STABILIZATION SYSTEM, ESPECIALLY FOR A FLOATING SUPPORT, WITH AT LEAST THREE LIQUID RESERVES CONNECT

专利摘要:
The present invention relates to a system for stabilizing (1) a system subjected to external stresses, in particular for a floating support, the stabilization system comprising at least three liquid stores (2) and at least three connecting tubes ( 3). The liquid reserves (2) are spatially distributed. In addition, the connecting tubes (3) ensure the circulation of the liquid between all liquid reserves. The invention further relates to a floating support comprising such a stabilization system.
公开号:FR3048409A1
申请号:FR1651746
申请日:2016-03-02
公开日:2017-09-08
发明作者:Olivier Lepreux；Christophe Coudurier
申请人:IFP Energies Nouvelles IFPEN；
IPC主号:

专利说明:

The present invention relates to the field of floating supports at sea ("offshore") in particular for offshore wind turbines, the field of supports placed at sea, in particular for offshore wind turbines laid, and the field of civil engineering, in particular for skyscrapers or bridges.
In the case of offshore wind turbines, the floating support supports, partly emerged, the wind turbine consisting of blades, rotor, nacelle and mat fixed on the floating support. These floating supports can be anchored to the seabed by stretched, semi-tensioned anchor lines or catenary anchor lines. The purpose of the floating support is to bring the buoyancy and stability of the wind turbine, so as to take the forces exerted on it, while limiting the movements of the assembly.
Various floating supports dedicated to the installation of multi-megawatt offshore wind turbines are under development in many countries. Depending on the depth of the considered site, several design options are possible. Despite their great diversity, several families of floating support emerge. There may be mentioned: SPAR-type floats, characterized by a slender geometric shape, and comprising a large ballast in order to lower the center of gravity of the entire structure as much as possible, and thus to ensure stability, barge type floats: these are low draft and very wide supports. Their stability is ensured by their large water surface. However, this type of support is very sensitive to swells, the TLP-type supports (of the English "Tension Leg Platform" which can be translated by platform to taut lines), which have the distinction of being moored in the background of the sea by taut lines guaranteeing the stability of the structure, and - the semi-submersible floats: these are supports consisting of at least three floats connected by arms to ensure rigidity. These supports generally have a small displacement, and have a large inertia of the buoyant surface, thus giving them a sufficient recovery torque to their stability. In addition, this type of float is less sensitive to swell than barges.
Floating supports can also be used in other areas than the offshore wind turbine installation (at sea), for example for hydrocarbon production means, wave energy systems (wave energy converter in mechanical energy or electric) ...
In order to allow the damping of the movement caused by the waves, various damping solutions have been envisaged for these floats.
According to a first solution, the damping can be achieved by a ballasting system with a "U-shaped tube" comprising a liquid that can move between the two vertical branches of the U. This solution is described in particular in the document: C. Coudurier, O. Lepreux, and N. Small, Passive and Semi-Active Control of an Offshore Floating Wind Turbine Using a Liquid Damper Column, in Proc, of 10th IFAC Conference on Maneuvering and Control of Marine Craft, MCMC, 2015.
However, this solution only serves to dampen the movements caused by the swell in a single direction. Indeed, for waves whose direction is not parallel to the "U-tube", the movement is not damped. However, at sea, the direction of the swell is variable in time, therefore the swell is not constantly parallel to the "U-tube".
In addition, the problem of stability also arises in other areas, for example for structures laid down at sea (especially for laid-down wind turbines) which are subjected to the stresses caused by the swell, but also for structures in the field of civil engineering. (buildings, bridges) that can be subjected to stresses caused by the wind or an earthquake ...
Thus, the present invention relates to a system for stabilizing a system subjected to external stresses, the stabilization system comprising at least three reserves of liquid and at least three connecting tubes. Liquid reserves are spatially distributed (not located in a single plane). In addition, the connecting tubes ensure the circulation of the liquid between all liquid reserves. Thus, the liquid can move in all directions, to dampen excitations, regardless of the direction of the swell.
The system according to the invention The invention relates to a stabilization system, in particular for a floating support, comprising at least three liquid stores and at least three connecting tubes, said liquid stores being distributed in such a way that, in order to from above, the centers of said liquid reserves are arranged on at least two distinct straight lines, and said connecting tubes connecting said liquid reserves for a circulation of said liquid between said liquid reserves. Said connecting tubes connect all said liquid reserves to each other.
According to one embodiment, said connecting tubes comprise means for restricting the passage of said liquid.
Advantageously, said connecting tubes form a star or a polygon, preferably a regular polygon, the vertices of said star or said polygon being formed by said liquid reserves, and the edges of said star or said polygon being formed by said tubes of link.
According to an alternative embodiment, said stabilization system comprises a reserve of liquid in the center of said star or said polygon.
According to one embodiment, said reserves of said liquid comprise a gas in their upper parts.
Advantageously, said stabilization system comprises at least one conduit for passing said gas connecting at least two liquid reserves.
Preferably, said gas passageways are parallel to said connecting tubes.
According to one design, at least one gas passage pipe comprises means for restricting the passage of the gas.
Advantageously, at least one liquid reserve has a connection with a gas of the external medium.
According to one embodiment, said liquid reserves have substantially a cylindrical shape.
According to one characteristic, said stabilization system comprises between three and eight reserves of liquid.
According to one design, said connecting tubes are arranged at the lower part of said liquid stores.
According to one embodiment, said connecting tubes are substantially horizontal.
In addition, the invention relates to a floating support comprising at least one float and a stabilization system according to one of the preceding characteristics.
According to one embodiment, said floating support comprises at least three floats, each float comprising a reserve of liquid of said stabilization system.
In addition, the invention relates to a system for producing energy at sea, comprising a wind turbine and a floating support according to one of the preceding characteristics.
BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the system according to the invention will become apparent on reading the description hereafter of nonlimiting examples of embodiments, with reference to the appended figures and described below.
Figure 1 illustrates a stabilization system according to a first embodiment of the invention.
Figures 2a to 2d illustrate variants of the first embodiment.
FIG. 3 illustrates a stabilization system according to a second embodiment of the invention.
Figures 4a to 4d illustrate variants of the second embodiment.
Figures 5a to 5f illustrate various embodiments of the stabilization system according to the invention.
FIG. 6 is a curve representing the displacement amplitude of a float for a system according to the prior art, and for a float according to the invention, for different angles of incidence of the swell.
Figures 7a and 7b illustrate the orientation of the swell for the example of Figure 6. Detailed Description of the Invention
The present invention relates to a stabilization system for a system that can be subjected to external stresses. The stabilization system comprises at least three liquid stores, and at least three connecting tubes. The liquid reserves are distributed three-dimensionally (spatially), that is to say that, in top view, the center of the liquid reserves are arranged on at least two distinct lines. Thus, the liquid reserves are distributed in at least two separate planes. In other words, the liquid reserves are not located in a single plane, which would correspond in plan view to an alignment of the centers of the liquid reserves on a single line. This three-dimensional distribution makes it possible to dampen the movements of the floating support for all directions of the swell. The connecting tubes connect the liquid reserves, thus allowing the circulation of the liquid between the liquid reserves. According to the invention, the connecting tubes connect all the liquid reserves between them. In other words, the liquid can move from one reserve to any other reserve of the stabilization system. This feature makes it possible to optimize the multidirectional damping, and also allows a reduced cost by the use of a single damping system within a floating system, and a limitation of the bulk of the liquid reserves, and easy adaptation to the geometry of the floating support (not necessarily possible with conventional U-tubes). The connecting tubes can connect adjacent liquid stores. and / or connecting a reserve of liquid to a central liquid reservoir, and / or connecting a reserve of liquid to another connecting tube.
The system being able to be subjected to stresses can be a floating support subjected to stresses caused by the swell. The system can also be a structure placed at sea subjected to stresses caused by the swell. Alternatively, this system can be a structure of civil engineering: a building, a bridge, ... subject to stresses of the wind or an earthquake. In the description, only the case of the floating support will be mentioned, but the various variants of the stabilization system described are suitable for any type of system subjected to external stresses.
Advantageously, the liquid used is water, for example seawater. However, the liquid may be of any type, in particular a liquid that does not pollute or little water from the ambient environment in case of leakage. .
The connecting tubes may be advantageously located in the lower part (at the base) of the liquid reserves, so as to promote the movement of the liquid between the liquid reserves.
In addition, the connecting tubes may be substantially horizontal, thus limiting the displacement of the liquid by gravity.
In the rest of the description and for the claims, the terms vague, seaflows, and waves are considered equivalent.
According to one embodiment of the invention, the connecting tubes can form a star or a polygon. In this case, liquid reserves form the vertices of the star or the polygon, and the connecting tubes form the edges of the star or the polygon. The choice of a polygon or a star is done in particular to adapt to the architecture of the floating support. Typically for a floating support of the semi-submersible type, it can be ensured that the tanks are located at the floats of the semi-submersible structure, and that the connecting tubes are supported by the arms connecting the floats. These arms can be star or polygon, we can adapt the stabilization system accordingly.
The star design allows the use of shorter connecting tubes. The "polygon" design allows for easier design by avoiding connections between connecting tubes.
For example, the star can have from three to six branches. In addition, the star can have a reserve of liquid in its center. When the connecting tubes form a polygon, the polygon is preferably a regular polygon, thus allowing a balanced distribution of the liquid, promoting the three-dimensional damping of the floating support. For example, the stabilization system may comprise three liquid reserves, connected by connecting tubes forming a triangle, preferably an equilateral triangle. In another example, the stabilization system may comprise four reserves connected by four connecting tubes forming a quadrilateral, preferably a rhombus, and very preferably a square. The polygon can also be a pentagon, a hexagon, an octagon (with eight reserves of liquid), and so on.
According to an implementation of the invention, at least one connecting tube may be steel, composite material, plastic, concrete, or any similar material.
According to one embodiment of the invention, at least one connecting tube, and preferably all the connecting tubes, comprises means for restricting the passage of the liquid. The means for restricting the passage of the liquid make it possible to slow down the flow that passes through them, so as to optimize the damping provided by the stabilizing system. These means of restricting the passage of the liquid can be passive or active. The active restriction means make it possible to improve the damping performances. The restriction means can be formed for example by a reduction of the diameter of the tube locally, by a valve, pumps, or compressors, etc. Setting this restriction adjusts some features of the damping system.
Liquid reserves can be of different shapes. Thus, they can be adapted to different forms of floating support. According to a preferred design of the invention, the liquid reserves have substantially a cylindrical shape. The reserves of liquid can then be designated by the term column.
According to one embodiment of the invention, at least one liquid reserve may be made of steel, composite material, plastic, concrete, or any similar material.
According to one embodiment of the invention, the lower part of the liquid reserves comprises the liquid, and the upper part comprises a gas, especially air. According to a first design, the liquid reserves can freely exchange gas with the external environment.
For this implementation (with a gas in the upper part), the stabilization system may include gas passageways connecting the liquid reserves. The liquid reserves can then be isolated from the outside air, so that an overpressure in a liquid supply causes a flow of gas to a liquid supply having a lower pressure through a gas passage. Advantageously, the gas passage pipes are located in the upper part of the liquid reserves. The gas passages may be parallel to the connecting tubes. Parallelism makes it possible to limit the size of the stabilization system. Alternatively, the gas passage pipes can connect the liquid reserves differently than the connecting tubes. For example, when the connecting tubes form a star, the gas passage pipes can form a polygon, and conversely, when the connecting tubes form a polygon, the gas passage pipes can form a star.
According to one characteristic, the gas passage pipes may comprise means for restricting the passage of the gas. The means for restricting the passage of the gas make it possible to limit the flow of gas from one liquid reserve to another. These means of restricting the passage of the liquid can be passive or active. The active restriction means make it possible to improve the damping performances. The means for restricting the passage of the gas may be formed, for example, by reducing the diameter of the tube locally, by means of a valve, pumps, or compressors. Adjusting this restriction adjusts certain characteristics related to the damping of the stabilization system.
In addition, alternatively or in addition to the gas flow lines, at least one liquid reserve may comprise a connection with the external medium, allowing the passage of air from the external environment to the upper part of the liquid reserve and vice versa. . Thus, an overpressure in a liquid reserve generates a flow of gas to the outside. This connection can be a restriction. The adjustment of this overpressure makes it possible to adjust certain characteristics related to the damping of the stabilization system.
The dimensions of the connecting tubes and the liquid reserves depend on the size of the floating support. It can be sought to move the water reserve to the maximum in the floating support, and the connecting tubes are adapted accordingly. For example for a circular barge 36m in diameter, and in a triangle polygon configuration, can be used connecting tubes of about 30m long, diameter 1.5m, reserves of 5 to 10m high and 3m diameter. Typically one can use a total mass of liquid (contained in the liquid reserves and connecting tubes) of the order of 5 to 15% of the mass of the floating support. The concept works however at all scales.
According to one embodiment, the stabilization system comprises an equal number of liquid reserves and connecting tubes. Alternatively, the difference between the number of liquid reserves and the number of connecting tubes may be equal to one. This equality or quasi-equality makes it possible to ensure that all the liquid reserves are connected to each other by connecting tubes. However, the stabilization system with a larger number of connecting tubes can allow simultaneous damping of several components of wave motion (typically rotation and translation) with a single stabilization system, by increasing the number of natural frequencies stabilization system.
FIG. 1 represents, schematically and without limitation, a stabilization system according to a first embodiment of the invention. The stabilization system 1 is formed of three reserves of liquid 2 and three connecting tubes 3. The centers of the liquid reserves 2 are arranged on two distinct lines, in other words: the liquid reserves 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects two liquid stores 2. Thus, the connecting tubes 3 form a triangle. In the illustrated case, it is an equilateral triangle. The connecting tubes 3 are situated in the lower part of the liquid reserves 2. This arrangement is adapted to a floating support of the tri-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire stabilization system.
Figures 2a to 2d show, schematically in plan view, and without limitation, four variants of the first embodiment, that is to say with three liquid reserves connected in a triangle.
The stabilization system, according to the alternative embodiment of Figure 2a, further comprises elements illustrated in Figure 1, the liquid passage passage restriction means 4. The liquid 4 passage restriction means are placed on each tube 3. They reduce the flow of liquid passing through the connecting tubes 3.
The stabilization system, according to the alternative embodiment of Figure 2b, further comprises elements illustrated in Figure 1, gas flow lines 5 (dashed lines) and means for restricting the passage of the gas 6. The gas flow lines 5 connect the upper part of the liquid reserves 2 for the passage of gas from one liquid reserve to another. For this variant, the gas flow lines 5 are parallel to the connecting tubes 3, and thus form a triangle. In addition, each gas passage pipe 5 comprises means for restricting the passage of the gas 6. They make it possible to limit the flow of gas between the liquid stores 2. However, these means for restricting the passage of the gas 6 are optional.
The stabilization system, according to the alternative embodiment of Figure 2c, further comprises elements illustrated in Figure 1, gas flow lines 5 (dashed lines) and means for restricting the passage of gas 6. The gas flow lines 5 connect the upper part of the liquid reserves 2 for the passage of gas from one liquid reserve to another. For this variant, the gas flow lines 5 are not parallel to the connecting tubes 3, and form a star joining at the center of the triangle formed by the connecting tubes 3. In addition, each gas passage 5 has means for restricting the passage of the gas 6. They allow to limit the flow of gas between the liquid reserves 2. However, these means for restricting the passage of the gas 6 are optional.
The stabilization system, according to the alternative embodiment of Figure 2d, further comprises elements illustrated in Figure 1, connections 7 with the external medium. The connections 7, in the form of a restriction, allow the passage of the gas from the external environment in the upper part of the liquid reserves 2 and vice versa. This variant may further comprise gas passage pipes (not shown).
These variants can be combined with each other; in particular, the stabilization systems of the variant embodiments of FIGS. 2b to 2d may comprise means for restricting the passage of the liquid, as illustrated in FIG. 2a.
FIG. 3 is a diagrammatic view from above, and in a nonlimiting manner, of a stabilization system according to a second embodiment of the invention. The stabilization system 1 is formed of three reserves of liquid 2 and three connecting tubes 3. The centers of the liquid reserves 2 are arranged on two distinct lines, in other words: the liquid reserves 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects a reserve of liquid 2 and two other connecting tubes 3. Thus, the connecting tubes 3 form a star with three branches. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the tri-float type, for which each float comprises a reserve of liquid 2. This embodiment variant is also adapted to a floating support comprising a single float, this single float comprising the entire system stabilization.
Figures 4a to 4d show, schematically in plan view, and without limitation, four variants of the second embodiment, that is to say with three reserves of liquid connected star.
The stabilization system, according to the variant embodiment of FIG. 4a, furthermore comprises elements illustrated in FIG. 3, means for restricting the passage of the liquid 4. The means for restricting the passage of the liquid 4 are placed on each tube. 3. They reduce the flow of liquid passing through the connecting tubes 3.
The stabilization system, according to the variant embodiment of FIG. 4b, additionally comprises elements illustrated in FIG. 3, means for restricting the passage of the liquid, gas flow lines (in dotted lines), means for restricting the passage of gas 6 and connections 7 with the external medium. The liquid passage 4 restriction means are placed on each connecting tube 3. They reduce the flow of liquid passing through the connecting tubes 3. The gas flow lines 5 connect the upper part of the liquid reserves 2 for the passage of gas from one liquid reserve 2 to another. For this variant, the gas flow lines 5 are not parallel to the connecting tubes 3, and thus form a triangle. In addition, each gas passage pipe 5 comprises means for restricting the passage of the gas 6. They make it possible to limit the flow of gas between the liquid stores 2. However, these means for restricting the passage of the gas 6 are optional. Moreover. The connections 7, in the form of a restriction, allow the passage of the gas from the external environment in the upper part of the liquid reserves 2 and vice versa.
The stabilization system, according to the alternative embodiment of Figure 4c, further comprises elements illustrated in Figure 3, the gas passageways 5 (in dashed lines) and means for restricting the passage of gas 6. The gas flow lines 5 connect the upper part of the liquid reserves 2 for the passage of gas from one liquid reserve to another. For this variant, the gas flow lines 5 are parallel to the connecting tubes 3, and thus form a star. In addition, each gas passage pipe 5 comprises means for restricting the passage of the gas 6. They make it possible to limit the flow of gas between the liquid stores 2. However, these means for restricting the passage of the gas 6 are optional.
The stabilization system, according to the alternative embodiment of Figure 4d, further comprises elements illustrated in Figure 3, connections 7 with the external environment. The connections 7, in the form of a restriction, allow the passage of the gas from the external environment in the upper part of the liquid reserves 2 and vice versa. This variant may further comprise gas passage pipes (not shown).
These variants can be combined with each other; in particular, the stabilization systems of the alternative embodiments of FIGS. 4c and 4d may comprise means for restricting the passage of the liquid. In addition, each variant embodiment of FIGS. 4a to 4d may comprise a reserve of liquid in the center of the device. 'star.
Figures 5a to 5f illustrate, in top view, and without limitation, other embodiments of the stabilization system according to the invention. In these figures, only the main elements have been represented. Nevertheless, these embodiments are compatible with the use of gas passage conduits, liquid passage restriction means, gas passage restriction means, connections with the external medium, etc.
The stabilization system, according to the embodiment of FIG. 5a, comprises six liquid stores 2 and six connecting tubes 3. The centers of the liquid stores are arranged on three distinct lines, in other words: liquid 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects two liquid stores 2. Thus, the connecting tubes 3 form a hexagon. In the illustrated case, it is a regular hexagon. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the hexa-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system. stabilization.
FIG. 5b is a diagrammatic view in plan view, and in a nonlimiting manner, of a stabilization system according to another embodiment of the invention. The stabilization system 1 is formed of six liquid stores 2 and six connecting tubes 3. The centers of the liquid stores 2 are arranged on three distinct lines, in other words: the liquid stores 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects a reserve of liquid 3 and the other connecting tubes 2. Thus, the connecting tubes 3 form a six-pointed star. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the hexa-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system. stabilization. This embodiment may optionally include a reserve of liquid in the center of the star (not shown).
FIG. 5c is a diagrammatic view from above, and in a nonlimiting manner, of a stabilization system according to another embodiment of the invention. The stabilization system 1 is formed of four liquid stores 2 and three connecting tubes 3. The centers of the liquid stores 2 are arranged on two distinct lines, in other words: the liquid stores 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects a reserve of liquid 3 to another reserve of liquid. Thus, the connecting tubes 3 form a star with three branches and has a reserve of central liquid (in the center of the star). The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the tri-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system stabilization.
The stabilization system, according to the embodiment of Figure 5d, comprises four liquid reserves 2 and four connecting tubes 3. The liquid reserves 2 are not arranged in a single plane, they are spatially distributed. The centers of the liquid stores 2 are arranged on two distinct lines, in other words: the liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects two liquid stores 2. Thus, the connecting tubes 3 form a quadrilateral. In the illustrated case, it is a square. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the four-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system stabilization.
The stabilization system, according to the embodiment of FIG. 5e, comprises five liquid reserves 2 and five connecting tubes 3. The centers of the liquid reserves 2 are arranged on three distinct lines, in other words: the reserves of liquid 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects two liquid stores 2. Thus, the connecting tubes 3 form a pentagon. In the illustrated case, it is a regular pentagon. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the penta-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system stabilization.
The stabilization system, according to the embodiment of FIG. 5f, comprises four liquid stores 2 and six connecting tubes 3. The centers of the liquid stores are arranged on two distinct lines, in other words: liquid 2 are not arranged in a single plane, they are spatially distributed. The liquid stores 2 have a substantially cylindrical shape. Each connecting tube 3 connects two liquid stores 2. For this embodiment, the connecting tubes 3 form a star and a triangle, in particular an equilateral triangle, with a liquid reserve 2 disposed in the center of the triangle. The connecting tubes 3 are located in the lower part of the liquid reserves. This arrangement is adapted to a floating support of the four-float type, for which each float comprises a reserve of liquid 2. This variant embodiment is also adapted to a floating support comprising a single float, this single float comprising the entire system stabilization. By means of this design, it is possible to damp two components of the swell movement simultaneously (typically a rotation and a translation) with a single damping system (this is possible because the number of eigenfrequencies is increased).
In addition, the present invention relates to a floating support. The floating support comprises a stabilization system according to any one of the combinations of variants described above. The stabilization system makes it possible to damp the multidirectional movement of the swell for the floating support.
The floating support may have a single float having a substantially cylindrical shape, for example as described in the patent application FR 2998338. In this case, the stabilization system may be included in the single float.
Alternatively, the floating support may comprise a plurality of floats connected together. It may be in particular of the tri-float type, as described in the patent application FR 2990005 (US 2015-0071779). This design with several floats has, in general, a small displacement, and has a large inertia of the buoyant surface, thus giving them a sufficient recovery torque to their stability. In addition, this type of float is less sensitive to swell than barges. In the case of a plurality of floats, each float may comprise a liquid reserve of the stabilization system, the connection tubes of the stabilization system then connect the different floats to each other and may be supported by the structure of the floating multi-float support.
These floating supports can be anchored to the seabed by stretched, semi-tensioned anchor lines or catenary anchor lines.
The present invention also relates to a wind turbine installation on a body of water (sea for example). The installation comprises a vertical axis or horizontal axis wind turbine, and a floating support according to any of the combinations of variants described above. The purpose of the floating support is to bring the buoyancy and stability of the wind turbine, so as to take the forces exerted on it, while limiting the movements of the assembly. The floating support according to the invention is particularly suitable for the installation of an offshore wind turbine (offshore), to allow the damping of the swell and the stability of the wind turbine.
The floating support according to the invention can also be used in fields other than the offshore wind turbine installation (at sea), for example for hydrocarbon production means, wave energy systems (energy converter of the swell in mechanical or electrical energy), but also in civil engineering, for example for skyscrapers or bridges ...
Example
To evaluate the performance of a floating support (float) equipped with a stabilization system according to the invention, one can describe on the one hand the interactions between the latter and the float and, on the other hand, the interactions between the float and the swell. A Lagrangian approach is used to obtain the equations of motion, the general form of which is given by
where L is the Langrangian of the system consisting of the float and the stabilization system, the parameters of the system and the generalized forces.
By this example, we show the multidirectional character of the stabilization system according to the invention. For this, we evaluate the response of a float equipped with a stabilization system according to the invention as shown in Figure 1, for different angles of incidence of the swell. A local coordinate system is associated with each incidence angle, as defined in Figure 7a. Whatever the angle of incidence, the movements of the float are evaluated in the local coordinate system of the incident swell (thus of the excitation), in particular in terms of angular amplitude of motion in the direction perpendicular to the incident wave ( according to Xf).
The results are given in FIG. 6 using the MIT barge as a float (as described in the document: JM Jonkman, Dynamics Modeling and Loadings of an Offshore Floating Wind Turbine, PhD Thesis NREL / TP-500-41958, National Renewable Energy Laboratory, Nov 2007). FIG. 6 includes curves of the ratio A (° / m) of the angular amplitude with respect to the height of the wave as a function of the wave period Th (s). This float being circular, by symmetry, its response without damping device, that is to say according to the prior art, is identical regardless of the angle of incidence. This answer is given by the REF curve. To evaluate the sensitivity of the response of the float equipped with the stabilization system according to the invention, to the angle of incidence of the swell, this angle was varied by interval of 15 ° between -30 ° and + 30 ° ( see FIG. 7). The support according to the invention "in equilateral triangle" being itself invariant by rotation of 120 ° and symmetrical, this 60 ° sweep is equivalent to a 360 ° sweep of the angle of d 'impact. The curves (one for each angle of incidence of the swell) obtained for the system according to the invention are denoted INV. These curves are almost identical. Compared with the REF reference according to the prior art, the use of the stabilization system according to the invention INV allows a very significant reduction (about 50%) of the amplitude of the movement over a wide range of excitation periods, just as it is the case for a barge equipped with a simple "tube in U" disposed in the plane of incidence of the swell. In addition, by superimposing the curves, there is an extremely low sensitivity to the angle of incidence. It can therefore be said that the stabilization system according to the invention has a multidirectional character for damping. In contrast, a simple "U-tube" system does not allow damping for a swell whose incidence angle is perpendicular to the axis of the "U-tube".

权利要求:
Claims (16)
[1" id="c-fr-0001]
Claims 1) Stabilization system, in particular for a floating support, comprising at least three liquid stores (2) and at least three connecting tubes (3), said liquid stores (2) being distributed in such a way that viewed from above, the centers of said liquid stores (2) are arranged on at least two distinct lines, and said connecting tubes (3) connecting said liquid reserves (2) for a circulation of said liquid between said liquid reserves (2 ), characterized in that said connecting tubes (3) connect all said liquid reserves (2) to each other.
[0002]
2) System according to claim 1, wherein said connecting tubes (3) comprise means (4) for restricting passage of said liquid.
[0003]
3) System according to one of the preceding claims, wherein said connecting tubes (3) form a star or a polygon, preferably a regular polygon, the vertices of said star or said polygon being formed by said liquid reserves (2 ), and the edges of said star or said polygon being formed by said connecting tubes (3).
[0004]
4) System according to claim 3, wherein said stabilization system (1) comprises a liquid reserve (2) in the center of said star or said polygon.
[0005]
5) System according to one of the preceding claims, wherein said reserves of said liquid (2) comprise a gas in their upper parts.
[0006]
6) System according to claim 5, wherein said stabilization system (1) comprises at least one conduit for passage of said gas (5) connecting at least two liquid reserves (2).
[0007]
7) System according to one of claims 5 or 6, wherein said gas passageways (5) are parallel to said connecting tubes (3).
[0008]
8) System according to one of claims 5 to 7, wherein at least one gas passage conduit (5) comprises means for restricting the passage of the gas (6).
[0009]
9) System according to one of claims 5 to 8, wherein at least one liquid reserve (2) comprises a connection (7) with a gas of the external medium.
[0010]
10) System according to one of the preceding claims, wherein said liquid reserves (2) have substantially a cylindrical shape.
[0011]
11) System according to one of the preceding claims, wherein said stabilization system (1) comprises between three and eight reserves of liquid (2).
[0012]
12) System according to one of the preceding claims, wherein said connecting tubes (3) are arranged at the bottom of said liquid reserves (2).
[0013]
13) System according to one of the preceding claims, wherein said connecting tubes (3) are substantially horizontal.
[0014]
14) Floating support comprising at least one float and a stabilization system (1) according to one of the preceding claims.
[0015]
15) Floating support according to claim 14, wherein said floating support comprises at least three floats, each float comprising a liquid reserve (2) of said stabilization system (1).
[0016]
16) A system for producing energy at sea, comprising a wind turbine and a floating support according to one of claims 14 or 15.

类似技术:

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公开号 | 公开日 | 专利标题

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FR3048409A1|2017-09-08|STABILIZATION SYSTEM, ESPECIALLY FOR A FLOATING SUPPORT, WITH AT LEAST THREE LIQUID RESERVES CONNECTED THERETO

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FR2967642A1|2012-05-25|OFFSHORE WIND POWER DEVICE WITH PARTICULAR SEMI-SUBMERSIBLE FLOAT

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FR3052817A1|2017-12-22|FLOATING DEVICE SUPPORT FOR OFFSHORE WIND TURBINES AND FLOATING WINDING ASSEMBLY THEREFOR

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EP1856406B1|2010-11-17|Device for maintaining a hydraulic turbomachine

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JP2010280301A|2010-12-16|Floating structural for offshore facility and method of constructing offshore facility

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EP2441893A1|2012-04-18|Support device for a wind turbine for producing electric power at sea, corresponding facility for producing electric power at sea.

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EP3286069B1|2019-09-25|Floating mounting having a depth-variable horizontal cross-section

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FR3053020A1|2017-12-29|PLATFORM FOR A FLOATING WIND TURBINE, FLOATING WIND TURBINE EQUIPPED WITH SUCH A PLATFORM.

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FR2990476A1|2013-11-15|Wind turbine for use at sea, has supporting unit for supporting mast of wind turbine in desired position, where supporting unit is interdependent of mast, and independent of movements of floating support

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EP2852759A1|2015-04-01|Floating wind turbine having a vertical axle, with improved flotation stability

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WO2008047011A2|2008-04-24|Network of floaters, especially for anchoring wind turbines and/or underwater generators on deep marine sites

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EP2746581B1|2017-08-16|Offshore wind turbine on an off-axis floating support

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WO2017148648A1|2017-09-08|Stabilisation system, in particular for a floating support, comprising multiple u-shaped damping devices

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FR2867523A3|2005-09-16|Sea and river currents` energy acquiring device for producing e.g. electricity, has turbines vertically suspended under support barge, where turbines are fixed together by their supports and connected to barge using vertical posts

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FR3072643A1|2019-04-26|FLOATING WIND TURBINES WITH REDUCED PILLARS

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EP3490883A1|2019-06-05|Floating support structure comprising a floater and a damping plate with a cross-section that varies with depth

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WO2017001246A1|2017-01-05|Floating platform intended to support a wind turbine tower and wind turbine comprising a tower assembled to the platform

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EP3490882A1|2019-06-05|Floating support structure comprising a floater and a damping plate with a row of apertures

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FR3088893A1|2020-05-29|Floating structure skirt

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FR2670459A1|1992-06-19|SEMI-SUBMERSIBLE PLATFORM WITH POROUS BRIDGES.

同族专利:

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公开号 | 公开日

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US10683065B2|2020-06-16|

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WO2017148647A1|2017-09-08|

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US20190061884A1|2019-02-28|

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FR3048409B1|2018-03-23|

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EP3423345A1|2019-01-09|

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CN108698675A|2018-10-23|

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JP2019508313A|2019-03-28|

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KR101921279B1|2015-06-19|2018-11-22|프린시플 파워, 인코포레이티드|Floating Wind Turbine Platform Structures for Optimum Delivery of Wave and Wind Load|

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US10151294B2|2016-06-10|2018-12-11|Zhanfei Fan|Buoyant housing device enabling large-scale power extraction from fluid current|KR101840649B1|2017-11-20|2018-03-21|알렌 주식회사|A buoyant system of floating electricity generation platform|

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WO2021254786A1|2020-06-19|2021-12-23|Cefront Technology As|Floating support structure with a stable vertical floating position for connection to a horizontally positioned tower of a wind turbine|

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CN111942528B|2020-08-13|2021-07-13|苏州普轮电子科技有限公司|Marine wind power of haulage rope fixed is with preventing unrestrained base|

法律状态:
2017-03-27| PLFP| Fee payment|Year of fee payment: 2 |

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2017-09-08| PLSC| Publication of the preliminary search report|Effective date: 20170908 |

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2018-03-28| PLFP| Fee payment|Year of fee payment: 3 |

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2020-03-26| PLFP| Fee payment|Year of fee payment: 5 |

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2021-03-26| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1651746A|FR3048409B1|2016-03-02|2016-03-02|STABILIZATION SYSTEM, ESPECIALLY FOR A FLOATING SUPPORT, WITH AT LEAST THREE LIQUID RESERVES CONNECTED THERETO|

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FR1651746|2016-03-02|FR1651746A| FR3048409B1|2016-03-02|2016-03-02|STABILIZATION SYSTEM, ESPECIALLY FOR A FLOATING SUPPORT, WITH AT LEAST THREE LIQUID RESERVES CONNECTED THERETO|

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EP17702139.1A| EP3423345A1|2016-03-02|2017-02-02|Stabilisation system, in particular for a floating support, comprising at least three interconnected liquid reserves|

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JP2018545936A| JP2019508313A|2016-03-02|2017-02-02|Stabilization system, especially for floating supports, having at least three liquid reservoirs interconnected|

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US16/081,564| US10683065B2|2016-03-02|2017-02-02|Stabilization system, in particular for a floating support, comprising at least three interconnected liquid reserves|

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PCT/EP2017/052294| WO2017148647A1|2016-03-02|2017-02-02|Stabilisation system, in particular for a floating support, comprising at least three interconnected liquid reserves|

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CN201780013665.8A| CN108698675A|2016-03-02|2017-02-02|The systems stabilisation for including at least three interconnection liquid storage devices, is especially used for the systems stabilisation of Floating support|