A fluid flow actuated tool including a housing, a tool and an actuating mechanism. The housing includes a housing interior. The housing interior receives a flow of fluid. The actuating mechanism includes a fluid wheel structure. The fluid wheel structure is connected to the tool. At least a portion of the fluid wheel structure is arranged in the flow of fluid for rotating the fluid wheel structure. The tool is actuated based on rotation of the fluid wheel structure.

An assembly for generating electrical power from a fluid flow being installable to a fluidic conduit comprising a fluid, the assembly comprising a turbine for generating power from the fluid flow, the turbine provided within a turbine body, a connecting member having a proximal portion attached to a distal portion of the turbine body and a distal portion comprising a cap, a separate enclosure for housing the turbine and turbine body, the enclosure slidably receiving the connecting member through a distal portion, the cap of the connecting member being securable to the enclosure. The enclosure is connectable to a valve member, the valve member and the enclosure for provision external to the fluidic conduit comprising the fluid.

A fluid flow device has a body with a mechanism for altering state of a fluid flowing through the device, an inlet conduit providing inlet of the flowing fluid to the body of the device, an outlet conduit providing outlet of the flowing fluid from the body of the device, and a micro-generator assembly installed in either the inlet conduit or the outlet conduit, the micro-generator assembly having an impeller driven by the flowing fluid, the impeller turning a shaft driving a generator producing a voltage across two output conductors.

A fluid flow device has a body with a mechanism for altering state of a fluid flowing through the device, an inlet conduit providing inlet of the flowing fluid to the body of the device, an outlet conduit providing outlet of the flowing fluid from the body of the device, and a micro-generator assembly installed in either the inlet conduit or the outlet conduit, the micro-generator assembly having an impeller driven by the flowing fluid, the impeller turning a shaft driving a generator producing a voltage across two output conductors.

A light-emitting assembly with a micro hydraulic power generator includes a power generation module and a light-emitting module. The power generation module includes a housing, a coil module and an impeller. An accommodating space inside the housing is divided by a transverse baffle therein into two cavities, respectively a coil cavity and an impeller cavity. A side wall of the impeller cavity is provided with at least one water inlet. At least one internally recessed portion is provided at a connection portion between the transverse baffle and an outer wall of the coil cavity, and the transverse baffle defines a water outlet at a portion positionally corresponding to the internally recessed portion. The coil module is arranged in the coil cavity in a sealed manner by a colloidal material. The impeller is placed in the impeller cavity, the impeller can be rotated by an external force.

A hydroelectric facility for generating electrical energy from the flow of water circulating in a water network, includes at least one cross-flow pico-turbine mounted on a shaft extending perpendicular to a direction of the water flow, the pico-turbine including a substantially annular blade installed in the water flow in order to generate a mechanical energy of rotation, at least one generating unit, installed outside of the water flow and coupled to the shaft of the pico-turbine in order to transform the mechanical energy of rotation into electrical energy, at least one measurement and control unit, installed outside of the water flow, connected to the generating unit, controlling the distribution of the collected electrical energy as well as the rotation of the pico-turbine depending on the characteristics of the water flow.

A lighting shower includes a body, a lighting device, a control module, and a hydraulic power generating device. The body has a first portion and a second portion facing opposite directions and includes an inlet tube and an outlet cover plate disposed on the second portion. The lighting device includes a transparent cover disposed on the first portion and a light-emitting element disposed in the transparent cover. The control module includes a storage battery and a controller electrically connected to the light-emitting element and adapted to control the light-emitting element to turn on or turn off. The water flows into a first chamber of the body from the inlet tube and through the hydraulic power generating device out from the outlet cover plate. The hydraulic power generating device is electrically connected to the control module to output an electrical energy to the storage battery for storage for providing an electricity required by the lighting device.

A separation assembly comprises a housing, a jet that expels a fluid within the housing, and a turbine positioned within the housing. The fluid causes the turbine to rotate about a center rotational axis within the housing. The turbine comprises a first axial end, a second axial end, and a plurality of vanes extending axially relative to the center rotational axis from the first axial end to the second axial end. The plurality of vanes defines axially-extending channels between each of the plurality of vanes. The first axial end comprises a radially-extending structure that axially blocks the flow of the fluid through the first axial end. The second axial end does not comprise any structure that axially blocks the flow of the fluid through the second axial end.

A lighting shower includes a body, a lighting device, a control module, and a hydraulic power generating device. The body has a first portion and a second portion facing opposite directions and includes an inlet tube and an outlet cover plate disposed on the second portion. The lighting device includes a transparent cover disposed on the first portion and a light-emitting element disposed in the transparent cover. The control module includes a storage battery and a controller electrically connected to the light-emitting element and adapted to control the light-emitting element to turn on or turn off. The water flows into a first chamber of the body from the inlet tube and through the hydraulic power generating device out from the outlet cover plate. The hydraulic power generating device is electrically connected to the control module to output an electrical energy to the storage battery for storage for providing an electricity required by the lighting device.

A fluid flow actuated tool including a housing, a tool and an actuating mechanism. The housing includes a housing interior. The housing interior receives a flow of fluid. The actuating mechanism includes a fluid wheel structure. The fluid wheel structure is connected to the tool. At least a portion of the fluid wheel structure is arranged in the flow of fluid for rotating the fluid wheel structure. The tool is actuated based on rotation of the fluid wheel structure.