A combined pump and turbine (electromechanical converter), which may be operable as a motorized centrifugal pump for starting a siphon and as an electromechanical turbine particularly for transmission of a liquid, such as water, in a water treatment plant. Recovery of energy from liquid flow with the combined pump and turbine, particularly in water treatment applications, allows for increased energy gains.

A device and method for converting electric energy into pneumatic energy and vice versa, which involves: pumping a liquid forming a liquid piston into a conversion chamber in which a quantity of air is trapped until the air reaches a pressure of a compressed air storage vessel; or churning a liquid by expanding the compressed air in a conversion chamber which is filled with a quantity of liquid, in which device or method the pumping or the churning of the water takes place in the same conversion chamber and consecutively in at least two pumping or churning stages, respectively, provided so as to operate in different pressure ranges. The present device and method can be used in particular in the field of converting and storing electric energy.

A device and method for converting electric energy into pneumatic energy and vice versa, which involves: pumping a liquid forming a liquid piston into a conversion chamber in which a quantity of air is trapped until the air reaches a pressure of a compressed air storage vessel; or churning a liquid by expanding the compressed air in a conversion chamber which is filled with a quantity of liquid, in which device or method the pumping or the churning of the water takes place in the same conversion chamber and consecutively in at least two pumping or churning stages, respectively, provided so as to operate in different pressure ranges. The present device and method can be used in particular in the field of converting and storing electric energy.

The present invention is a reversible pump-turbine installation position in a vertical shaft instead of in a conventional underground powerhouse or deep concrete powerhouse. The required plant cavitation coefficient may be achieved by simply boring a vertical shaft to the required depth rather than routing the water flow to and from a deeply buried powerhouse. A pneumatically controlled pressure relief valve may be incorporated into this invention.

A pumped storage hydropower apparatus includes a housing and at least one pump disposed within the housing. The at least one pump is configured to operate in a first mode of operation or a second mode of operation based on an operation condition including at least one of a time or a price of electrical power from a remote electrical power source. In the first mode of operation, the at least one pump receives a first flow of water from a first water storage unit, transports the first flow to a second water storage unit, and generates electrical power for transmission to the remote electrical power source. In the second mode of operation, the at least one pump receives a second flow of water from the second water storage unit, and transports the second flow to the first water storage unit using electrical power from the remote electrical power source.

A pumped storage hydropower apparatus includes a housing and at least one pump disposed within the housing. The at least one pump is configured to operate in a first mode of operation or a second mode of operation based on an operation condition including at least one of a time or a price of electrical power from a remote electrical power source. In the first mode of operation, the at least one pump receives a first flow of water from a first water storage unit, transports the first flow to a second water storage unit, and generates electrical power for transmission to the remote electrical power source. In the second mode of operation, the at least one pump receives a second flow of water from the second water storage unit, and transports the second flow to the first water storage unit using electrical power from the remote electrical power source.

A reactive blade turbine system works vertically, horizontally, or at an angle and clockwise or counterclockwise according to blade angle and locking position and adjusts to variations in fluid flow such as changes in tidal currents to generate power more efficiently regardless of direction of fluid flow.

A reactive blade turbine system works vertically, horizontally, or at an angle and clockwise or counterclockwise according to blade angle and locking position and adjusts to variations in fluid flow such as changes in tidal currents to generate power more efficiently regardless of direction of fluid flow.

A reactive blade turbine system works vertically, horizontally, or at an angle and clockwise or counterclockwise according to blade angle and locking position and adjusts to variations in fluid flow such as changes in tidal currents to generate power more efficiently regardless of direction of fluid flow. A method for generating electrical power from a continuous fluid flow via the reactive turbine system is also provided herein.

A reactive blade turbine system works vertically, horizontally, or at an angle and clockwise or counterclockwise according to blade angle and locking position and adjusts to variations in fluid flow such as changes in tidal currents to generate power more efficiently regardless of direction of fluid flow. A method for generating electrical power from a continuous fluid flow via the reactive turbine system is also provided herein.