• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to an installation for producing electricity using a hydraulic pressure using the water available in valleys and mountains, said installation comprising a hydraulic primary system (20) having reservoir means (21) for sensing water. water at high altitude, and forced pipe means (22) for transporting this water captured at hundreds of meters lower under very high pressure. It comprises: a primary system (20), a secondary system (56) and a rotary element (55). The installation comprises a plurality of buckets (54) fixed to the rotary element (55), a reserve (47) of a fluid, the action of the hydraulic cylinder (33) being able to recover the fluid from the reserve , and to pump (45) this fluid at the top of the pylon (46) from which it is able to flow into the buckets (54) of the rotary element (55), which causes a rotational movement of the a rotating element (55) around the pinions (53), an alternator associated with a pinion (53) of the rotary element (55), said alternator being capable of triggering the production of electrical energy by the rotational movement of the rotating element (55).
    公开号:FR3054615A1
    申请号:FR1657387
    申请日:2016-07-29
    公开日:2018-02-02
    发明作者:Joseph Cariou;Cedric Cariou;Kevin Cariou;Loic Cariou;Alain Cariou
    申请人:Alain Cariou;
    IPC主号:
    专利说明:

    TECHNICAL FIELD OF THE INVENTION
    The present invention relates to an installation for producing electricity using hydraulic pressure using the water available in valleys and mountains. It applies, in particular, to the field of electricity production.
    STATE OF THE ART
    Document FR992902 is known from an assembly which produces electricity from a penstock containing water. This complex comprising a hydroelectric power station supplied by a lake located high up on the hydroelectric power station. This assembly also comprises a motor powered by a natural energy source, for example the wind, which ensures the ascent of the water used by the hydroelectric plant upstream of said hydroelectric plant.
    However, it is noted that the power supplied by the engine varies according to the wind speed, which is variable and unreliable.
    Likewise, this set reuses water to fill the reserve located at the top so that the installation works and that there is a constant level of water. The reserve located at the top and the basin at the bottom operate by alternating a filling mode and an emptying mode. When one is filled the other becomes empty. In normal operation, this assembly does not produce electricity continuously. This turbine in full operation can only produce 50% of its operating time in electricity production. The other 50% of its time when it does not produce, this set consumes electricity to raise the water in the upstream basin. This electricity must be produced by an external system.
    Due to its configuration, to run the hydroelectric plant, it is necessary to have a large volume of water available.
    OBJECT OF THE INVENTION
    The present invention aims to remedy these drawbacks.
    To this end, the present invention relates to an installation for producing electricity using hydraulic pressure using the water available in valleys and mountains, said installation comprising a primary hydraulic system having reservoir means for capturing water at high altitude, and means of penetration to transport this water collected hundreds of meters below under very high pressure; said installation being remarkable in that it comprises:
    - a primary system comprising a hydraulic cylinder to exploit this very high pressure of the water in the hydraulic primary circuit, the hydraulic cylinder being capable of using water from the hydraulic primary circuit,
    - a secondary system of a closed circuit fluid for the operation of a rotary element comprising:
    • the rotary element rotating around pinions located at the top and bottom of a pylon, • a plurality of buckets fixed to the rotary element, • a reserve of a fluid, • the action of the hydraulic cylinder being capable to recover the fluid from the reserve, and to pump this fluid at the very top of the pylon from where it is capable of pouring into the buckets of the rotary element, which causes a rotary movement of the rotary element around the pinions, • an alternator associated with a pinion of the rotary element, said alternator being capable of triggering the production of electrical energy by the rotational movement of the rotary element.
    Thanks to these provisions, the installation is capable of ensuring continuous electrical production, with low water consumption. The small amount of water corresponds to the volume of the cylinder body. When one volume of water is used in the primary circuit, ten volumes of water are moved in the secondary circuit.
    The power of the primary circuit is completely transferred, by mechanical effect in the secondary circuit which produces electricity, in deduction of the loss of energy consumed by friction in the movement of the pistons and the energy necessary for the opening and closing of valves .
    Example of low water consumption:
    - water column collected at 1000 m we have a high pressure available 100 Kg / cm2
    - a mountain source allowing a flow rate of 1 m3 of water per minute.
    - a single cylinder-pump system • cylinder piston surface of 5 cm2 • pump piston surface of 500 cm2 • pump piston / cylinder piston coefficient of 10
    - there is an equilibrium point at a first height to obtain a dead current at the top on the secondary circuit,
    - below this is a point of operation of the rotating element at a second height where there is an interesting flow rate and optimized to rotate the rotating element,
    - second height + weight of water => potential energy to be exploited.
    The rotating element allows the operation of an internal circulation turbine.
    The secondary system is waterproof, without water loss.
    The invention is advantageously implemented according to the embodiments and the variants set out below, which are to be considered individually or according to any technically effective combination.
    In one embodiment, the fluid is water.
    Water is a classic and well-known way to generate electricity.
    Turbine technology is mastered. The system is most efficient in power generation when the fluid is water.
    In one embodiment, the secondary circuit comprises at least one hydraulic pump linked to the hydraulic cylinder by integral pistons.
    Thus, the action of the hydraulic cylinder drives the hydraulic pump. Having at least one hydraulic pump allows in another mode to have two hydraulic pumps on each side of the hydraulic cylinder. Thus, a single hydraulic cylinder actuating by a single action (return movement of the cylinder piston) two hydraulic suction and pressure pumps. This results in a high pressure water saving of 50%.
    In one embodiment, the plurality of buckets is mounted at the location configured for a weir to fill the buckets with water.
    In one embodiment, the fluid is air.
    The air is lighter, no mass effect, it is transportable very long distance horizontally or vertically (can be transported at an altitude much higher than the point of capture of high pressure water).
    The air can operate turbines with an internal hydraulic circuit or high pressure compressed air.
    In one embodiment, the secondary circuit comprises at least one pump linked to the hydraulic cylinder by integral pistons.
    Thus, the action of the hydraulic cylinder drives a pump to compress air. Having at least one pump allows in another mode to have two pumps on each side of the hydraulic cylinder. Thus, a single hydraulic cylinder actuating by a single action (return of the piston of the cylinder) two suction and pressure pumps. This results in a high pressure water saving of 50%.
    In one embodiment, the plurality of buckets are mounted upside down and configured so that a compressed air intake nozzle fills the air buckets.
    In one embodiment, the hydraulic cylinder comprises a piston and means for regulating the speed of movement of the piston.
    BRIEF DESCRIPTION OF THE FIGURES
    Other advantages, aims and characteristics of the present invention emerge from the description which follows, given for explanatory purposes and in no way limiting, with reference to the appended drawings, in which:
    FIG. 1 represents a diagram of the elements of a particular embodiment of the installation for producing electricity using hydraulic pressure using the water available in valleys and mountains, object of the present invention,
    FIG. 2 represents a view of the diagram of FIG. 1 in section along the cutting axis, denoted A and represented in FIG. 1,
    FIG. 3 represents a variant of the diagram of FIG. 1 in section of the pylon,
    - Figure 4 shows the installation for producing electricity using hydraulic pressure according to another embodiment.
    DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION
    Figure 1 shows the elements of a particular embodiment of an installation for producing electricity from pressurized water using the water available in valleys and mountains.
    The installation comprises a primary system 20 composed of a high altitude water reserve 21, for example the top of a mountain. The water is directed hundreds of meters below via penstock means 22, in a high pressure water distribution tank 24. The high pressure is called HP for the rest of the description. A penstock means a hydraulic pipe, that is to say an assembly of pipes transporting pressurized water to the installation located downstream and below the tank which supplies it.
    The installation comprises a primary system 20 composed of at least one primary circuit. The installation comprises a secondary system 56 composed of a fluid in a closed circuit. In this example the fluid is water.
    An HP general circuit cut-off hydraulic valve 23 is placed above the HP water distribution tank 24 to shut down the system, allowing maintenance of the installation.
    The secondary circuit 56 can be switched off and out of the water in order to allow maintenance operations on all the components of the secondary circuit 56.
    The shutdown is effective by the general circuit cut-off valve 23 which in this case is closed. The secondary circuit can be put out of water by a drain, not shown.
    The HP water contained in the HP water distribution tank 24 is injected into the secondary system 56 using the hydraulic circuit breaker HP valve 26 of the primary system 20. The hydraulic HP circuit breaker valve 26 is located under the HP 24 water distribution tank.
    In this exemplary embodiment, there are several additional outlet points 25 for the exploitation of HP water in other installations connected in parallel.
    In a variant, not shown, there is only one exit point.
    When the hydraulic circuit breaker HP valve 26 is open, the water coming from the water distribution tank HP 24 enters a water distribution tank HP 57. On either side of the water distribution tank HP 57 has an HP valve for suction 27 and an HP valve for delivery 29.
    The HP water movements are used to move the piston 35 of the hydraulic cylinder of the primary circuit located in the body of the hydraulic cylinder HP 33 of the primary circuit. When stopped, the piston 35 of the hydraulic cylinder of the primary circuit is located in the left part (first position) of the body of the hydraulic cylinder HP 33 of the primary circuit. The piston of the pump 37 of the secondary circuit is located in the left part (first position) of the body of the hydraulic pump 34 of the secondary circuit 56.
    The secondary circuit includes a hydraulic pump linked to the hydraulic cylinder by integral pistons, the piston 35 is integral with the piston 37 by a rod of the cylinder-pump system 36.
    Below is a description of the different operating modes.
    System stopped: power on:
    When the primary system 20 is stopped, the hydraulic HP valves of the following primary circuit are closed: the HP valve for suction 27, the discharge water discharge valve 28, the HP valve for discharge 29, the suction water evacuation valve 30 and the water routing valve 32.
    The water routing valve 32 connects a conduit to the HP water distribution tank 24 The conduit is connected to the tank 47 by the non-return valve 49.
    The following primary circuit hydraulic HP valves are open: the general HP hydraulic circuit breaker valve 23, the hydraulic HP circuit breaker valve 26 and the continuous water discharge valve to nature 31.
    When the installation is put into operation, different stages take place in the primary 20 and secondary 56 systems.
    In the secondary system, the following steps take place:
    - the water injection valve 44 in the secondary system 56 closes,
    - the water suction valve 43 of the water recovery tank 42 opens.
    In the primary system, the following steps take place:
    - the discharge water discharge valve 28 closes, the HP valve for discharge 29 closes,
    - the suction water evacuation valve 30 opens,
    - the HP valve for suction 27 opens.
    Description of the suction movement:
    According to a suction movement of the primary system 20, the HP water contained in the HP water distribution tank 57 enters the circuit through the HP valve for suction 27. In an initial position (first position), the piston is located on the left of the HP 33 hydraulic cylinder body of the primary circuit. The action of the HP water entering the body of the HP hydraulic cylinder 33 of the primary circuit makes it possible to push the piston 35 of the hydraulic cylinder of the primary circuit to the right (second position).
    In a variant, not shown, means for regulating the speed of movement of the piston prevent deterioration of the piston.
    The piston 37 of the secondary circuit pump also moves to the right (second position) in the body 34 of the secondary circuit hydraulic pump to the suction-discharge reversal sensors 39.
    In a variant, the suction - discharge 39 or discharge - suction 40 reversing sensors are limit switches for the piston 35 of the hydraulic cylinder of the primary circuit or of the piston 37 of the pump of the secondary circuit. The discharge-suction sensors 40 are located in the junction formwork 38 between the pump body and the suction and discharge pipe.
    A volume of HP water fills the body of the HP 33 hydraulic cylinder of the primary circuit.
    Water is taken from the water recovery tank 42 and passes through the water suction valve from the recovery tank 43. A volume of water fills the body of the hydraulic pump 34 of the secondary circuit. .
    Description of the repression movement:
    According to a repression movement, various stages take place in the primary 20 and secondary 56 systems.
    In the secondary system, the water suction valve 43 present in the water recovery tank 42 closes.
    In the primary system, the following steps take place:
    - the HP valve for suction 27 closes
    - the suction water drain valve 30 closes,
    - the discharge water discharge valve 28 opens,
    - the HP valve for discharge 29 opens.
    According to a discharge movement, the piston 35 of the hydraulic cylinder of the primary circuit moves to the left (first position). The piston 37 of the secondary circuit pump also moves to the left (first position) in the body 34 of the secondary circuit hydraulic pump. The piston 37 of the secondary circuit pump moves to the discharge-suction reversal sensors 40.
    When the piston 37 of the secondary circuit pump goes to the left in the discharge movement, the air intake at atmospheric pressure 41 makes it possible to fill the body of the hydraulic pump of the secondary circuit 34 with air.
    The valve for injecting water 44 into the secondary circuit opens, bringing the water back into the tank 47 via the conduit for the delivery of water from the secondary circuit 45.
    A non-return valve 49 located in the lower part of the tank 47 keeps the water 48 in the tank 47. The non-return valve communicates with the routing valve 32.
    In one embodiment, there is no check valve. The non-return valve ensures the tightness of the tank 47, even if this is ensured by the valve 32.
    The tank 47 is equipped with an anti-turbulence grid to ensure a laminar flow of water in the weir 52.
    The valve for routing the water discharged to the pylon 32 is used to top up the water in the tank 47 to charge the secondary system with fluid.
    Description of the operation of the installation:
    The water 48 contained in the tank 47 is poured into buckets 54. In this case the buckets 54 are mounted upright, the opening is oriented towards a weir 52 located at the top of the pylon 46. The weir 52 ensures the supply of the buckets 54 with water. The water flow rate from the weir for feeding the buckets is modulated by valves 51 for feeding the buckets 54. The buckets 54 are fixed to a rotary element 55 such as a belt, which drives sprockets 53. The filling the buckets 54 with water causes the belt to move by the effect of gravity. The pinions 53 are connected to an alternator, not shown, which produces electricity.
    2 shows a sectional view along the axis noted A in Figure 1. It is shown the belt having buckets 54 and fixed to the gables 53. The dotted circles represent several installations mounted in parallel.
    Figure 2 shows a configuration where the suction and delivery movements are ensured by mounting three installations mounted in parallel showing three different filling states (offset). The references are noted on a single installation shown by the dotted lines. In the water recovery tank 42 are represented three junction forms 38, the body of the hydraulic pump of the secondary circuit 34 and the body of the hydraulic cylinder HP of the primary circuit 33. In the junction form 38 are placed the sensors of return-suction reversal 40. The body of the hydraulic pump of the secondary circuit 34 comprises the piston of the pump of the secondary circuit 37 and of reverse-suction-discharge sensors 39. The piston of the pump of the secondary circuit 37 is connected by a rod of the pump-cylinder system 36 to the piston of the hydraulic cylinder of the primary circuit 35, itself contained in the body of the hydraulic cylinder 33 HP of the primary circuit.
    Figure 3 shows a variant of the diagram of Figure 1 in section of the pylon. There are certain elements mentioned in Figure 1.
    In this figure, there is shown a metal support 220 of the pinion axis 223 bottom. A base 227 supports the entire secondary system. The axis of the high pinion 223 is held by two ball bearings 221.
    A sealed formwork 226 is shown around the rotary element 55. At the top pinion 223, there is an air intake 225. The axis of the bottom pinion 222 is held by two ball bearings 221.
    There are also shown electrical connectors 224 and a power supply 230 for controlling the opening and closing of the compressed air distribution valves in the buckets 54.
    Another ball bearing 221 maintains the end of the pinion axis 223.
    The arrow 228 represents a part of the rotary element 55 immersed in water and the arrow 229 represents an air space at atmospheric pressure.
    Figure 4 shows some elements of Figure 1.
    FIG. 4 represents, according to another particular embodiment, an installation for producing electricity from pressurized water using the water available in valleys and mountains.
    The installation comprises a primary system 20 composed of a high altitude water reserve, not shown, for example the top of a mountain. The water is directed hundreds of meters below via penstock means 22, in a high pressure water distribution tank 24. The installation comprises a primary system 20 composed of at least one primary circuit. The installation comprises a secondary system 56 composed of a fluid in a closed circuit. In this example the fluid is air.
    An HP general circuit cut-off hydraulic valve 23 is placed above the HP water distribution tank 24 to shut down the system, allowing maintenance of the installation. The HP water contained in the HP water distribution tank 24 is injected into the secondary system 56 using the hydraulic circuit breaker HP valve 26 of the primary system 20. The hydraulic circuit breaker HP valve 26 is located under the HP 24 water distribution tank.
    In a variant, not shown, there are several exit points.
    When the hydraulic circuit breaker HP valve 26 is open, the water from the HP water distribution tank 24 enters a HP 57 water distribution tank.
    On either side of the HP water distribution tank 57 is an HP valve for suction 27 and an HP valve for discharge 29.
    The movements of water (suction or discharge) HP are used to move the piston 35 of the hydraulic cylinder of the primary circuit located in the body of the hydraulic cylinder HP 33 of the primary circuit. When stopped, the piston 35 of the hydraulic cylinder of the primary circuit is located in the left part (first position) of the body of the hydraulic cylinder HP 33 of the primary circuit.
    In this exemplary embodiment, the installation operates in two configurations:
    - for suction, we go from left to right (first position to second position)
    - for delivery, go from right to left (second position to first position)
    Below is a description of the different operating modes.
    System stopped: power on:
    When the primary system 20 is stopped, the hydraulic HP valves of the following primary circuit are closed: the HP valve for the suction 27, the discharge water discharge valve 28, the HP valve for the discharge 29, the water discharge valve 30, the air suction valve for the discharge 143, the air injection valve in the secondary circuit 144 and the suction valve of the air for suction 145.
    The following primary circuit hydraulic HP valves are open: the general circuit hydraulic HP valve 23 and the circuit circuit hydraulic HP valve 26.
    Description of the suction movement:
    Different stages take place in the primary 20 and secondary 56 systems.
    In the secondary system, the following steps take place:
    - the air injection valve in the secondary circuit 146 closes,
    - the air suction valve for suction 145 opens,
    - the air suction valve for delivery 143 closes,
    - the air injection valve in the secondary circuit 144 opens.
    In the primary system, the following steps take place:
    - the discharge water discharge valve 28 closes,
    - the HP valve for delivery 29 closes
    - the water drain valve 30 opens,
    - the HP valve for suction 27 opens.
    According to a suction movement of the primary system 20, the HP water contained in the HP water distribution tank 57 enters the circuit through the HP valve for suction 27. In an initial position, the piston is located left of the HP 33 hydraulic cylinder body (first position) of the primary circuit. The action of HP water pushes the piston 35 of the hydraulic cylinder of the primary circuit to the right (second position).
    The displacement of the piston 35 of the hydraulic cylinder of the primary circuit from the left (first position) to the right (second position) causes compression of the air present in the suction pump body 134.
    The secondary circuit includes a pump linked to the hydraulic cylinder by integral pistons. The suction piston 158 is linked to the piston 35. When the piston 35 passes from the left to the right (first to the second position) it causes the rectilinear movement of the suction piston 158.
    In a variant, a sensor system 153 limits the amplitude of movement of the piston and prevents deterioration of the piston.
    In the secondary system, the air suction valve for discharge 143 closes. The air injection valve in the secondary circuit 144 opens. The compressed air is then sent to the compressed air recovery tank 142.
    When the piston 35 goes to the right in the suction movement, the suction-discharge of air from the suction pump 160 makes it possible to fill the body of the suction pump 134. The suction-discharge of air from the discharge pump 161 allows air to be expelled from the body of the discharge pump 135.
    Description of the repression movement:
    Different stages take place in the primary 20 and secondary 56 systems.
    In the secondary system, the following steps take place:
    - the air suction valve for suction 145 closes,
    - the air injection valve in the secondary circuit 146 opens,
    - the air injection valve in the secondary circuit 144 closes.
    - the air suction valve for discharge 143 opens,
    In the primary system, the following steps take place:
    - the water drain valve 30 closes,
    - the HP valve for suction 27 closes
    - the discharge water discharge valve 28 opens,
    - the HP valve for discharge 29 opens.
    According to a delivery movement, the piston 35 of the hydraulic cylinder of the primary circuit moves to the first position. The water contained in the body of the HP hydraulic cylinder 33 of the primary circuit is evacuated by the water evacuation valves 28.
    The displacement of the piston 35 of the hydraulic cylinder of the primary circuit from the right (second position) to the left (first position) causes compression of the air present in the pump body 135.
    The secondary circuit includes a pump linked to the hydraulic cylinder by integral pistons. The discharge piston 159 is linked to the piston 35. When the piston 35 passes from the right to the left (second to the first position) it causes the rectilinear movement of the discharge piston 159.
    When the piston 35 goes to the left in the discharge movement, the suction-discharge of air from the discharge pump 161 makes it possible to fill the body of the discharge pump 135. The suction-discharge of the pump d the suction 160 makes it possible to expel the air from the body of the suction pump 134.
    The compressed air contained in the air recovery tank 142 is sent to the reserve tank using a compressed air regulator 157.
    The air contained in the reserve tank 147 is sent to buckets 54. A compressed air intake nozzle 152 supplies the buckets 54 with compressed air. Compressed air distribution valves 156 send the air under the buckets 54. The air flow rate coming from the compressed air intake nozzle 152 ensures the filling speed of the buckets as a function of their volume. In this case, the buckets 54 are mounted upside down at the level of the compressed air distribution valves 156.
    The buckets 54 are fixed on a belt which drives sprockets 53. In this embodiment, the buckets are mounted opposite to the figure
    1. The filling of the buckets 54 with air causes the belt to move. The pinions 53 are connected to an alternator (not shown in Figure 1), which produces electricity.
    NOMENCLATURE
    20. primary system
    21. water reserve at altitude
    22. HP (High Pressure) water penstock
    23. general hydraulic HP cut-off valve
    24. HP water distribution tank
    25. exit points
    26. hydraulic HP circuit breaker valve
    27. HP valve for suction
    28. discharge water valve
    29. HP valve for delivery
    30. suction water drain valve
    31. continuous water drain valve to nature
    32. water routing valve
    33. HP hydraulic cylinder body of the primary circuit
    34. body of the secondary circuit hydraulic pump
    35. piston of the hydraulic cylinder of the primary circuit
    36. pump cylinder rod
    37. piston of the secondary circuit pump
    38. junction formwork between the pump body and suction and discharge line
    39. suction-discharge reversing sensor
    40. return-to-suction reversing sensor
    41. air intake at atmospheric pressure
    42. water collection tank
    43. water suction valve of the recovery tank
    44. water injection valve in the secondary circuit
    45. conduit for the delivery of water from the secondary circuit
    46. pylon
    47. bac
    48. water
    49. check valve
    50. anti-turbulence grid
    51. valves for supplying water to the buckets
    52. weir for feeding the water buckets
    53. pinion driven by the belt carrying the buckets
    54. buckets
    55. secondary system rotary element
    57. HP water distribution tank
    134. body of the suction pump
    135. body of the discharge pump
    142. compressed air recovery tank
    143. air suction valve for discharge
    144. air injection valve in the secondary circuit
    145. air suction valve for suction
    146. air injection valve in the secondary circuit
    147. reserve tank
    152. compressed air intake nozzle
    153. sensor
    156. compressed air distribution valves
    157. compressed air regulator
    158. piston of the suction pump
    159. piston of the discharge pump
    160. suction-discharge air from the suction pump
    161. suction-discharge air from the discharge pump
    220. metal support of pinion axis
    221. ball bearings
    222. high pinion axis
    223. low pinion axis
    224. electrical connectors
    225. air intake
    226. watertight formwork of the rotary element
    227. base of the rotary element
    228. part of the turbine immersed in water
    229. air space at atmospheric pressure
    230. power supply for opening and closing control of the compressed air distribution valves in the buckets
    权利要求:
    Claims (8)
    [1" id="c-fr-0001]
    1. Installation for producing electricity using hydraulic pressure using the water available in valleys and mountains, said installation comprising a primary hydraulic system (20) having reservoir means (21) for collecting water at high altitude, and penstock means (22) for transporting this captured water hundreds of meters below under very high pressure; said installation being characterized in that it comprises:
    - a primary system (20) comprising a hydraulic cylinder (33) for exploiting this very high pressure of the water in the hydraulic primary circuit, the hydraulic cylinder (33) being capable of using water from the hydraulic primary circuit,
    - a secondary system (56) of a fluid in a closed circuit for the operation of a rotary element (55) comprising:
    • the rotary element (55) rotating around pinions (53) located at the top and bottom of a pylon (46), • a plurality of buckets (54) fixed to the rotary element (55), • a reserve (47) of a fluid, • the action of the hydraulic cylinder (33) being capable of recovering the fluid from the reserve, and of pumping (45) this fluid at the very top of the pylon (46) from where it is capable of pouring into the buckets (54) of the rotary element (55), which causes a rotary movement of the rotary element (55) around the pinions (53), • an alternator associated with a pinion (53 ) of the rotary element (55), said alternator being capable of triggering the production of electrical energy by the rotational movement of the rotary element (55).
    [2" id="c-fr-0002]
    2. Installation according to claim 1, wherein the fluid is water.
    [3" id="c-fr-0003]
    3. Installation according to claim 2, wherein the secondary circuit comprises at least one hydraulic pump (34) connected to the hydraulic cylinder (33) by integral pistons (35, 37).
    [4" id="c-fr-0004]
    4. Installation according to claim 1, wherein the plurality of buckets (54) is mounted in the place configured so that a weir (52) fills the buckets (54) with water.
    [5" id="c-fr-0005]
    5. Installation according to claim 1, in which the fluid is air.
    [6" id="c-fr-0006]
    6. Installation according to claim 5, wherein the secondary circuit comprises at least one pump (134, 135) connected to the hydraulic cylinder (33) by integral pistons (35, 158, 159).
    [7" id="c-fr-0007]
    7. Installation according to claim 5, wherein the plurality of buckets (54) is mounted upside down configured so that a compressed air intake nozzle (152) fills the buckets (54) with air .
    15
    [0008]
    8. Installation according to claim 1, wherein the hydraulic cylinder (33) comprises a piston (35) and means for regulating the speed of movement of the piston (35).
    1/4
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    同族专利:
    公开号 | 公开日
    EP3276159A1|2018-01-31|
    CN107664090A|2018-02-06|
    FR3054615B1|2018-08-10|
    EP3276159B1|2019-01-23|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    GB172819A|1920-10-18|1921-12-22|Manuel Chavez|Improvements in and relating to water motors|
    JPH05240154A|1992-03-02|1993-09-17|Osaka Prefecture|Submergible pump with bubble nozzle|
    JP2005214151A|2004-02-02|2005-08-11|Hiromu Kazama|Power generating device|
    FR3071382B1|2017-09-22|2020-01-31|Joseph Cariou|IRRIGATION INSTALLATION|
    BE1026570B1|2018-08-27|2020-03-23|Laethem Thierry Van|Device for generating electricity|
    KR102080000B1|2019-09-23|2020-02-21|이기동|Power generation|
    法律状态:
    2017-07-31| PLFP| Fee payment|Year of fee payment: 2 |
    2018-02-02| PLSC| Publication of the preliminary search report|Effective date: 20180202 |
    2018-03-23| TP| Transmission of property|Owner name: JOSEPH CARIOU, FR Effective date: 20180214 |
    2018-07-30| PLFP| Fee payment|Year of fee payment: 3 |
    2020-04-10| ST| Notification of lapse|Effective date: 20200306 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1657387|2016-07-29|
    FR1657387A|FR3054615B1|2016-07-29|2016-07-29|INSTALLATION FOR PRODUCING ELECTRICITY|FR1657387A| FR3054615B1|2016-07-29|2016-07-29|INSTALLATION FOR PRODUCING ELECTRICITY|
    CN201710618358.4A| CN107664090A|2016-07-29|2017-07-26|Generating equipment|
    EP17183635.6A| EP3276159B1|2016-07-29|2017-07-27|Installation for generating electricity|
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