An electrical energy generating device (1) to transform kinetic energy of fluid passing through a pipe into electrical energy, the device may include a flow management unit (2) having a first housing (20) enclosing a plurality of tubes and a first gasket (27); a generating unit (3) having a second housing (30) with a plurality of coils (37) embedded within the second housing (30), a rotor rotatable within the second housing (30); and a connector (4) connecting the flow management unit (2) to the generating unit (3).

A runner for a hydraulic turbine configured to reduce fish mortality. The runner includes a hub and a plurality of blades extending from the hub. Each blade includes a root connected to the hub and a tip opposite the root. Each blade further includes a leading edge opposite a trailing edge, and a ratio of a thickness of the leading edge to a diameter of the runner can range from about 0.06 to about 0.35. Further, each blade has a leading edge that is curved relative to a radial axis of the runner.

The invention provides an energy generation system comprising a generator having charged mutually rotating plate elements, and comprising an integrated drive mechanism for precisely controlling a separation distance between the plates. The drive mechanism provides a separation which varies as a function of the speed of rotation, hence assimilating separation control within the natural operation of the device. Embodiments provide plates comprising self-generating bearings, both hydrodynamic gas and fluid bearings and centrifugal regulator solid bearings, the bearings providing a supporting force between the plates of a magnitude which increases as the rotational speed of the plates increases. Methods of energy generation are also provided.

The invention relates to an impeller for a pump or turbine, comprising at least one blade, which blade is provided on the pressure side thereof with a standing edge on its outer peripheral edge zone. The invention also relates to a pump for pumping water or a turbine for generating energy from water and having a casing and such an impeller.

A screw system including a plurality of segmented blades. Each blade segment of the plurality of blade segments including a mounting portion and a vane portion. The mounting portion, having a helical length, for removably attaching the blade segment. The vane portion extending from the mounting portion along the helical length thereof. The vane portion having a front surface that is not parallel to a back surface from the mounting portion to a tip of the blade segment, along the helical length.

A power generation system using water power and wind power as two simultaneous energy sources to compensate for and supplement each other includes a power generation unit, a water energy unit, and a wind energy unit. The power generation unit includes a first power generation module and a second power generation module. The first power generation module rotates relative to the second power generation module, cutting a magnetic induction line to generate electrical energy. The water energy unit drives the first power generation module, the wind energy unit drives the second power generation module. The direction of rotation of the water energy unit is opposite to the direction of rotation of the wind energy unit, to rotate the two in opposite directions.

In a rotating electrical machine apparatus, a rotor portion provided in a cylindrical portion and a stator portion provided in a recessed portion in which the rotor portion is housed are aligned along the rotation axis of a rim such that a force is generated in a direction opposite to the direction of a load that acts along the rotation axis of the rim of loads that act on the rim following rotation of a blade.

The invention provides an energy generation system comprising a generator having charged mutually rotating plate elements, and comprising an integrated drive mechanism for precisely controlling a separation distance between the plates. The drive mechanism provides a separation which varies as a function of the speed of rotation, hence assimilating separation control within the natural operation of the device. Embodiments provide plates comprising self-generating bearings, both hydrodynamic gas and fluid bearings and centrifugal regulator solid bearings, the bearings providing a supporting force between the plates of a magnitude which increases as the rotational speed of the plates increases. Methods of energy generation are also provided.

A fluid mass movement electrical energy generation device and system may comprise a modular and scalable array of stationary tube-shaped modules containing small rotating turbines. Tube-shaped modules may be easily installed by anyone, almost anywhere fluid mass flow is present (including many locations not suited to conventional wind turbines) and may efficiently, safely and quietly capture energy from turbulent and inconsistent fluid flow patterns.

A liquid-filled hydroelectric generation device has a storage unit and at least one generating set. The storage unit has at least one generating chamber mounted in a bottom thereof. Each generating chamber has a closed end in a top thereof and an open end in a bottom thereof, and is connected with at least one inlet pipe. Each inlet pipe is bent into an inverted L shape and has a top end connected to the generating chamber and a bottom end spaced from the bottom of the storage unit. The at least one generating set is mounted respectively in the at least one generating chamber. Each generating set has a driving shaft, at least one blade wheel assembly mounted on the driving shaft, and a generator connected to the driving shaft. The liquid-filled hydroelectric generation device generates power stably regardless of the flow rate of the water source.