An apparatus for generating energy by intake and drainage of a fluid includes a reservoir and a pair of receptacles in fluid communication with the reservoir and mounted above the reservoir. Each of the pair of receptacles has a variable volume for holding the fluid. The variable volume is controlled by movable portions. The apparatus includes a lever rotatable about a lever pivot. The lever is coupled at a first side of the lever pivot to the movable portions associated with a first one of the pair of receptacles. The lever is coupled at a second side of the lever pivot to moveable portions associated with a second one of the pair of receptacles. The apparatus includes control valves controlling fluid communication between the pair of receptacles and the reservoir and a controller coupled to the control valves. The apparatus includes a generator coupled to moving portions.

The cyclic hydropower system includes a power generation device. The first power generation device includes a circular frame pivoted on an axle whose one end is coupled to an end of the axle. A number of basins are arranged around the circular frame. An arc trough is positioned at a distance from and along an arc section of the circular frame. A channel is formed between the arc trough and the circular frame allowing the basins to move through. The channel has inlet at an upper position and an outlet at a lower position. A tank is positioned beneath the outlet of the power generation device, a pumping element is provided inside the tank, and a pipe extended from the pumping element above the power generation device with a pipe outlet above the inlet of the power generation device.

In an embodiment, a closed loop electrical generator may include a multiphase riser column. The generator may also include a liquid return column. The generator may include a turbine generator disposed between the multiphase riser column and the liquid return column, such that a working fluid flows from the liquid return column to the turbine generator and then to the multiphase riser column. The generator may include a gas return column. The generator may include a compressor fluidly connected to the gas return column and the multiphase riser column, such that a gas from the gas return column is provided to the multiphase riser column and combined with the working fluid to produce a multiphase fluid. The generator may also include a separator fluidly connected to the multiphase riser column, the liquid return column, and the gas return column.

A hydro-turbine apparatus (1) comprising a turbine (9), a water collection chamber (11), a water inlet, at least one water injector (10) directed towards the turbine so as to provide a driving force to the turbine, wherein the water inlet in communication with the at least one water injector, and the water collection chamber arranged to receive water which has been directed at the turbine, and the apparatus arranged for operative submersion in a body of water (WL).

Aspects of the disclosure provide a power conversion system and a method for conversing power. The power conversion system includes a first fluid holding tank, a second fluid holding tank, a fluid inlet hose, a fluid outlet hose, a fluid container, and one or more tension springs connected to the upper surface of the container and to a lower surface of the first fluid holding tank. The power conversion system further includes a rotational component connected to a lower side of the container via a connecting rod. The power conversion system further includes a generator connected to the rotational component via a horizontal shaft. The power conversion system further includes a feedback hose connected between the second fluid holding tank and the first fluid holding tank. The power conversion system further includes a hydraulic pump connected to the second fluid holding tank.

A water driven power generating system has a frame with a waterwheel carried within the frame in an upright manner having a plurality of water receiving elements for turning the waterwheel. A water discharge manifold is used to discharge water from a supply tank onto the water receiving elements. The water supply tank is supplied with water from an adjacent water reservoir, such as a stock tank. After passing over the water receiving elements of the water wheel, the discharge water is allowed to flow back to the water reservoir by gravity. The water used in the system is pumped from the reservoir to the supply tank by a truck mounted pump which is powered by the power take-off of the truck.

A pump equipped with a plurality of systems includes a first system and a plurality of second systems, each of the plurality of systems containing an enclosed gas placed in contact with an internal liquid, it being possible for the enclosed gas to be placed at a depressed pressure or at a raised pressure in relation to the pressure of surroundings external to the system by variations in level of the liquid. The respective liquid environments of the plurality of systems are connected continuously so that compression or depression of the gas enclosed in the first system leads to successive variations in the levels of liquid in the second systems following successive applications of raised pressure or depressed pressure to the gases contained in the plurality of systems so as to allow the pumping of an external liquid in contact with the internal liquid of one of the systems.

A hydraulic-pneumatic energy storage and recovery system, which comprises first and second sealed containers within each of which a volume of liquid is introducible and from which the introduced liquid is pneumatically propellable; a turbine interposed between the first and second containers and coupled with a generator, to produce power when caused to be rotated by the pneumatically propelled liquid; and collection-delivery apparatus located externally to the first and second containers, for collecting energy-depleted liquid gravitating from the turbine and for delivering the collected liquid to one of the first and second containers, to be used in subsequent energy recovery cycles.

Aspects of the disclosure provide a power conversion system and a method for conversing power. The power conversion system includes a first fluid holding tank, a second fluid holding tank, a fluid inlet hose, a fluid outlet hose, a fluid container, and one or more tension springs connected to the upper surface of the container and to a lower surface of the first fluid holding tank. The power conversion system further includes a rotational component connected to a lower side of the container via a connecting rod. The power conversion system further includes a generator connected to the rotational component via a horizontal shaft. The power conversion system further includes a feedback hose connected between the second fluid holding tank and the first fluid holding tank. The power conversion system further includes a hydraulic pump connected to the second fluid holding tank.

An air-driven generator for generating electric power from movement of a working fluid. Upper ends of buoyancy conduits are in fluidic communication with an upper end of a gravitational distribution conduit, and a lower end of the gravitational distribution conduit is in fluidic communication with lower ends of the buoyancy conduits. An air injection system injects air into the buoyancy conduits. A closed fluid loop is formed with working fluid flowing from the gravitational distribution conduit driving a fluid turbine system that is interposed between the lower ends of the gravitational distribution conduit and the buoyancy conduits. Flow of working fluid can be induced by an injection of air into working fluid disposed in the buoyancy conduits to achieve a generation of power by actuation of the fluid turbine system. An upper chamber can remove entrained air. A Rankin Cycle Generator can receive and be actuated by exhausted air.