first step of the installation process, and in accordance with the foregoing, it is evaluated, by calculations based on the results of the above studies, the average forces that will be applied to the base 20 once at sea. on these calculations, the stabilization means to be implemented during the stabilization step are optimally chosen and dimensioned, for the purpose, for example, of dimensioning these means at a minimum so as to take up neither more nor less than the forces applied on the pedestal only.

The position and the optimal orientation of the armature 60 can be determined according to the predicted direction of the swell and the wind. In the absence of preferential direction, the stabilizing force FS will generally pass through the center of gravity of the base, and will be directed substantially vertically. In other cases, the shear forces applied to the base will be offset by an offset of the FS stabilization force to oppose the moment resulting from these efforts.

A second step of the installation process comprises placing, on the subsea soil S, flanges 30 which will be intended to receive the feet 26 of the base 20 and to distribute, in the ground S, the forces, in particular compression, transmitted by the base 20.

Advantageously, to ensure the proper spacing of the soles 30 is previously disposed on the undersea soil S a template 70 formed of a plurality of hollow sleeves 72 of substantially parallel axes connected by a wire mesh 76.

Each outer sleeve 72 of the jig 70 is typically designed to receive one of the flanges 30, which sole 30 will be the support of a foot 26 of the base.

For this step, which can be carried out very upstream, it is possible to take advantage of the nautical means implemented during the preliminary prospecting phases, typically a barge 90 of the type illustrated in FIG.

The jig 70 here comprises five sleeves arranged in staggered rows, the four outer sleeves 72 being intended respectively to receive a foot 26 of the base 20. The central sleeve 74 is intended to receive a fixing support 50 illustrated in FIG. the prestressing cable 60, here a concrete sole, as will be described later.

Under the influence of its weight and as shown in FIG. 1, the template 70 fits all or part of the ground S.

Follows, if necessary, a step of dredging the sediments contained in the interior space of each sleeve 72, 74, until reaching a soil of sufficient quality to receive a sole 30 or a support 50.

Whether a flange 30 is made of precast concrete or is cast in place, it advantageously comprises a plurality of reservations 32, 34 as illustrated in FIG. 1A.

One of these reservations 32, generally central, is intended to receive a foot 26 of the base 20.

Other reservations 34, surrounding this central reservation 32, are provided for the realization of the final anchors of the base 20, which will be described in more detail below.

The sole 50 forming a fixing support for the preloading cable 60 defined above, is disposed in the central sleeve 74 of the template 70 as shown in Figure 1B which is a sectional view of said sleeve.

In a third step of the method also illustrated in Figure 1B, the central sole 50 is reinforced by anchoring means adapted to take the tensile forces that will be applied to the frame 60 once tensioned. In the example, these anchoring means comprise micropiles 52 made through the reservations 56 of said soleplate 50 illustrated in FIG. 1B, and whose reinforcement is secured to the sole 50 by an anchor block 54 and by a grout sealing inside the reservation of 56.

Note that one can, during the manufacture of the sole 30, add inside at least one of reservations 34 a tube protruding from the underside of the sole. Once sealed to the ground, the tube can resume horizontal forces, especially in the case where the friction between the sole and the ground would not be sufficient.

Of course, the micropiles 52 described above can be replaced by any other deep foundation element, or by tie rods.

These anchoring elements will advantageously be made by the vibratory drilling method mentioned earlier in this paper.

Moreover, although two deep foundation elements 52 are implemented in the illustrated example, only one can in some cases be sufficient. At this stage of the installation, the prestressing cable 60 is hooked on the central soleplate 50 which, for this purpose, is provided with a ring 58 for attaching a loop of the cable. Note that any other part for the attachment of a cable or, if necessary, another frame, can replace or supplement the ring shown in the figures, for example a removable axis or other. The upper end of the cable is easily accessible because it is attached to a buoy 92 floating on the surface of the water. This step is illustrated in Figure 2.

The following step of placing the base 20, requires significant handling means, including a lifting platform 94 and a hoist 96 as shown in Figure 3.

With these means and as shown in Figures 3 and 4, the base 20 is lowered to sea and each of its four feet 26 is engaged in the corresponding reservation 32 of one of the four outer flanges 30.

Thanks to the lifting crane 96, it is possible to correctly adjust the position of each foot 26, in particular to ensure the verticality of the base 20.

Once the optimal position of the base 20 obtained, each foot 26 is secured to its sole 30 by cementing.

At this precise moment, the stability of the base 20 is not necessarily ensured under all conditions, and the hoist 96 continues to be necessary.

The cable 60 is then stretched and locked relative to the intermediate platform PLI of the base 20 by means of an anchoring system 62. In this position, the base 20 is prestressed, biased by the cable 60 towards the ground under -marine S.

In the example, the stretched cable 60 extends substantially vertically. The stabilizing force FS, shown in FIG. 4, is therefore also directed vertically. This arrangement may, as indicated above, be adjusted according to the modeling of the projected forces applied on the base 20.

Thanks to the force FS, the base 20 is prevented from tilting or translating under the effect of the swell and / or wind, especially in bad weather conditions. Therefore, the hoist 96 is no longer needed. Note that the cable 60 could be fixed to the upper platform PLS, or to any other location on the upper part of the base, that is to say the part extending from its upper end over a distance at most equal to 40%, of preferably 30% of the total height of the base 20, measured along its main axis A.

The final anchors 80 of the base 20 can take very different forms. Unlike the stabilization means 60, the final anchors 80 are adapted here to take up the forces exerted on the assembly formed by the base 20 and the wind turbine EL once secured.

In the example illustrated in FIG. 5, the base 20 is anchored by means of tie-rods 82 whose reinforcements 84, sealed to the ground S, pass respectively inside the reservations 34 of the flanges 30 and are tensioned and maintained in this position thanks to an anchoring system 86 bearing on the upper face of the sole 30.

The base 20 is then ready to receive the EL wind turbine on its upper platform PLS, as illustrated in FIG. 6.

The temporary stabilizing cable 60 can be retained or removed once the final anchoring of the base 20 ensured.

Alternatively, the tensile force applied to the cable 60 can also be increased to reinforce this anchoring and thus make it permanent.

Note that the example described above is not limiting, many variants can be envisaged.

For example, the tie rods 82 making the final anchorage can be locked at the PLS intermediate platform or upper PLS base 20. They can then pass indifferently to the inside or outside of the tubes forming the legs 22 of the base 20.

In place of the aforementioned tie rods, or part of them, it will also be possible to bond the soles to elements of deep foundations such as piles or micropiles.

In the same way, the anchoring means of the cable fixing support can take different forms: piles, tie rods, etc. FIG. 7 illustrates a variant of the first embodiment described above, in which the fixing support 50 of the armature 60 is a metal ballast, fixed to the ground S by its own weight. As in the previous embodiment, the armature 60 is stretched and locked relative to the upper part of the base 20 by means of an anchoring system 62.

FIG. 8 illustrates a method of installing an underwater foundation 110 for an offshore device according to a second embodiment of the invention. Here, the stabilizing force FS is due to the weight of an additional load 160 secured to the upper part of the base 120.

In the example, the load 160 consists of a plurality of removable compartments 162, compartmentalized, filled with water pumped into the sea, and dimensioned to provide reduced resistance to wind.

As in the example illustrated, the load 160 is preferably configured to enlarge the upper platform PLS (or, if appropriate, an intermediate platform) of the base 120.

A method of installing an underwater foundation 210 for an offshore device according to a third embodiment of the invention will now be described with reference to FIGS. 9 to 12.

The provisional stabilization of the base 210 is obtained, here, by producing deep foundation elements 260 in the ground S, prior to the establishment of the base 220, and by securing the feet 226 of the base 220 to these deep foundation elements a once the base is in place.

In the example illustrated, the deep foundation elements are piles 260. According to a technique known per se, these piles 260 are, in a first step of the method illustrated in FIG. 9, made by threshing a metal tube 262 in the soil using a threshing hammer. On this occasion, an empty upper part of the tube is retained to allow the housing of a foot of the base and its attachment with the pile 260.

In the particular example represented diagrammatically illustrated in FIG. 10, each leg 226 of the base 220 consists of the lower end of a leg 222 and a plurality of hollow sleeves 228. surrounding said leg 222, integral therewith and extending substantially axially.

In a second step of the method, the base 220 is put in place, the lower end of each of its legs 222 being engaged in the upper part of the tube 262 of a pile 260 remained free. The base 220 being held by a hoist 96, its vertical positioning is easily adjusted. Once verticality assured, his feet 226 are secured to the piles 260 by cementing, as shown in Figure 10.

Thanks to its attachment to the piles 260, the base 220 is stabilized against tilting before the start of the final anchoring work.

The piles 260 are here dimensioned to take the projected forces of traction and the horizontal forces related to the swell and the wind as well as the compressive forces, in the absence of a wind turbine.

Note that the piles are just one example of deep foundation elements that can be implemented in the present embodiment.

Furthermore, the connection of the base with the deep foundation elements can be achieved by means different from those described above.

The final anchorage made in a subsequent step reinforces these preliminary foundations, to take all the efforts that will be applied to the base and the wind turbine which it is solidary, in operation.

In the example, the final anchorage consists of a plurality of piles 280 bonded to the base 220, the peripheral sleeves 228 of each leg 226 of the base 220 constituting guides for drilling these piles 280. This step is illustrated in FIG. Figures 11 and 12.

Note, again, that the final anchorage could include in addition to or instead of piles, micropiles, tie rods or other means adapted to properly resume the aforementioned efforts.

Claims

A method of installing an underwater foundation (10, 110, 210) for an offshore device (EL), said foundation comprising a base (20, 120, 220), in particular of the jacket type, for the device (EL), said method comprising

a step of placing the base (20, 120, 220) on the underwater ground (S) and

a step of permanently anchoring the base (20, 120, 220) to the underwater ground (S),

the method being characterized in that it comprises, after the step of placing the base on the submarine soil and prior to the final anchoring step, a step of stabilizing the base on the underwater soil whereby the base (20, 120, 220) is stabilized during the completion of the final anchorage.

A method according to claim 1, wherein the stabilization step uses stabilization means sized to take up a first envelope of forecast forces to be applied to the base once placed on the submarine soil, for stabilize said base, and the final anchoring implements anchoring means sized to take a second envelope of forces greater than those of the first envelope.

A method according to claim 1 or 2, wherein the stabilizing step comprises applying a stabilizing force (FS) to the upper part of the base (20,120) so as to urge said base (20,120 ) towards the submarine soil (S).

Method according to any one of claims 1 to 3, wherein, during the stabilization step, at least one reinforcement (60) is stretched between the upper part of the base (20) and the ground (S).

The method of claim 4, wherein the armature (60) is attached to a mounting bracket (50) itself fixed to the ground (S).

6. Method according to claim 5, wherein the fastening support (50) is secured to the ground by means of a tie rod. 7. The method of claim 5, wherein is carried out at least one deep foundation element (52) and secures the support (50) to said deep foundation element (52).

8. Method according to any one of claims 1 to 7, wherein, during the stabilization step, the pedestal (120) is weighted by arranging at least one load (160) on its upper part.

9. The method of claim 3 and any one of claims 1 to 8, wherein, during the final anchoring of the base (20, 120), the intensity of the stabilizing force (FS) is increased.

10. The method of claim 1 or 2, wherein the stabilization step comprises the securing of the base (220) to at least one deep foundation element (260) made in the ground (S) and adapted to resume and distribute in the ground (S) efforts transmitted by the base (220).

11. Method according to any one of claims 1 to 10, wherein the upper part of the base (20, 120, 220) comprises a platform (PLS, PLI), and the final anchoring step of the base (20, 120, 220) is performed from said platform (PLS, PLI).

12. Method according to any one of claims 1 to 11, wherein, during the final anchoring of the base, is made at least one anchor between the soil (S) submarine located in the vicinity of a foot (26, 126, 226) of the base (20, 120, 160) and the upper part or foot of the base (20, 120, 220).

13. Method according to any one of claims 1 to 12, wherein, during the final anchoring of the base (20, 120, 220), is made at least one deep foundation element (80, 280) in the ground (S) and secures the base (20, 120, 220) to said deep foundation member (80, 280).

14. Method according to any one of the preceding claims, wherein before the stabilization step, is installed on the subsea ground (S), in the vicinity of the location provided for a foot (26, 126) of the base (20, 120), at least one sole (30, 130) adapted to absorb forces transmitted by the base (20, 120). 15. Installation set of an underwater foundation (10, 110, 210) for an offshore device (EL), comprising a base (20, 120, 220), in particular of jacket type, means for setting up the base (20, 120, 220) on the subsea ground (S), and stabilizing means for stabilizing the base (20, 120, 220) after it has been placed on the underwater ground (S) and previously at its final anchorage to the underwater ground (S).

16. An assembly according to claim 15, wherein the stabilizing means comprises a holding member (60, 160) configured to apply on the upper part of the base (20, 120) a force directed towards the lower end of the base (20, 120). , 120).

17. The assembly of claim 16, wherein the upper part of the base comprises a platform (PLS, PLI), and in that the holding member comprises at least one armature (60) fixed to the platform (PLS, PLI). and extending substantially vertically from the platform to the lower end of the base (20).

18. The assembly of claim 16, wherein the holding member comprises at least one load (160) adapted to be disposed on the upper part of the base (120).