FR2897118A1 - DEVICE FOR CONVERTING THE SWITCHING AND / OR OSCILLATIONS OF A MASS OF A LIQUID IN WHICH IT IS AT LEAST PARTIALLY IMMERSE TO A USEABLE ENERGY. - Google Patents

Abstract

The present invention relates to a device (1) for converting the undulation and / or oscillations of a mass of a liquid in which it is at least partially immersed into a usable energy characterized in that it includes at least: a first support structure (2) of elongated shape carrying at its two opposite ends a first pair of floats (5); a second support structure (2 ') of elongated shape carrying at its two opposite ends a second pair of floats (5); a central float (6) substantially coaxial with said vertical axis; two connecting mechanisms (7, 7 ') arranged between the central float (6) and the central part of said support structures (2, 2'), these two mechanisms (7, 7 ') each comprising at least three telescopic elements (8 ) disposed substantially at a distance of 120 DEGREE from each other about said vertical axis, at least one of said telescopic elements (8) has two parts (9, 10) sliding relative to each other, connected to a converter converting the relative displacements of said parts (9, 10) into the above usable energy.

Description

The present invention relates to a device for

  converting the undulation and / or oscillations of a mass of a liquid in which it is at least partially immersed into usable energy. It applies in particular, but not exclusively, to the conversion of wave, wave and tidal energy into electrical energy. It is known that there are already devices for converting the mechanical energy of waves, waves and tide into electrical energy. These devices generally comprise at least one float connected to a rack which extends in a substantially vertical axis, the latter 20 cooperating with gear mechanisms connected to a drive shaft. In this way, the vertical movement of the rack which results from the movement of the waves is transformed into a rotational movement by said gear mechanisms and then it is communicated to the drive shaft which can be connected to an electric generator. Nevertheless, these devices require the use of means to convert the movement of the float into a gold rotational movement, the elements constituting these means (such as for example gear mechanisms) are subject to rapid wear and corrosion in particular due to friction and the characteristics of the marine environment, which requires significant maintenance efforts. In addition, the support of the rack 1 must be firmly connected to the seabed, which generally involves tedious and expensive work of assembly of the lower end of said support to said bottom sea.

  The object of the invention is therefore more particularly to eliminate these disadvantages. For this purpose, it proposes a device which makes it possible to convert the movements of a mass of a liquid into a usable energy without it being necessary to use intermediate conversion means whose function is, at first, to transform the movement of a float in a rotational movement and then to communicate it to specific means of conversion of mechanical energy. Thus, the present invention relates to a device for converting the undulation and / or oscillations of a mass of a liquid in which it is at least partially immersed into usable energy, characterized in that comprises at least: a first support structure, of elongate shape, carrying at its two opposite ends, a first pair of floats; A second support structure, of elongate shape, carrying at its two opposite ends, a second pair of floats, this second structure extending substantially perpendicular to the first structure so that the central regions of the two structures are located substantially on a same vertical axis; A central float substantially coaxial with said vertical axis; Two connecting mechanisms arranged between the central float and the central part of said support structures, these two mechanisms each comprising at least three telescopic elements arranged substantially at 120 from each other about said vertical axis and hinged on the one hand, at one of their ends, to the central region of a corresponding structure and secondly, at their other end, to a substantially peripheral region of said central float.

  At least one of said telescopic elements comprises two sliding parts relative to each other, connected to a converter ensuring the conversion of the relative displacements of said parts to the aforesaid usable energy. The two sliding parts relative to each other may be a cylinder hydraulic piston rod assembly or a driving rod-body assembly of a linear electric generator.

  The converter may be an electric generator that can operate alternately in one direction or the other.

  In this way, the movements of said support structures which result from the action of the swell and / or the waves and / or the tide, cause relative movement of said two parts sliding relative to each other, movement is then transmitted to the (x) converter (s) of mechanical energy ie, for example, generator (s) of the aforesaid type.

  Thus, the device according to the invention makes it possible to directly communicate the movement of at least one float to said two parts sliding relative to one another and thus to said converter, which makes it possible to dispense with the use of a support vertical, such as a rack support, and gear mechanisms.

  According to an alternative embodiment of the invention, each of said support structures may have substantially the shape of a rhombus.

  Advantageously, the devices according to the invention can be connected in a network, which makes it possible to increase the production of usable energy and to average the total available energy from the energies produced by the devices individually. of the invention will be described hereinafter, by way of nonlimiting examples, with reference to the accompanying drawings, in which: FIG. 1 is a schematic representation in perspective of the

  device according to the invention where said support structures present

  substantially the shape of a rhombus. Figure 2 is a schematic representation of a hydraulic circuit included in a device according to an alternative embodiment of the invention. Figure 3 is a schematic perspective view of devices according to the invention networked.

  FIG. 4 is a diagrammatic representation in perspective of devices according to the invention in a network where the support structure comprises rigid reinforcement assemblies. Figure 5 is a schematic side view of devices according to the invention networked. By way of nonlimiting example, as illustrated in FIG. 1, the device according to the invention 1 comprises: at least two support structures 2, 2 ', interlaced, of elongated shape and which extend substantially perpendicularly relative to each other so that the central regions of the two structures 2, 2 'are located substantially on the same vertical axis; each of the support structures 2, 2 'comprising:

  o an upper part 3, 3 'and a lower part 4, 4' disposed respectively substantially in the same vertical plane, the upper part 3 of a first support structure 2 passing through the part of the plane delimited by the upper parts 3 'and lower 4 'of the second support structure 2';

  at least one float 5 disposed at each of their ends; At least one central float 6 which is substantially coaxial with said vertical axis and which is disposed between the upper part 3 of said first support structure 2 and the lower part 4 'of the second support structure 2'; At least two connecting mechanisms 7, 7 'respectively arranged between the central float 6 and the central part of one of said support structures 2, 2', each of these connecting mechanisms 7, 7 'comprises at least three telescopic elements 8 disposed substantially at 120 from each other about said vertical axis and articulated on the one hand, by one of their ends, to the central region of a corresponding support structure 2, 2 'and on the other hand at their other end to a substantially peripheral region of said central float 6. At least one of said telescopic elements 8 has two parts 9, 10 sliding relative to each other which are connected to a conversion converter. relative displacements of said portions 9, 10 into usable energy. According to the alternative embodiment of the invention, as shown in Figure 1, each of said support structures 2, 2 'may have substantially the shape of a rhombus. In addition, in the present case, the upper parts 3, 3 'and lower 4, 4' of the support structures 2, 2 'each consist of two subparts connected to each other which are themselves constituted each of two arms 12, 12 'substantially parallel, the free end of each of these arms 12, 12' being attached to an end float 5. The upper parts 3, 3 'and the lower parts 4, 4' form respectively according to another embodiment of the invention, as illustrated in FIG. 1, the lower part 4 of the first support structure 2 as well as the upper part 3 'of the second support structure 2 'can each comprise in their central region, a plate or a junction frame 13 which allows in particular to connect their two sub-respective parts. The set of end floats 5 preferably has a volume substantially equal to that of the central float 6.

  Advantageously, the lower part of the various floats 5, 6 preferably has a convex shape in order to optimize their reactivity to the movements of the fluid in which the device 1 is immersed. Each of the floats 5, 6 may be ballasted in particular by a material preferably having a low density or for example by an inflatable bladder, the rest of the volume being able to be filled with seawater. Each of the different floats 5, 6 preferably has a density substantially equal to / Z. According to an alternative embodiment of the invention, the two parts 9, 10 sliding relative to each other may be a driving rod assembly 10 - body of a linear electric generator 9 of conventional type. Thus, under the effect of the action of the swell and / or waves and / or tide, said drive rod 10 will slide relative to said generator body

  25 linear electric 9 and drive a movable element (not shown) which acts as an inductor (the armature remains fixed), which allows to produce electrical energy. According to another alternative embodiment of the invention, the two parts 9, 10 sliding relative to each other may be a hydraulic piston rod assembly 10 '- cylinder 9'.

  Thus, by way of example, as illustrated in FIG. 2, the device according to the invention 1 may comprise a hydraulic circuit 14 which comprises: a hydraulic piston rod 10 'sliding in a cylinder 9', this last comprising a hydraulic fluid; A high-pressure pneumatic reservoir 15 connected to said cylinder 9 'by exhaust pipes 16 and 35 respectively connected to the substantially lower and upper part of the cylinder 9'; A hydraulic motor 11 connected to the pneumatic reservoir 15 via an exhaust manifold 17; • a buffer tank 18 connected to the hydraulic motor 11 and the cylinder 9 'respectively by a discharge pipe 19 and by supply pipes 20 and 36 respectively connected to the substantially lower and upper portion of the cylinder 9'.

  Each tubing 16, 35, 17, 19, 20, 36 of said hydraulic circuit 14 comprises a non-return valve 21, which can be automated, in order to prevent backflow of the downstream hydraulic fluid upstream.

  Preferably, in order to preserve them in particular from corrosion, the elements of said hydraulic circuit 14 (with the exception of the hydraulic piston rod 10 'and the cylinder 9') are included in the central float 6. In this way, under the effect of the movements of the fluid, the hydraulic piston rod 10 'will slide in said cylinder 9'. The lowering of the piston compresses the hydraulic fluid included in the cylinder 9 'so, when the pressure exerted by the piston exceeds the operating pressure of the high pressure reservoir 15, the said fluid is expelled through the exhaust pipe 16 equipped from a nonreturn valve 21 to the high pressure pneumatic reservoir 15. The flow of hydraulic fluid into the pneumatic reservoir 15 is carried out until the piston rod assembly 10 '- piston 2897118 -8 - in the compressed position. The hydraulic motor 11 is then fed through a pipe 17 provided with a non-return valve 21. The leakage flow of the hydraulic motor 11 is discharged through the discharge pipe 19 provided with a non-return valve 21 towards the buffer tank 18, at low pressure or at

  5 atmospheric pressure. This buffer tank 18 completes the cycle by feeding said cylinder 9 'through the supply pipe 20 provided with a non-return valve 21. The raising of the piston, under the effect of the movements of the sea, allows

  10 to expel the hydraulic fluid through the exhaust pipe 35 equipped with a nonreturn valve 21, to the pneumatic reservoir 15. At the end of the cycle, the buffer tank 18 feeds said cylinder 9 'through the supply pipe 36 provided with a non-return valve 21. The device according to the invention 1 may comprise an electronic control device (not shown) making it possible to control, in particular, the electric generator (s) linear (s) 9 or the hydraulic motor (s) 11 in real time and thus to manage the production of energy according to the needs. Advantageously, at least one float 5, 6 of the device according to the invention 1 may comprise ballasting compartments (not shown), the filling of which may be controlled upon the announcement of a major storm, in order to allow its diving and thus avoid being subjected to excessive movement under the action of a particular swell

  25 strong; filling and emptying said ballasting compartments that can be controlled by said electronic control device. If the floats 5, 6 comprise an inflatable bladder, a simple deflation of the latter can drive all by the bottom to ensure its protection in case of storm. Advantageously, the device according to the invention 1 can be moored to a mooring body. Several devices according to the invention 1 can be grouped together in a network in order to increase the production of usable energy. Thus, by way of example, as shown in FIG. 3, the assembly 22 that results from this networking comprises: a support structure 23 which comprises: lower arms 24 substantially parallel to each other and spaced apart preferably at substantially regular intervals;

  o upper arms 25 substantially parallel to each other and arranged transversely to the axis of said lower arms 24 and preferably at substantially regular intervals; Floats 26 of the above-mentioned type, arranged between the upper and lower arms 24 preferably at substantially regular intervals, each of the floats 26 being connected to the support structure 23 by two corresponding connecting mechanisms 27; • a set of pairs of connecting mechanisms 27, each of these pairs of connecting mechanisms 27 being disposed between a float 26 and the support structure 23; these mechanisms 27 each comprise at least three telescopic elements 8 arranged substantially at 120 from each other about the vertical axis of said float 26 and articulated on the one hand, by one of their ends, to the lower arms 24 or at the upper arms 25 and at the other end, at a substantially peripheral region of said float 26. At least one of said telescopic elements 8 comprises two parts 9, 10 which slide relative to one another. other, and which are connected to a converter 2897118 - 10 - converting the relative displacements of said parts 9, 10 into a usable energy. Thus, the two parts 9, 10 sliding relative to each other can be

  A hydraulic piston rod assembly 10 '- cylinder 9' or a drive rod assembly 10 - the body of a linear electrical generator 9 of the aforesaid type. Advantageously, as illustrated in FIG. 4, in order to reinforce the strength of the assembly 22, the support structure 23 may comprise: a first set of rigid reinforcements 30 which are substantially parallel to one another and spaced apart preferably at substantially regular intervals; A second set of rigid armatures 31 which are substantially

  15 parallel to each other and arranged transversely to the axis of the armatures of the first set 30, preferably at substantially regular intervals. Each of said armatures 30, 31 comprises two frames 32 substantially parallel to each other and connected at substantially regular intervals by a connecting element 33 which may advantageously take the form of said joining plate or frame 13, these joining elements 13, 33 being respectively disposed at the lower end of the first set of frames 30 and at the upper end of the second set of frames 31.

25

  The armatures 30, 31 are arranged in such a way that the upper part of the first set of rigid armatures 30 passes through the parts of the plane delimited by the armatures of the second set of rigid armatures 31, the armatures 30, 31 being disposed of in such a way that each float 26 is coaxial with the vertical axis of a joint member 33 of an armature of the first assembly 30 and a joint member 33 of an armature of the second set 31. The telescopic elements 8 of the connecting mechanisms 27 are articulated

  On the one hand, at one of their ends, to said joining element 33 of a frame of the first set 30 or to said connecting element 33 of a frame of the second set 31 and secondly, by their other end at a substantially peripheral region of said float 26.

Advantageously, as shown in FIG. 5, the length of the support structure 23 may be relatively long in order to be equal to or greater than the wavelength of most of the waves and thus to make the most of its sound. amplitude.

Claims (12)

claims   1. Device (1) for converting the undulation and / or oscillations of a mass of a liquid in which it is at least partially immersed into usable energy, characterized in that it comprises at least A first support structure (2), of elongated shape, carrying at its two opposite ends, a first pair of floats (5); A second support structure (2 '), of elongate shape, carrying at its two opposite ends, a second pair of floats (5), this second structure (2') extending substantially perpendicularly to the first structure (2) such that the central regions of the two structures (2, 2 ') are located substantially on the same vertical axis; A central float (6) substantially coaxial with said vertical axis; Two connecting mechanisms (7, 7 ') arranged between the central float (6) and the central part of said support structures (2, 2'), these two mechanisms (7, 7 ') each comprising at least three telescopic elements ( 8) disposed substantially at 120 from each other about said vertical axis and articulated on the one hand, by one of their ends, to the central region of a corresponding structure (2, 2 ') and on the other hand, at their other end, to a substantially peripheral region of said central float (6); at least one of said telescopic elements (8) comprises two parts (9, 10) sliding relative to each other, connected to a converter ensuring the conversion of the relative displacements of said parts (9, 10) in the said usable energy.   2. Device (1) according to claim 1, characterized in that it comprises: • at least two support structures (2, 2 '), interlaced, elongated and extending substantially perpendicularly one with respect to the other such that the central regions of the two structures (2, 2 ') are located substantially on the same vertical axis; each of the support structures (2, 2 ') comprising: o an upper part (3, 3') and a lower part (4, 4 ') arranged substantially in the same vertical plane, the upper part (3) of a first support structure (2) passing through the portion of the plane delimited by the upper (3 ') and lower (4') portions of the second support structure (2 '); at least one float (5) disposed at each of their ends; At least one central float (6) which is substantially coaxial with said vertical axis and which is arranged between the upper part (3) of said first support structure (2) and the lower part (4 ') of the second support structure (2). '); At least two connecting mechanisms (7, 7 ') respectively arranged between the central float (6) and the central part of one of said support structures (2, 2'), each of these connecting mechanisms (7, 7 ') ') comprises at least three telescopic elements (8) arranged substantially at 120 from each other about said vertical axis and articulated on the one hand, by one of their ends, to the central region of a support structure corresponding (2, 2 ') and secondly, at their other end, to a substantially peripheral region of said central float (6); at least one of said telescopic elements (8) comprises two parts (9, 10) sliding relative to each other which are connected to a converter ensuring the conversion of the relative displacements of said parts (9, 10) into a usable energy. 2897118 -14-   3. Device (1) according to claim 2, characterized in that each of said support structures (2, 2 ') has substantially the shape of a rhombus and / or the upper parts (3, 3') and lower (4, 4 ') support structures (2, 2') each consist of two sub-parts connected to each other which are themselves each consisting of two arms (12, 12 ') substantially parallel, the free end of each of these arms (12, 12 ') being attached to an end float (5), and / or the lower part (4) of the first support structure (2) and the upper part (3'). ) of the second support structure (2 ') comprise in their central region, a plate or a connecting frame (13) which allows in particular to connect their two sub-respective parts.   4. Device (1) according to one of the preceding claims, characterized in that the two parts (9, 10) sliding relative to each other are a drive rod assembly (10) - body d a linear electric generator (9) of conventional type.   5. Device (1) according to one of claims 1 to 3, characterized in that the two parts (9, 10) sliding relative to each other are a hydraulic piston rod assembly (10 ') cylinder (9 ').   6. Device (1) according to claim 5, characterized in that it comprises a hydraulic circuit (14) which comprises: • a hydraulic piston rod (10 ') sliding in a cylinder (9'), the latter comprising a hydraulic fluid; A high pressure pneumatic reservoir (15) connected to said cylinder (9 ') by exhaust pipes (16) and (35) connected respectively to the substantially lower and upper part of the cylinder (9'); A hydraulic motor (11) connected to the pneumatic reservoir (15) via an exhaust manifold (17); 2897118 - 15 - • a buffer tank (18) connected to the hydraulic motor (11) and to the cylinder (9 ') respectively via an evacuation pipe (19) and connected supply pipes (20) and (36) respectively to the substantially lower and upper portion of the cylinder (9 '). Each tubing (16, 17, 35, 19, 20, 36) of said hydraulic circuit (14) comprises a non-returnable valve (21), which can be automated, in order to prevent backflow of the downstream hydraulic fluid upstream. .   7. Device (1) according to claim 6, characterized in that the elements of said hydraulic circuit (14), with the exception of the hydraulic piston rod (10 ') and the cylinder (9'), are included in the central float (6).   8. Device (1) according to one of claims 4 to 7, characterized in that it comprises an electronic control device for controlling in particular the (s) electric generator (s) linear (s) (s) (s) ( 9) or the hydraulic motor (s) (1l) in real time and thus to manage the production of energy according to the needs. 20   9. Device (1) according to one of the preceding claims, characterized in that at least one float (5, 6) may comprise ballast compartments, the filling can be ordered at the announcement of a major storm filling and emptying said ballast compartments controllable by said electronic control device.   10. Device (1) according to one of the preceding claims, characterized in that several devices (1) are grouped in a network. 2897118 16 -   11. Device (1) according to claim 10, characterized in that the assembly (22) resulting from this networking comprises: • a support structure (23) which comprises: 5 o substantially parallel lower arms (24) between them ; o upper arms (25) substantially parallel to each other and arranged transversely to the axis of said lower arms (24); Floats (26) of the aforesaid type, arranged between the upper (25) and lower (24) arms, each of the floats (26) being connected to the support structure (23) by two corresponding connecting mechanisms (27); A set of pairs of link mechanisms (27), each of these pairs of link mechanisms (27) being disposed between a float (26) and the support structure (23); these mechanisms (27) each comprise at least three telescopic elements (8) arranged substantially at 120 from each other about the vertical axis of said float (26) and articulated on the one hand by one of their ends, the lower arms (24) or the upper arms (25) and secondly, at their other end, to a substantially peripheral region of said float (26); At least one of said telescopic elements (8) has two parts (9, 10) which slide relative to one another and which are connected to a converter for converting relative displacements of said parts (9 , 10) into usable energy. 25   12. Device (1) according to claim 11, characterized in that the support structure (23) comprises: • a first set of rigid reinforcements (30) which are substantially parallel to each other • a second set of rigid reinforcements (31) ) which are substantially parallel to each other and arranged transversely to the axis of the frames of the first set (30); Each of said armatures (30, 31) comprises two frames (32) substantially parallel to each other and connected at substantially regular intervals by a connecting element (33), these connecting elements (33) being respectively disposed at the lower end of the first set of frames (30) and at the upper end of the second set of frames (31); the reinforcements (30, 31) are arranged in such a way that the upper part of the first set of rigid reinforcements (30) passes through the parts of the plane delimited by the reinforcements of the second set of rigid reinforcements (31), the reinforcements (30, 31) being arranged in such a manner that each float (26) is coaxial with the vertical axis of a joint member (33) of a frame of the first set (30) and an element joining (33) an armature of the second set (31); the telescopic elements (8) of the connecting mechanisms (27) are articulated on the one hand, by one of their ends, to said connecting element (33) of a reinforcement of the first set (30) or to said element of 15 junction (33) of an armature of the second assembly (31) and secondly, at their other end, to a substantially peripheral region of said float (26).