FR2949482A1 - SUPPORT FOUNDATION FOR A HYDROLIENNE, SUBAQUATIC DEVICE AND METHOD OF PLACING THE SAME. - Google Patents

Abstract

The support foundation (20) comprises a base (50), a tidal support (54) carried by the base (50) and at least three support legs (52) on the bottom of the body of water (14). ), connected together by the base (50). Each support leg (52) comprises a hollow box (70), a rigid member (72) for adjusting the vertical position of the hollow box (70) relative to the bottom (12) of the body of water. The rigid adjustment member (72) is immobilized in vertical projection under the box (70). Each support leg (52) further comprises a member (74) for cooperation with the bottom of the body of water (14), integral with the lower end of the rigid adjustment member (72).

Description

The present invention relates to a support foundation for a tidal turbine, intended to be placed on the bottom of a body of water, the support foundation comprising: - a base; - a tidal turbine carrier carried by the base; - At least three support legs on the bottom of the body of water, connected to each other by the base, each support leg having a hollow box.

Such a support foundation is intended to be placed in abutment on the bottom of a body of water, in which hydraulic or marine currents are present. This body of water may be for example an ocean, or a sea, in which case the hydraulic or marine currents result in particular tides or swell. Alternatively, the body of water is a river or river, in which the hydraulic or marine currents result in particular from the flow between the source and the mouth of the body of water. The support foundation carries and fixes on the bottom of the body of water a tidal turbine comprising a turbine and an alternator. The tidal turbine is able to collect the hydraulic energy resulting from the circulation of water into a mechanical energy of rotation using the turbine, then to transform the mechanical energy into electrical energy using the alternator . Given the potential strength of the currents that can be exerted on the tidal turbine, it is important that the support foundation maintains the tidal turbine very firmly in position on the bottom of the body of water, keeping as much as possible the orientation tidal turbine to optimize its energy production. To ensure good stability to the tidal turbine, it is known to use a tripod-type support foundation, as described for example in WO 2008/110811 and EP 1 992 741. These support foundations comprise a central base carrying the tidal turbine. and three vertical legs to sink into the bottom of the body of water.

Each leg includes a box open down which sinks into the bottom of the body of water, once the foundation support placed on the bottom. In WO 2008/110811, the box is further ballasted to stabilize the support foundation on the bottom of the body of water.

Such support foundations are well suited for substantially flat bottoms and having sufficient rigidity to prevent too much depression of the support foundation in the bottom. If the bottom is not flat, it is necessary to prepare the bottom of the body of water, both to ensure a certain flatness, and to ensure that the bottom is not too loose. This prevents the support foundation from sinking uncontrollably into the subsoil and ensures the orientation of the tidal turbine in a horizontal plane and in a vertical plane. Such a preparation of the bottom of the body of water is consuming time and heavy means, since it is necessary to mobilize vessels specialized in underwater earthmoving. An object of the invention is to obtain a tidal turbine support foundation that can be arranged simply and inexpensively on any type of seabed, including those having a bottom provided with reliefs and / or soft areas.

To this end, the subject of the invention is a support foundation of the aforementioned type, characterized in that each support leg further comprises: a rigid member for adjusting the vertical position of the box relative to the bottom of the mass of water, the rigid adjustment member being immobilized in vertical projection under the box; * A cooperating member with the bottom of the body of water, secured to the lower end of the rigid adjustment member. The support foundation according to the invention may comprise one or more of the following characteristics, taken in isolation or in any combination (s) technically possible (s): - at least two of the adjustment members have heights different, taken between the caisson and the cooperation body; each adjusting member comprises a deployable element towards the bottom of the body of water with respect to the box before the installation of the support foundation on the bottom of the body of water; each adjusting member comprises a fixed element relative to the caisson, the deployable element being mounted movable relative to the fixed element before the installation of the support foundation on the bottom of the body of water, the fixed element and the deployable element being in particular formed by telescopic tubes; - Each box comprises at least one bottom wall and a side wall defining an internal volume to be filled with gas to ensure proper buoyancy to the support foundation on the body of water; - The box comprises an upper wall closing up the internal volume, the box having at least one injection nozzle and / or purge fluid in the interior volume. the internal volume opens constantly upwards above the lateral wall; one of the cooperation members delimits a cavity opening downwards, intended to be inserted into the bottom of the body of water; the cavity is delimited by a hollow receptacle opening downwards and presenting an upper closing wall towards the top of the cavity; one of the cooperation members comprises a totally solid bottom surface, in particular a convex surface, to oppose the penetration of the cooperation member into the bottom of the body of water. The invention also relates to an underwater device for generating electric power, characterized in that it comprises: a support foundation as defined above; a tidal turbine mounted on the tidal turbine support. The invention also relates to a method of setting up a support foundation as defined above comprising the following steps: transporting the support foundation at least partially above the surface of the body of water up to at a point next to a laying region of the supporting foundation on the bottom of the body of water; - total immersion of the support foundation in the body of water; - Laying of the legs of the support foundation resting on the laying region, each cooperating member being placed in contact with the bottom of the body of water. The method according to the invention can comprise one or more of the following characteristics, taken alone or in any combination (s) technically possible (s): - it comprises a pitch adjustment step protruding each rigid adjustment member under the box, and a step of immobilizing each rigid adjustment member relative to the box. - The step of adjusting the height of each rigid adjustment member projecting under the box is performed before the total immersion of the support foundation in the body of water. - The transport step is performed by maintaining the support foundation partially immersed in the body of water under the effect of its own buoyancy.

The invention will be better understood on reading the description which will follow, given solely by way of example, and with reference to the appended drawings, in which: FIG. 1 is a partially exploded perspective view from above of FIG. a first device for generating electrical power comprising a support foundation according to the invention placed on the bottom of a body of water; Figure 2 is a side view of the device of Figure 1; - Figure 3 is a view similar to Figure 2, before its installation on the bottom of the body of water; - Figure 4 is a sectional view along a median vertical plane of a leg of the support foundation of Figure 1; 5 to 9 are views similar to FIG. 4 of variants of support foundation legs according to the invention; - Figure 10 is a front view of a tidal turbine clean to be carried by the support foundation of Figure 1; - Figure 11 is a perspective view of three-quarter face of another clean water turbine to be carried by the support foundation of Figure 1; - Figure 12 is a side view showing a laying ship and a support foundation according to the invention, in a first step of a first method of placing the support foundation according to the invention; - Figure 13 is a view similar to Figure 12, in a second step of the first implementation method; - Figure 14 is a side view of a laying ship and a support foundation in a first step of a second implementation method according to the invention; - Figure 15 is a view similar to Figure 14 in a second step of the second implementation method; and FIG. 16 is a view similar to FIG. 14 during a third step of the second placing method. A first underwater device 10 for generating electrical power according to the invention is shown in FIGS. 1 to 4.

This device 10 is intended to be placed on the bottom 12 of a body of water 14, in order to produce electrical power from the hydraulic or marine currents present in the body of water 14. The body of water 14 is for example a body of salt water presenting hydraulic or marine currents, such as an ocean or a sea, or a body of fresh water in circulation, such as a river or a river. The minimum depth of the water body 14 in the region where the device 10 is placed is greater than 5 m and is generally between 20 m and 60 m. The bottom 12 of the body of water is delimited by solid material such as rocks or sediments. It has an upper surface which, in the example shown in FIG. 2, is provided with asperities such as steps 16A, 16B, 16C extending at different depths with respect to the surface of the body of water. The bottom 12 of the body of water 14 may furthermore have relatively more rigid zones and relatively more flexible areas facing the underwater device 10. The underwater device 10 is totally immersed under the surface of the body of water 14 It comprises a support foundation 20 fixed in abutment on the bottom 12 of the body of water 14 and a tidal turbine 22, sometimes referred to as the hydroelectric turbine, mounted on the support foundation 20. In known manner, the tidal turbine 22 comprises a base body 24 fixed on the support foundation 20 by means of a fixing stud 26.

It comprises a hydraulic turbine 28 rotatably mounted about a substantially horizontal axis A-A 'on the base body 24 to transform the hydraulic energy present in the body of water 14 into a mechanical rotational energy. The tidal turbine 22 further comprises an alternator 30 adapted to convert the mechanical energy resulting from the rotation of the turbine 28 into an electric power. In the example of a tidal turbine 22 shown in FIG. 10, the base body 24 comprises a fairing 32 capable of guiding the flow of water towards the turbine 28 along its axis of rotation AA 'and a turbine support. 34 The turbine 28 comprises a hub 36 rotatably mounted about the axis AA 'in the turbine holder 34 and a plurality of blades 38 which protrude radially in the fairing 24 from the hub 36. In the tidal turbine variant 22 shown in FIG. 11, the base body 24 is devoid of fairing and the turbine 28 is mounted at one end of the turbine support 34. In another variant, the axis AA 'of rotation of the turbine 28 is vertical. In the example shown in FIG. 1, the fixing stud 26 comprises a substantially cylindrical upper portion 40 carrying the base body 24, an intermediate guiding portion 42 of convergent shape downwards, and a substantially cylindrical lower portion 44 for to be inserted in the support foundation 20. The lower portion 44 has a transverse dimension, taken perpendicular to a vertical axis, less than the transverse dimension of the upper portion 40. The attachment stud 26 comprises, along a generator of the lower portion 44, a vertical guide rib 46 for angularly indexing the tidal turbine 22 on the support foundation 20 as will be seen below. In the example shown in the figures, the tidal turbine 22 is removably mounted on the support foundation 20 so that it can be raised to the surface of the body of water 14, for its periodic maintenance, without having to go up the foundation. 20. Alternatively, the tidal turbine 22 is permanently fixed on the support foundation 20. With reference to FIGS. 1 to 4, the support foundation 20 comprises a perforated base 50, at least three substantially vertical legs 52 of support on the base. bottom 12 of the body of water 14, connected together by the base 50, and a tidal turbine support 54 carried by the base 50. In the example shown in FIG. 1, the base 50 has an outer contour substantially in polygon shape, the legs 52 being arranged at the vertices of the polygon.

More specifically, the base 50 has an advantageously equilateral or isosceles triangle shape and the support foundation 20 has three legs disposed at the top of the base 50. In a variant, the number of legs 52 is greater than three to further increase the stability of the base. support foundation 20.

The base 50 is formed by a plurality of ribs 60A, connecting the tug support 54 to each leg 52, and a plurality of ribs 60B connecting each leg 52 to two adjacent legs 52. Thus, in the example shown in FIG. 1, the base 50 comprises at least two inclined ribs 60A, connecting the base 54 to each leg 52 and at least two substantially horizontal ribs 60B connecting a leg 52 to an adjacent leg 52. The ribs 60A, 60B delimit between them circulation of water to minimize the resistance of the support foundation 20 to hydraulic or marine currents.

According to the invention, each leg 52 comprises a hollow upper box 70, a member 72 for adjusting the vertical position of the box 70 relative to the bottom 12 of the body of water, attached to the box 70 to protrude vertically under the box 70, and a cooperating member 74 with the bottom 12 of the body of water 14, disposed at the lower end of the adjusting member 72, in contact with the bottom 12. Each leg 52 further comprises an element 76 hooking to a line of descent of the support foundation 20 in the body of water 14.

As illustrated in FIG. 4, each box 70 delimits an internal volume 78 of buoyancy and ballasting, intended to be filled selectively with a gas to ensure the buoyancy of the support foundation 20 during its transport and by a solid or a liquid of ballast to ensure the stability of the support foundation 20 on the bottom 12 of the body of water 14 after the laying of the support foundation. Each box 70 has a substantially cylindrical shape with a vertical axis B-B '. It thus comprises a bottom wall 80, a peripheral lateral wall 82 and an upper wall 84, the walls 80, 82 and 84 internally defining the volume 78.

The internal volume of each box 70 is for example between 300 m3 and 500 m3. The casing 70 further comprises a nozzle 85A for injection of liquid or solid into the volume 78 and a purge tap 85B of the volume 78 opening into the internal volume 78 above the injection nozzle 85A The connections 85A, 85B are equipped with valves to selectively block access to the volume 78. The adjustment member 72 is fixed on the box 70. It has a maximum transverse dimension, taken horizontally in Figure 2, less than the minimum transverse dimension of the box 70.

The member 72 comprises in this example a first tubular element 86 fixedly mounted in the casing 70 through the internal volume 78 between the bottom wall 80 and the upper wall 84 and a lower tubular element 88, deployable from the fixed element 86 before or during the installation of the support foundation 20, to adjust the vertical position of the box 70 above the bottom 12 of the body of water. In this example, the fixed element 86 and the movable element 88 are formed by telescopic tubes mounted sliding one inside the other along a vertical axis.

The deployable member 88 is movable relative to the fixed member 86 to protrude downwardly beyond the housing 70 between a retracted position in the well 70, shown in FIG. 3, and a plurality of deployed positions under the box 70 at a chosen height.

During the installation of the support foundation 20, the deployable element 88 is temporarily or permanently immobilized in a deployed position chosen relative to the fixed element 86 and relative to the box 70, to maintain the box 70 at a fixed position. vertical position chosen relative to the bottom 12 of the body of water.

This vertical position is for example between 0.5 m and 5 m above the bottom 12. The immobilization of the fixed element 86 relative to the deployable element 88 is for example provided by welding, by screwing, by riveting, or by plastic deformation.

The presence of the adjustment members 72 on the different legs 52 makes it possible to adjust the height of each adjustment member 72 which projects below the box 70 between the bottom wall 80 and the cooperation member 74 as a function of the depth of the bottom 12 opposite the leg 52. Thus, whatever the topography of the bottom 12 of the body of water 14, the boxes 70 can be maintained with their bottom walls 80 substantially at a vertical position chosen so that the base 50 and the support 56 have a determined orientation in a horizontal plane and in a vertical plane. In the example shown in the figures, the base 50 is kept substantially horizontal, the boxes 70 are all arranged substantially at the same depth with respect to the surface of the body of water 14. For this purpose, as shown in FIG. 2, the projecting height of the adjusting members 72 between the box 70 and the cooperation member 74 may be different from one leg 52 to the other. This height is for example between 1/10 times and 1 times the height of the box 70.

Thus, the support foundation 20 comprises at least two adjustment members 72 which have different heights projecting under their caisson 70.

The cooperation member 74 has an upper maximum transverse dimension, taken horizontally in FIG. 2, greater than the maximum transverse dimension of the rigid adjustment member 72. In the example shown in FIGS. 1 to 4, the member 74 is formed by a shoe 90 attached to the lower end of the adjusting member 72. The pad 90 is disposed in abutment on the bottom 12 of the body of water. It has a bottom surface 92, convex and convex, directed downwards to prevent or at least limit the depression of the leg 52 in the bottom 12, especially if the bottom 12 is movable.

In a variant, shown in Figure 5, the pad 90 is formed by a cone pointing downwards, delimiting a bottom surface 92 full. Such a conical shoe 90 is particularly adapted to a bottom 12 consisting of or comprising a large amount of rocks 94. In the variants shown in Figures 6 and 7, the cooperation member 74 is formed by a hollow receptacle 94 returned to the bottom delimiting a cavity 96 for receiving the bottom 12. The cavity 96 opens downwards to allow the receptacle 94 to sink into the bottom 12. In the example shown in FIG. 6, the height of the receptacle 94 is advantageously relatively small, for example, less than the height of the box 70. In addition, the hollow wall delimiting the receptacle 54 is solid facing the volume 98 delimited between the receptacle 94 and the bottom 12 in the cavity 96. In the variant shown in FIG. the receptacle 94 comprises a stitch 100 opening into the volume 98 through an upper region of the hollow wall forming the receptacle 94. The stitching 100 is intended to be connected to a pump to suck the fluid present in the volume 98 and drive the receptacle 54 into the bottom 12, which forms a suction anchor. The height of the receptacle 94 is then advantageously greater than that of the box 70.

In the variant shown in FIG. 8, the cooperation member 74 is formed by a mass 102 of cement which is injected through the upper tubular element 86 and through the lower tubular element 88 whose end is first introduced. by drilling in the bottom 12 of the body of water 14. The mass 102 extends around the lower tubular element 88 between its lower end and the mass of water 14. Depending on the different soil compositions forming the bottom 12 opposite the legs 52, a cooperation member 74 adapted to the nature of the ground below the leg 52 is used. The support foundation 20 may therefore comprise legs 52 having cooperation members 74 of distinct structures. This makes it possible to ensure good stability, in particular horizontal stability, of the support foundation 20 on the bottom 12 of the mass of water 14.

In a variant shown in FIG. 9, the box 70 is open upwards along the upper edge of the side wall 82. It thus has no upper wall 84 above the side wall 82. The interior volume 78 can be filled with liquid and / or solid ballast through the opening of the box 70 located above the side wall 82.

Referring to Figure 1, the tidal turbine support 54 comprises a nacelle 110 substantially cylindrical, and a sleeve 112 for guiding the attachment stud 26 inserted into the nacelle 110 The nacelle 110 is formed by a hollow wall opening upwards. It extends along a nacelle axis CC 'which, in this example, is vertical and passes substantially in the vicinity of the barycentre of the base 50. The ribs 60A connecting the support 54 to each leg 52 are fixed on the outer surface of the nacelle 110 being angularly distributed around the axis of the nacelle. The guide sleeve 112 is arranged in the nacelle 110. It comprises a lower region 114 intended to receive the lower portion 44 of the stud 26 and an upper region 116 diverging upwards for the support of the convergent intermediate portion 42 of the stud 26 The sleeve 112 further defines a vertical slot 118 for receiving the indexing rib 46, the slot 118 opening upwards through a divergent cavity 120 for guiding the groove 46 towards the slot 118. The lower region 114 defines a cylindrical central cavity of cross section substantially conjugated to the cross section of the lower portion 44.

The upper region 116 also defines an upwardly diverging central cavity, having a shape complementary to the shape of the intermediate portion 42. The slot 118 extends through the lower region 114 and partially through the upper region 116. has a width conjugate to that of the rib 46 to block in rotation the stud 26 about the axis CC 'when the rib 46 is received in the slot 118. The diverging cavity 120 is formed in the upper region 116 at the end upper of the slot 118.

When the tidal turbine 22 is fixed on the support foundation 20, the stud 26 has been partially introduced into the nacelle 110. The lower portion 44 is housed in the lower region 114 and the intermediate portion 42 rests on the upper region 116. The rib 46 is immobilized angularly in the slot 118 providing angular indexing of the tidal turbine 22 in a determined position around the axis C-C '. A first method of setting up a device 10 for generating electrical power according to the invention is illustrated in FIGS. 12 and 13. This method is implemented using a laying ship 130 provided with lifting gear 132, such as cranes. The machines 132 have deployable lines 133 capable of lowering the device 10 in the body of water 14. This process comprises a step of transporting the support foundation 20 to the surface of the body of water 14 to a point located facing a laying region 134 of this foundation on the bottom 12 of the body of water 14.

The method then comprises a step of total immersion of the support foundation 20 in the body of water 14 from the laying ship 130, and a step of placing the support foundation 20 resting on the bottom 12 of the mass of water. 14. Initially, in the transport step, the support foundation 20 is loaded onto the ship 130. As shown in FIG. 3, the adjusting members 72 of the legs 52 are retracted into the caissons 70, so that the vertical footprint of the support foundation 20 is minimal.

For this purpose, the lower tubular elements 88 are maintained in the retracted position in the upper tubular elements 86. The cooperation members 74 are kept close to the caissons 70. In a first variant of the method, the topography of the laying region 134 is determined before the establishment of the support foundation 20. Thus, the height of each adjusting member 72 projecting under the box 70 is calculated for each leg 52 according to the determined topography to maintain the base 50 in a direction determined by in relation to a vertical plane and in relation to a horizontal plane on the bottom 12 of the body of water 14.

The adjustment members 72 are then deployed on the surface for each leg 52, by adjusting their height according to the height values calculated for each leg 52. Then, the lower tubular elements 88 are immobilized at the height determined on the upper tubular elements 86 by welding or by plastic deformation on the surface of the body of water, for example on the laying ship 130. The actuating lines 133 are then fixed on the attachment members 76 and the cranes 132 are operated to extract the support foundation 20 out of the ship 130 and place it facing the laying region 134 above or partially immersed in the body of water 14. A selected quantity of solid and / or liquid ballast is then introduced into the interior volume 78 of each box 70 and the support foundation 20 is lowered into the body of water 14. In the example shown in Figure 12, the tidal turbine 22 is previously mounted on its port 54 by introducing the attachment stud 26 into the nacelle 110 as previously described. Alternatively, the support foundation 20 is lowered and placed on the bottom 12 before the tidal turbine 22, the tidal turbine 22 then being lowered into the body of water 14 after the support foundation 20 has been placed on the bottom 12.

Then, in the immersion step, the support foundation 20 is totally immersed in the body of water 14, then descends to the region 134 while being hung on the lines 133 to have the cooperation members 74 in contact with the bottom 12 of the body of water.

Given the presence of adjusting members 72 of suitable heights for each leg 52 and 74 preselected cooperation members to adapt to the nature of the soil constituting the bottom 12, the support foundation 20 is positioned very precisely and robust on the bottom 12 of the body of water 14. This is achieved without the need to perform extensive earthworks, and a very simple installation process to implement. The cost of laying the support foundation 20 and the device 10 is reduced and the laying operation is facilitated. Then, the lines 133 are detached from the attachment members 76 and are raised to the laying ship 130. The tidal turbine 22 is then able to operate and produce electric power under the effect of the rotation of the turbine 28 via the alternator 30.

In a variant of the method, the support foundation 20 is lowered while keeping the adjustment members 72 retracted. Then, when the support foundation 20 reaches a chosen position with at least one leg 52 located away from the bottom 12 of the body of water, the lower tubular elements 88 are released to deploy towards the bottom 12 of the mass of water. until the engagement member 74 comes into contact with the bottom 12. When the positioning of the support foundation 20 is satisfactory, the lower elements 88 are immobilized relative to the upper elements 86, for example by plastic deformation. and lines 133 are raised. A second method of implementation according to the invention is shown in FIGS. 14 to 16. Unlike the first method described in FIGS. 12 and 13, the internal volume 78 of the buoyancy chambers 70 is filled with a quantity of gas sufficient to provide sufficient buoyancy to the support foundation 20 to maintain it partially immersed in the surface of the body of water 14, under the effect of its own buoyancy. As illustrated in FIG. 14, this own buoyancy is also sufficient to maintain the tidal turbine 22 above the surface of the body of water when this tidal turbine 22 is initially carried by the support foundation 20. At the transport stage shown in Figure 14, the laying ship 130 then draws the support foundation 20 partially immersed in the body of water 14 by means of a traction line 140 to a point opposite the region of 134. It is therefore not necessary that the ship 130 be equipped with lifting gear 132 of high capacity, capable of allowing the lifting of the support foundation 20.

Then, when the support foundation 20 reaches the aforementioned point, located opposite the implantation region 134, water lines 142 provided with buoys 144 distributed along their length are attached to each attachment element 74, in order to maintain the horizontal position of the support foundation 20 at the beginning of its immersion.

The fluid injection taps 85A of each box 70 are open to inject liquid or solid ballast into the interior volume 78, replacing at least a portion of the gas present in this volume 78. The buoyancy of the support foundation 20 decreases, causing its total immersion near the surface.

As illustrated in FIG. 16, the ship 130 is then placed above the support foundation 20. A down line 146, deployed with the aid of a winch from the ship 130, is then connected to the control members. grip 76 and the water lines 142 can be detached hooks 76. The support foundation 20 is then gradually lowered by the line of descent 146 to the region 134, to arrange the legs 52 resting on the bottom 12 of the body of water as previously described. Alternatively, the immersion of the support foundation 20 and its removal on the bottom 12 are carried out exclusively using the water lines 142, without using a line of descent 146 from the ship 130.

The immersion of the support foundation 20 is then automatically controlled by the buoys 144 present on the water lines 142. In all cases, as previously described, the adjustment members 72 may be deployed either before the lowering of the support foundation 20 in the body of water 14, if the topography of the region 134 has been previously studied, or alternatively, when the support foundation 20 is disposed in the body of water 14 in the vicinity of the region 134 with at least one leg to the distance from the bottom 12.

Claims (1)

CLAIMS1.- Foundation support (20) for a tidal turbine (22), intended to be placed on the bottom (12) of a body of water (14), the support foundation (20) comprising: - a base (50) ; - a tidal turbine carrier (54) carried by the base (50), - at least three legs (52) for bearing on the bottom (12) of the body of water, connected together by the base (50) each support leg (52) having a hollow box (70), characterized in that each support leg (52) further comprises: * a rigid member (72) for adjusting the vertical position of the box (70); ) relative to the bottom (12) of the body of water, the rigid adjustment member (72) being immobilized vertically projecting under the box; * A member (74) for cooperation with the bottom (12) of the body of water, secured to the lower end of the rigid adjustment member (72). 2. Supporting base (20) according to claim 1, characterized in that at least two of the adjusting members (72) have different heights, taken between the box and the cooperation member (74). 3. Supporting base (20) according to claim 1 or 2, characterized in that each adjusting member (72) comprises a member (88) deployable towards the bottom (12) of the body of water relative to the box ( 70) before the installation of the support foundation (20) on the bottom (12) of the body of water. 4. Supporting base (20) according to claim 3, characterized in that each adjusting member (72) comprises a fixed element (86) relative to the box (70), the deployable element (88) being mounted movably by relative to the fixed element (70) before the installation of the support foundation (20) on the bottom (12) of the body of water, the fixed element (86) and the deployable element (88) being in particular formed by telescopic tubes. 5. Supporting foundation (20) according to any one of the preceding claims, characterized in that each box (70) comprises at least one bottom wall (80) and a side wall (82) defining an interior volume (78) adapted to be filled with gas to ensure proper buoyancy to the support foundation (20) on the body of water (14). 6. Supporting foundation (20) according to claim 5, characterized in that the box (70) comprises an upper wall (84) closing up the inner volume (78), the box (70) having at least one stitching (85A, 85B) for injecting and / or purging fluid into the interior volume (78). 7. Supporting foundation (20) according to claim 5, characterized in that the internal volume (78) permanently opens upwards above the side wall (82). 8. Supporting foundation (20) according to any one of the preceding claims, characterized in that at least one of the cooperating members delimits a cavity (96) opening downwards, intended to be inserted into the bottom ( 12) of the body of water. 9. Supporting foundation (20) according to claim 8, characterized in that the cavity (96) is delimited by a hollow receptacle (94) opening downwards and having an upper closing wall towards the top of the cavity (96). 10. Supporting base (20) according to any one of the preceding claims, characterized in that at least one of the cooperation members (74) comprises a bottom surface (92) completely solid, in particular convex, to oppose the penetration of the cooperation member (74) in the bottom (12) of the body of water (14) 11.- Underwater device (10) for generating electrical power, characterized in that it comprises: - a support foundation (20) according to any one of the preceding claims, - a tidal turbine (22) mounted on the support of tidal turbine (54). 12. A method of placing a supporting foundation (20) according to any one of claims 1 to 10, characterized in that it comprises the following steps: - transporting the support foundation (20) at least partially above the surface of the body of water (14) to a point opposite a laying region (134) of the supporting foundation (20) on the bottom (12) of the body of water ; - total immersion of the support foundation in the body of water (14) - arrangement of the legs (52) of the support foundation (20) resting on the laying region (134), each cooperation member (74) being placed in contact with the bottom (12) of the body of water. 13.- Method according to claim 12, characterized in that it comprises a step of adjusting the projecting height of each rigid adjustment member (72) under the box, and a step of immobilizing each rigid adjustment member (72) relative to the box (70). 14.- Method according to claim 13, characterized in that the step of adjusting the height of each rigid adjustment member (72) projecting under the box (70) is performed before the total immersion of the support foundation ( 20) in the body of water (14). 15.- Method according to any one of claims 12 to 14, characterized in that the transport step is performed by maintaining the support foundation (20) partially immersed in the body of water (14) under the effect of its own buoyancy.