FR3028297A1 - HYDROELECTRIC DEVICE USING CURRENT OF A COURSE OF WATER - Google Patents

Abstract

The invention relates to a device (1) hydroelectric comprising: - a generator generating electrical energy from rotational kinetic energy of a horizontal axis of rotation (2) maintained by at least one adapted bearing; - A hub (3) rotatably mounted on said axis of rotation (2). This device is characterized in that said hub (3) carries at least n hydro-modules (4), n being greater than or equal to 2, preferably also distributed around said hub (3), each hydro-module (4) comprising: at least a first compressible reservoir (5) located at a radial distance L from the axis of rotation (2); at least one second reservoir (7) in hydraulic communication with said first reservoir (5) and at a distance 1 where 1 is less than L; - Compression means of said first reservoir (5) for repelling a fluid (6) contained therein towards said second reservoir (7).

Description

Hydroelectric device 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 overcome the drawbacks of the prior art and to propose a device for generating renewable electricity from the current of a river or river, which requires very little, or not at all , investment in civil engineering, and which nevertheless produces a satisfactory amount of electricity, with satisfactory efficiency. In addition, it promotes the reoxygenation of water in the watercourse. For this purpose, the invention relates to a hydroelectric device comprising: - a generator generating electrical energy from rotational kinetic energy of a horizontal axis of rotation maintained by at least one adapted bearing; a hub rotatably mounted on said axis of rotation; characterized in that said hub carries at least n hydro-modules, n being greater than or equal to 2, preferably also distributed around said hub, each hydro-module comprising: - at least a first compressible reservoir located at a radial distance L of the 'rotation axis ; at least one second reservoir in hydraulic communication with said first reservoir and at a distance 1 where 1 is less than L; means for compressing said first reservoir to push a fluid contained therein towards said second reservoir.

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 an overview of a device according to one embodiment of the invention; FIG. 2 represents a front view of a hydro-module of the device of FIG. 1; Figure 3 shows a side view of a hydro-module of the device of Figure 1 in two different configurations; FIG. 4 represents a side view of a hydro-module of the device of FIG. 1 moving in a stream; FIGS. 5 to 8 show front views of a hydro-module of the device of FIG. 1 in different configurations during a rotation cycle; As shown in Figures 1 to 8 attached, the present invention relates to a hydroelectric device 1 comprising: - a generator generating electrical energy from rotational kinetic energy of a horizontal axis 2 of horizontal rotation maintained by at least one adapted bearing; a hub 3 rotatably mounted on said axis 2 of rotation. This device is characterized in that said hub 3 carries at least n hydro-modules 4, n being greater than or equal to 2, preferably evenly distributed around said hub 3, each hydromodule 4 comprising: at least one first compressible reservoir 5 at a radial distance L from the axis 2 of rotation; At least one second reservoir 7 in hydraulic communication with said first reservoir 5 and at a distance 1 where 1 is less than L; - Compression means of said first tank 5 to push a fluid 6 contained therein towards said second tank 7.

This hydroelectric device 1 allows the production of renewable energy without the creation of greenhouse gases. It is implantable in a stream 8 such as rivers or rivers having a minimum depth of preferably 2.50 meters and a minimum current speed of preferably one meter per second.

The hydro-modules 4 are modules that can move in a rotary movement in a direction of rotation A successively in the water and out of the water of the watercourse 8. The hydro-modules 4 are therefore rotated by the current of the stream 8 in a direction and a direction B. The first and second tanks 5 and 7 are in communication and can be in closed circuit. That is, the fluid 6 present in these tanks may not escape outside this circuit. In a particular case, the fluid 6 is a liquid, preferably water. This device 1 can be installed on a platform 9 emerged. It can be supported by a vertical cylindrical metal structure, which can be supported on horizontal cylinders interconnected, preferably three. The cylinders can thus constitute the lower base of the device 1 and rest on the bottom of the stream 8. These cylinders can be filled with water and serve as ballasts. The device 1 can also be moored on one or both banks of the watercourse 8 thus limiting investments in civil engineering.

Advantageously, the entire metal structure is lowered to the bottom of the stream 8, sliding between different large posts which are driven into the ground to a sufficient depth, for example five meters. Thus, in case of flood, the ballast can be filled with air, which allows to reassemble the entire structure by sliding along the poles.

Preferentially, the platform 9 is mounted on several floating structures, for example three. These can be moored to the bank of the stream 8 with the aid of cables 10. This technical option makes it possible to easily move the device 1 for maintenance work. According to a preferred embodiment, said hydro-modules 4 comprise at least one flap 11 in rotation about an axis 110 parallel to the plane in which the rotation of said hub 3 is inscribed, preferably two flaps 11 are present. The flaps 11 can rotate in two opposite directions C1 and C2. This rotation of the flaps 11 allows the compression of the first tanks 5 to drive the fluid 6 they contain to the second tanks 7. This rotation also allows the filling of the first tanks 5 by the fluid 6 from the second tanks 7. According to a advantageous embodiment, said hydro-modules 4 are similar to blades extending substantially radially relative to the axis 2 of rotation of said hub 3. This arrangement allows to balance the device 1 and also allows an alternation of the presence of hydro-modules 4 in the water or out of the water.

Preferably, said hydro-modules 4 comprise a leading edge 40 at the front with reference to the direction of rotation of said hub 3, preferably, said leading edge 40 is in the form of a double bevel. The leading edge 40, and preferably the double bevel shape, allows easier penetration into the water of each hydro-module 4.

Advantageously, said second reservoir 7 comprises a ventilation duct 12, preferably closed by a valve and / or an air permeable and impermeable membrane. This ventilation duct allows the filling and emptying of the second reservoirs 7 while avoiding an overpressure or a vacuum of air in the reservoirs 7 which would prevent the flow of fluid 6 between the first and second reservoirs 5 and 7. of particular embodiment, said first tank 5 is formed inter alia by at least said flap 11 and a bellows 111, said bellows 111 being preferably made of flexible polymer such as flexible vitrimer and said flap preferably being made of rigid polymer such as vitrimer rigid. The bellows 111 can be connected to at least one flap 11. During the rotation of the flaps 11, the first tank 5 is filled or emptied of fluid 6. The bellows 111 compresses or decompresses, thereby compressing or decompressing the first one. tank 5. According to another particular embodiment, said hydraulic communication is provided by a feed conduit 13, preferably, said feed conduit 13 comprises at least one solenoid valve 14, more preferably a guillotine solenoid valve. This duct 13 thus allows easy transfer between the first and second tanks 5 and 7. The solenoid valve 14 stops the transfer of liquid from the first tank 5 to the second tank 7. This solenoid valve 14 is useful when setting up of the device 1 on the watercourse 8 or during maintenance operations. Advantageously, said hydro-modules 4 comprise a skirt 41 of protection. The protective skirt 41 makes it possible to damp the shock that the tank 5 must undergo when it enters the water of the watercourse 8. Preferably, said hydro-modules 4 are carried by bearing or floating structures. The supporting structures 15 serve to stiffen the device 1 and to keep the first and second tanks 5 and 7 at the distances required for the proper functioning of the invention. According to yet another embodiment, said hydro-modules 4 are positioned on said bearing structures 15 radially and in diametrically opposed pairs, preferably in the number of eight said pairs. The provision in diametrically opposite pairs makes it possible to balance the device 1 for its proper functioning. The operation of a particular embodiment can be described as follows. According to FIG. 2, the solenoid valves 14 are open to allow the cycles of rotation of the hydro-modules 4. The fluid 6 present in the second tank 7 can flow along the supply duct 13 and reach the first tank 5 of The hydro-module 4. Figures 5 to 7 show a complete cycle of rotation of hydro-modules 4 in and out of the stream 8. Figure 5 shows the hydro-module 4 before its entry into the 8. Due to the rotation in the direction A, the fluid 6 contained in the second tank 7 is progressively transferred into the first tank 5 via the supply duct 13. From the air can also enter the second tank 7 via the ventilation duct 12 to allow the discharge of fluid 6 out of the second tank 7. Figure 6 shows the hydro-module 4 during its passage through the water of the stream 8.

The first tank 5 is filled with fluid 6, the second tank 7, was empty but begins to fill with fluid 6 by compression of the first tank 5 by the surrounding hydrostatic pressure and hydrodynamic D (see Figure 4). In addition, when the flaps 11 are folded, the stream water 8 between the flaps 11 is expelled in the same direction but in the opposite direction E to the rotational movement A thereby generating a propulsion movement by reaction. FIG. 7 represents the hydro-module 4 before it leaves the water of the stream 8. The first reservoir 5 is almost empty while the second reservoir 7 is almost full. Figure 8 shows the hydro-module 4 during its passage out of the water stream 8. The first tank 5 is completely empty while the second tank 7 is completely filled. A new rotation cycle can thus start.15 Nomenclature 1. device 2. axis of rotation 3. hub 4. hydro-module 5. first reservoir 6. fluid 7. second reservoir 8. watercourse 10 9. platform 10. cables 11. flaps 12. air duct 13. supply duct 15 14. solenoid valve 15. supporting structure 16. mooring cables 40. leading edge 41. protective skirt 20 110. parallel axis 111. bellows A : direction of rotation of hydro-modules B: direction and direction of current Cl and C2: two opposite directions 25 D: hydrodynamic screen

Claims (10)

REVENDICATIONS1. Hydroelectric device (1) comprising: - a generator generating electrical energy from rotational kinetic energy of a horizontal axis of rotation (2) maintained by at least one adapted bearing; - A hub (3) rotatably mounted on said axis of rotation (2); characterized in that said hub (3) carries at least n hydro-modules (4), n being greater than or equal to 2, preferably evenly distributed around said hub (3), each hydro-module (4) comprising: - at at least one first compressible reservoir (5) located at a radial distance L from the axis of rotation (2); at least one second reservoir (7) in hydraulic communication with said first reservoir (5) and at a distance 1 where 1 is less than L; - Compression means of said first reservoir (5) for repelling a fluid (6) contained therein towards said second reservoir (7). 2. Device (1) hydroelectric according to claim 1 characterized in that said hydro-modules (4) comprise at least one flap (11) in rotation about an axis parallel (110) to the plane of rotation of said hub (3) , preferably two flaps (11). 20 3. Device (1) hydroelectric according to any one of the preceding claims characterized in that said hydro-modules (4) are comparable to blades extending substantially radially relative to the axis of rotation (2) of said hub (3). 4. Device (1) hydroelectric according to any one of the preceding claims characterized in that said hydro-modules (4) comprise a leading edge (40) at the front with reference to the direction of rotation of said hub (3) preferably, said leading edge (40) is in the shape of a double bevel. 5. Device (1) hydroelectric according to any one of the preceding claims characterized in that said second reservoir (7) comprises a ventilation duct (12), preferably closed by a valve and / or a membrane permeable to air and waterproof. 6. Device (1) hydroelectric according to any one of claims 2 to 5 characterized in that said first reservoir (5) is formed inter alia by at least said flap (11) and a bellows (111), said bellows (111 ) preferably being made of flexible polymer such as flexible vitrimer and said flap is preferably made of rigid polymer such as rigid vitrimer. 7. Device (1) hydroelectric according to any preceding claim characterized in that said hydraulic communication is provided by a supply conduit (13), preferably, said supply conduit comprises at least one solenoid valve (14), preferentially still a solenoid valve with guillotine. 8. Device (1) hydroelectric according to any one of the preceding claims characterized in that said hydro-modules (4) comprise a skirt (41) protection. 9. Device (1) hydroelectric according to any one of the preceding claims characterized in that said hydro-modules (4) are carried by bearing structures (15) or floating. 10. Device (1) hydroelectric according to the preceding claim characterized in that said hydro-modules (4) are positioned on said bearing structures (15) 20 radially and in pairs diametrically opposed, preferably to the number of eight said pairs.