Examples of the present disclosure are related to systems and methods for utilizing effluent pipeline to generate energy. More particularly, embodiments disclose positioning a turbine within a bypass pipeline, wherein the bypass pipeline has a greater diameter than the effluent pipeline.

Systems and methods are for generating electrical power using air moving through a duct of a forced air heating or air conditioning system within a building. In one embodiment, a wind turbine may be provided that is sized to be mounted within a duct and includes one or more blades coupled to a motor for converting kinetic energy from air moving the duct into electrical power. A device may be coupled to the motor for at least one of operating electrical components or sensors of the device and charging a battery of the device.

A control device estimates a flow rate and an effective height difference of a fluid machine based on a characteristic detectable with regard to a rotating electrical machine and correlating with the flow rate and the effective height difference of the fluid machine. A total flow rate in a pipe system is estimated based on these values estimated by the control device and a flow resistance characteristic line, and cooperative control of the fluid machine and the flow rate control valve is performed such that the estimated value of the total flow rate becomes close to a target flow rate of the total flow rate in the pipe system.

A hydropower generator includes: a driving shaft installed along a path through which a fluid flows; a plurality of blade assemblies installed along a lengthwise direction of the driving shaft; a spinning supporter connected to rotatably support the driving shaft; a power generator receiving a spinning force of the driving shaft and generating electricity; and a flow pipeline internally provided with the driving shaft along a lengthwise direction thereof and formed with a channel through which a fluid flows.

A method and a device for supplying a measurement electronics system in a fitting, through which a fluid flows, with electrical energy, which is generated in a turbine by the fluid flowing through the filling, wherein the flow quantities and pressures vary within wide boundaries, typically 1:1000. A pressure control device associated with the turbine controls the pressure of the fluid striking the turbine in such a manner that the electrical energy required for operating the measurement electronics system is generated with a small flow quantity, the pressure loss incurred by the fluid while flowing through the fitting being limited to a maximum value.

A downhole drill pipe may comprise a transducer disposed therein, capable of converting energy from flowing fluid into electrical energy. A portion of a fluid flowing through the drill pipe may be diverted to the transducer. After passing the transducer, the diverted portion of the fluid may be discharged to an exterior of the drill pipe. To generate electrical energy while not obstructing the main fluid flow from passing through the drill pipe, the transducer may be disposed within a lateral sidewall of the drill pipe with an outlet for discharging fluid exposed on an exterior of the lateral sidewall.

Apparatuses, systems, and methods are provided for generating power. A pipe having an input flow is coupleable to an input section configured to receive at least a portion of the input flow. A generation section is coupleable to the input section and includes a pipe section to carry the at least a portion of the input flow, a turbine coupleable to the pipe section and configured to capture energy from the at least a portion of input flow carried by the pipe section, and a generator coupleable to the turbine and configured to generate power from the energy captured by the turbine. An output section is coupleable to the pipe and configured to provide output of the generation section to the pipe.

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 water treatment system comprising a housing adapted to receive a flow of water. An electrolytic treatment system disposed within the housing, for producing one or more product substances to treat the water. A hydro generation system disposed within the housing, for generating power from the flow of water. An electronic control system disposed within the housing, for receiving and managing the electrical power produced by the hydro generation system, and for controlling the transfer of electrical power to the electrolytic treatment system to control the production of the one or more product substances.

An electrical power generation system comprising a tube comprising a plurality of upper curves and a plurality of lower curves and forming a loop, the upper curves located at a higher vertical height than the lower curves and a plurality of electric generators external to the tube, each electric generator comprising a generator wheel having a magnet thereon, the plurality of electric generators positioned proximal to an external wall of the tube and electrically connected to a power grid. A plurality of buoyant torpedoes comprising a magnet travels through the tube and turns the wheel of the electric generator in response to the magnetic interaction between the magnet on the torpedo and the magnet on the generator wheel. At least a portion of the plurality of lower curves of the tube may comprise a check valve.