FR3010151A1 - DEVICE FOR PRODUCING ELECTRICITY USING THE CURRENT OF A COURSE OF WATER - Google Patents

Abstract

The invention relates to an ispositif for generating electricity using the current of a watercourse comprising a hydro-module (1), mobile in rotation about a substantially horizontal axis of rotation (2). disposed at a fixed end of said hydro-module (1), said hydro-module (1) comprising a blade arranged to be driven by said current when in the submerged position in said stream. Said hydro-module (1) further comprises a compressor (3), comprising a fixed plate relative to said hydro-module (1), a main flap mounted for rotation about an axis disposed at one of its ends between an extended position, in which its movable end is remote from said fixed plate backwards in the direction of rotation of the hydro-module, and a folded position, in which its movable end is close to said fixed plate , so that the weight of the main flap produces by gravity the folded position in the downward phase and the deployed position in the up phase, said compressor further comprising a bellows sealingly connecting said main flap to said fixed plate, and said hydro-module comprises a hose (12) allowing the air inlet and outlet of the compressor (3).

Description

Device for producing electricity using the current of a watercourse. The invention relates to the field of hydroelectric power generation. It relates more particularly to a device for producing electrical energy from the current of a river or a large river. In the field of hydroelectric power, we know dams, which require significant investment in civil engineering, and which significantly modify the environment by creating a reservoir of water, and by changing the flow of water. This can often have a negative impact on the surrounding flora and fauna.

We also know the water wheels, which do not have the same disadvantages. However, their effectiveness remains very limited. An object of the present invention is to propose a device for generating electricity from the current of a river, which requires very little, if any, investment in civil engineering, and which nevertheless produces a satisfactory amount, with satisfactory efficiency. For this purpose, the invention relates to a device for generating electricity using the current of a watercourse comprising a hydro-module, mobile in rotation about a substantially horizontal axis of rotation disposed at the level of a fixed end of said hydro-module, said hydro-module comprising a blade arranged to be driven by said current when it is in the submerged position in said stream. This device is particular in that said hydro-module further comprises a compressor, comprising a fixed plate relative to said hydro-module, a main flap mounted to rotate about an axis disposed at one of its ends, between an extended position, in which its movable end is remote from said fixed plate backwards in the direction of rotation of the hydro-module, and a folded position, in which its mobile end is in the vicinity of said fixed plate, so that the weight of the main flap produces by gravity the folded down position and the deployed position in the up phase, said compressor further comprising a bellows sealingly connecting said main flap to said fixed plate, and said hydro-module comprises a hose allowing the entry and the exit of air of the compressor. Thanks to these provisions, the compressor is folded when it must enter the water, and it is filled with air when it has to go up, which has the effect of producing an Archimedes thrust on the compressor, and therefore an acceleration of the rotation of the hydro-module. According to other features: said bellows may be of flexible vitrimer, allowing a good life of the compressor, said compressor may further comprise two lateral flaps and a shutter flap, arranged on said main flap, on the opposite side to the bellows, so as to constitute a U whose base consists of said shutter located on the side of the movable end of said main flap, thus improving the rigidity of the main flap, said main flap and / or said side flaps and / or said shutter can be in hard vitrimer, allowing a good life of the compressor, said hydro-module may further comprise a water reservoir disposed near said axis of rotation, a buoy disposed at the mobile end of said hydro-module, a a water pipe connecting said buoy to said tank and a tank tank, and said hose arranged to connect said tank tank to a tank compressor; this produces a second effect of acceleration of the hydro-module, the folding of the compressor in the descending phase then accompanied by the filling of the buoy with water, which increases the weight of the end of the hydro-module in downward phase, and the deployment of the compressor in the rising phase accompanied by the emptying of the buoy, which creates an buoyancy thrust on the buoy, either as a replacement or by adding the buoyancy thrust on the compressor, said hydro-module may comprise a stack of modules of absorbent fibers and disks, slidably disposed along a sliding rod inside said water pipe, and connected to a fixed support plate relative to said hydro-module. module, so that the stack is compressed when the mobile end of the hydromodule is located above said axis of rotation, and relaxed and able to absorb water when the mobile end of the hydro-module is located below the dud it axis of rotation; thanks to these provisions, the pile absorbs water from the buoy already before the ascent phase, and allows an early emptying of the buoy; and the buoyancy thrust on the buoy is strong from the beginning of the rise of the hydromodule, said discs may be stainless steel, each provided with a sliding orifice arranged to allow its sliding along said sliding rod, and at least one conduit arranged to allow the passage of water, giving these discs a sufficient weight, as well as a good service life, said absorbent fiber modules can be made of super absorbent synthetic fibers surrounded by a polyamide elastic fabric provided with micro-perforations, allowing good water absorption and good life, said hydro-module may include a secondary compressor, a buoy balloon disposed within said buoy, and a hose secondary connecting said buoyancy balloon to said secondary compressor; such an arrangement also makes it possible to accelerate the emptying of the buoy after its penetration into the water; this acceleration can be further increased by an extension of the main flap so as to cause its folding by the difference in speed between the hydro-module and the water flow, as soon as the extension of said extension enters water, said device may comprise at least two hydro-modules arranged diametrically opposite with respect to said axis of rotation, and the compressor of one of the hydro-modules connected to the compressor of the hydro-module diametrically opposed by said hose, so that when the one of the compressors is in the deployed position, the other is in the folded position; such arrangements allow a very simple embodiment of the device according to the invention, while enjoying the buoyancy of Archimedes on each compressor during the recovery phase out of the water. The advantage of the present invention is that one or more devices can increase the performance of hydro-modules of the device according to the invention. Other features and advantages of the invention will emerge from the following detailed description relating to an exemplary embodiment given by way of indication and not limitation. The understanding of this description will be facilitated with reference to the accompanying drawings, in which: Figure 1 shows a side view of a device according to the invention; FIG. 2 represents a pair of hydro-modules of the device of FIG. 1 according to a first embodiment; FIG. 3 represents a hydro-module of the device of FIG. 1 according to a second embodiment; FIG. 4 represents a hydro-module of the device of FIG. 1 according to a third embodiment; FIG. 5 shows a side view of a compressor of the device of FIG. 1; FIG. 6 represents a view from above of the compressor of FIG. 5; - Figures 7 and 8 show a side view of a stack of absorbent fibers and discs in a relaxed position, and in a compressed position; - Figures 9 and 10 show a top view of a module of absorbent fibers and a disk; As shown in FIGS. 1 to 10 of the attached drawing, the present invention relates to a device for generating electricity using the current of a watercourse comprising two sets of eight mobile hydro-modules 1 in rotation about a substantially horizontal axis of rotation 2 disposed at a fixed end of said hydro-modules 1. Between the two sets of eight hydro-modules 1 is disposed a support structure, having a generator 32 actuated by said axis 2. The support structure may be a floating structure 30, maintained by mooring cables 31 at the bank, a mast 33 connecting said floating structure 30 to the axis of rotation 2 and the generator 32. This option makes it possible to easily move the structure for maintenance work. It can also be a vertical cylindrical metal structure, which is supported on three horizontal cylinders which are interconnected. The three cylinders are filled with water and serve as ballasts. As a result, the entire structure descended to the bottom of the river, sliding between six large metal columns that are driven into the ground, for example to a depth of five meters. In case of flood, the ballasts are filled with air, which allows to reassemble the whole structure by sliding along the metal poles.

A mat is disposed on this structure, at the top of which is disposed the axis of rotation 2. Each hydro-module 1 may have for example a length of five meters, and comprises a compressor 3 having a plate 4 fixed relative to said hydro- module 1, a main flap 5 rotatably mounted about an axis 6 disposed at one of its ends, between an extended position, in which its movable end 7 is remote from said fixed plate 4, and a folded position, in which its movable end 7 is in the vicinity of said fixed plate 4. The compressor 3 further comprises a bellows 8 sealingly connecting said main flap 5 to said fixed plate 4. The main flap 5 can be made of hard vitrimer, and can have a length of 2 meters and a width of 0.80 meters. On the flap, on the opposite side to the bellows 8, can be disposed at its movable end 7 a shutter 9, and on both sides side flaps 10, which can also be hard vitrimer. The addition of shutter 9 and side flaps 10 improves the performance of the compressor 3. A weight 11 can be fixed under the main flap 5 at its movable end 7, to increase the effect of gravity on the main flap 5. According to a first embodiment shown in FIG. 2, an air supply hose 12 connects the two compressors 3 of two opposed hydro-modules 1. A solenoid valve 13 disposed on this hose 12 makes it possible to prevent the circulation of air between the two compressors 3 at certain phases of the cycle. A complementary flap 14 is disposed on each hydro-module 1, arranged to increase the effect of the surface current when the hydro-module 1 is immersed in water.

Each compressor 3 is in the folded position as soon as the corresponding hydro-module 1 is in descending phase, because of the weight of the main flap 5, increased if necessary by the weight 11. When the hydro-module 1 is in an ascending phase , the weight of the shutter instead causes the deployment of the compressor 3, and therefore its filling air. A very favorable effect is thus obtained, which facilitates the descent into the water of the hydro-module 1, provided with a compressor 3 folded, and promotes its rise by Archimedes thrust on the compressor 3 which is then deployed. The solenoid valve 13 can be closed during the upwelling phase of the hydro-module 1 and until the compressor 3 comes out of the water, to prevent the buoyancy of the impeller from producing the folding of the compressor 3. The solenoid valve 13 is then reopened as soon as the compressor 3 is out of the water. According to a second embodiment shown in FIG. 3, each hydro-module 1 may comprise a reservoir 15 disposed near the axis of rotation 2, and a tank 16 connected to the compressor 3 by a hose 12. It also comprises a buoy 17 disposed at the mobile end of the hydro-module 1, and connected to the reservoir 15 by a water pipe 18. Thus, when the hydro-module 1 is in a down phase, the compressor 3 folds and inflates the tank 16. From the reservoir 15 to the buoy 17. Thus the end of the hydro-module 1 becomes heavier, and facilitates the descent of the hydro-module 1. Conversely, when the hydro-module 1 begins its rising, its moving end being submerged, the compressor 3 unfolds, thus emptying the tank 16, which has the effect of drawing water from the buoy 17 to the tank 15, and empty the buoy 17. The buoy 17 being emptied of its water, is pushed up by buoyancy, in addition to Archimedean siege on the deployed compressor 3. As in the embodiment of FIG. 2, a solenoid valve 13 makes it possible to close and open the hose 12 at appropriate times to maximize the advantage gained from the buoyancy. Optionally, a stack 19 of modules 20 of absorbent fibers and disks 21 may be disposed inside the water pipe 18, sliding along a sliding rod 22, and attached at one end to a support plate 23 fixed. Thus when the mobile end of the hydro-module 1 is up, the battery 19 is compressed (see Fig. 8), and does not retain water, or only very little; on the other hand, when the moving end of the hydro-module 1 is down, the battery 19 is relaxed (see Fig. 7) and the absorbent fibers can retain a quantity of water. The absorbent fiber modules 20 may be made of super absorbent synthetic fibers and delimited by a polyamide elastic fabric with micro-perforations. A sliding orifice 24 is arranged in their center, and several (4 in Fig. 9) conduits 34 for passage of water. Similarly, each disk 21 (see Fig. 10) is provided with a slide port 24 and several conduits 34 for water passage. The discs 21 and 20 modules may have for example a diameter of 20cm, and the ducts 34 for passage of water a diameter of 5cm. The discs 21 may be made of stainless steel, as well as the support plate 23. This battery 19 expands as soon as the mobile end of the hydro-module 1 is down, so well before the compressor 3 starts to deploy. The effect obtained is that the battery 19 begins to absorb water from the buoy 17 as soon as the mobile end of the hydro-module 1 enters the water; thus there is a significant Archimedean thrust from the beginning of the rise of hydro-module 1.

According to a third embodiment shown in FIG. 4, the hydro-module 1 does not have a battery 19, but a secondary compressor 25, disposed on the opposite side of the hydro-module 1 relative to the compressor 3, and connected by a secondary hose 26 to a balloon buoy 27. During the rise phase of the hydro-module 1, at the same time as the deployment of the compressor 3 empties the reservoir tank 16 which fills the tank 15 with water, the folding of the secondary compressor 25 inflates the buoyancy balloon 27, and participates in the effect of flushing the water from the buoy 17 to the tank 15. Conversely, during the descent phase of the hydro-module 1, at the same time as the folding of the compressor 3 inflates tank 16, which empties the water reservoir 15 in favor of the buoy 17, the deployment of the secondary compressor 25 empties the buoy balloon 27, and participates in the flushing effect of the water from the reservoir 15 to the buoy 17. The compressor 3 and secondary compressor 25 can be arranged on the hydromo dule 1 so as never to be submerged under water. It can then provide an extension 28 of the main flaps so that their end enters the water when the hydro-module 1 is immersed in water. An effect of acceleration of deployment / refolding of the two compressors 3, 25 is thus obtained because the linear speed of the hydro-module 1 is greater than the speed of the water. A float 29 may be disposed at the movable end 7 of the main flap 5 of the compressor 3, causing a force upward of the hydro-module 1 as soon as the float 29 is immersed. The advantage of the present invention lies in particular in that Although the invention has been described with respect to a particular embodiment, it is understood that it is in no way limited and that it can be make various modifications of shapes, materials and combinations of these various elements without departing from the scope of the invention. Nomenclature 1. hydro-module 2. axis of rotation 30 3. compressor 4. fixed plate 5. main flap 6. axis of rotation 7. moving end of the main flap 8. bellows 9. flap shutter 10. side flaps 11. weight 12 hose 13. solenoid valve 14. additional flap 15. tank 16. tank bladder 17. buoy 18. water pipe 19. battery 20. absorbent fiber module 15 21. discs 22. slide rod 23. support plate 24. sliding port 25. secondary compressor 20 26. secondary hose 27. buoy balloon 28. extension 29. float 30. floating structure 25 31. mooring cables 32. generator 33. mast 34. line A: direction of rotation of hydro -modules 30 B: current direction

Claims (10)

REVENDICATIONS1. Device for producing electricity using the current of a watercourse comprising a hydro-module (1), mobile in rotation about a substantially horizontal axis of rotation (2) arranged at one end fixed said hydro-module (1), said hydro-module (1) comprising a blade arranged to be driven by said current when in the submerged position in said stream, characterized in that said hydro-module ( 1) further comprises a compressor (3), comprising a fixed plate (4) relative to said hydro-module (1), a main flap (5) rotatably mounted about an axis disposed at one of its ends, between an extended position, in which its movable end (7) is moved away from said fixed plate (4) in the direction of rotation of the hydro-module (1), and a folded position, in which its movable end (7) is close to said fixed plate (4), so that the weight of the main flap ( 5) produces by gravity the folded down position and the deployed position in the up phase, said compressor (3) further comprising a bellows (8) sealingly connecting said main flap (5) to said fixed plate (4), and said hydro-module (1) comprises a hose (12) for the entry and exit of air from the compressor (3). 2. Device according to the preceding claim, wherein said bellows (8) is in flexible vitrimer. 3. Device according to one of the preceding claims, wherein said compressor (3) further comprises two side flaps (10) and a shutter (9), arranged on said main flap (5), on the opposite side to the bellows ( 8), so as to form a U whose base consists of said shutter flap (9) located on the side of the movable end (7) of said main flap (5). 4. Device according to one of the preceding claims, wherein said main flap (5) and / or said side flaps (10) and / or said shutter flap (9) is hard vitrimer. 5. Device according to one of the preceding claims, wherein said hydro-module (1) further comprises a reservoir (15) of water disposed near said axis of rotation (2), a buoy (17) disposed at at the movable end of said hydromodule (1), a water pipe (18) connecting said buoy (17) to said tank (15) and a tank bucket (16), and said hose (12) is arranged to connect said tank bladder (16) to said compressor (3). 6. Device according to the preceding claim, wherein said hydro-module (1) comprises a stack (19) of modules (20) of absorbent fibers and disks (21), slidably disposed along a sliding rod (22). ) inside said water pipe (18), and connected to a support plate (23) fixed with respect to said hydromodule (1), so that the cell (19) is compressed when the mobile end of the hydro-module (1) is located above said axis of rotation (2), and relaxed and able to absorb water when the mobile end of the hydro-module (1) is located below said rotation axis (2). 7. Device according to the preceding claim, wherein said discs (21) are stainless steel, each provided with a sliding orifice (24) arranged to allow its sliding along said slide rod (22), and from at least one conduit (34) arranged to allow the passage of water. 8. Device according to one of claims 6 or 7, wherein said modules (20) of absorbent fibers are super absorbent synthetic fibers surrounded by a polyamide elastic fabric provided with micro-perforations. 9. Device according to claim 5, wherein said hydro-module (1) comprises a secondary compressor (25), a buoy balloon (27) disposed inside said buoy (17), and a secondary hose (26). ) connecting said buoy balloon (27) to said secondary compressor (25). 10. Device according to one of claims 1 to 4, comprising at least two hydro-modules (1) arranged diametrically opposite with respect to said axis of rotation (2), and the compressor (3) of one of the hydro-modules (1) is connected to the compressor (3) of the hydro-module (1) diametrically opposed by said hose (12), so that when one of the compressors (3) is in the deployed position, the other is in folded position.