A plumbing system for generating electrical power, including a hydroelectric generator assembly configured to generate power, a power source arranged in parallel with the hydroelectric generator assembly, and an interconnecting power harness in communication with the hydroelectric generator assembly and the power source. The plumbing system additionally includes a plumbing fixture in communication with the interconnecting power harness. The plumbing fixture includes a valve and a sensor configured to detect the presence of a user. The hydroelectric generator assembly is configured to provide power to the valve.

A system and method to direct a communication from a user device to rotate a deflector guide located proximal to a sprinkler head. The sprinkler head rests on a sealed bottom ring comprised of a waterwheel, transformer, rotating slider, and D2M communications device. When water is deployed from the sprinkler head, the waterwheel inside the sealed bottom ring rotates to generate energy. This starts the communication device which maintains a D2M communication signal until the water is turned off. The communication device is managed by a user on a user device through a user interface. After communication signal is selected in the user interface of the user device, the deflector head responds to commands and pivots along a circular path. The deflector comprises an opening that limits the spray from the sprinkler head to a more limited range than if the deflector was not used. The user can adjust the spray pattern of the sprinkler head without manually adjusting the deflector guard and therefore the user is able to remain dry during the process.

An adapter element for a solenoid valve assembly in an irrigation system includes an integral water turbine generator including an impeller positioned in an outlet flow path of a solenoid assembly thereof such that the impeller rotates when water flows to generate electricity.

An apparatus comprising a meter device with a rotating component configured to rotate in response to a flowing fluid, an indexing unit coupled with the meter device and configured to process signals from the meter device resulting in values for measured parameters of a flowing fluid, and an energy harvester coupled to the pair of impellers, the energy harvester comprising a first harvesting unit and a second harvesting unit that co-operate to generate an electrical signal, the first harvesting unit configured to co-rotate with the pair of impellers, the second harvesting unit comprising a hollow, magnetic core disposed proximate the first harvesting unit.

A cooking apparatus includes a housing defining an internal chamber. The internal chamber includes a cooking portion. The apparatus includes a single cooking container configured and adapted to be removably received in the cooking portion of the internal chamber. The single cooking container defines a cooking volume. The apparatus includes at least two heating elements positioned within the cooking portion of the internal chamber.

Implementations of energy harvester systems may include: an accumulator having an air bladder separated from water by a membrane; one or more hydro turbines coupled with the accumulator; two or more check valves each coupled with one of the one or more hydro turbines; a system battery coupled to the power conditioner; and an electronic load coupled to the system batter through the power conditioner; wherein the two or more check valves are configured to be in contact with water.

A power generator for generating power using a liquid that can alternatively flow at a lower flow rate and at a higher flow rate. The power generator includes a conduit and a rotor mounted in the conduit so as to be rotatable about a rotation axis. The rotor includes a top set of blades provided in a conduit top portion and configured for rotating about the rotation axis when the liquid flows at the higher flow rate in the conduit. The rotor also includes a bottom set of blades provided in a conduit bottom portion and configured for rotating about the rotation axis when the liquid flows at the lower flow rate in the conduit. An output shaft protrudes from the conduit and is rotatable by at least one of the top and bottom sets of blades. The top and bottom blades have different configurations.

An apparatus, system and method to reduce the contaminate concentration of effluent before discharge is provided utilizing discharge pipes, inlets and outlets. The apparatus comprises a central bore having an internal diameter suitable for a fluid flow, the fluid flow moves inside the central bore through the apparatus, and at least one outlet, the fluid flow exits the apparatus through the at least one outlet, a plurality of inlets for flowing additional fluid to the central bore, and the inlets mix the fluid flow with the additional fluid from the plurality of inlets. The apparatus can further mix the effluent though additional mixing devices and additional devices can be used to recapture energy such as, hydroelectric power from the fluid flow. A method reduces the effluent concentration by mixing for example, by creating a helical flow in the central bore.

A fluid-powered generator harvests the inherent energy in a flowing medium, such as wind or water, as it flows along a flexible sail, creating an undulating motion that causes rotation of a crankshaft. The generator comprises a plurality of ribs pivotably connected to a support shaft. Each rib is coupled to the sail and to a crank arm such that when the sail undulates, the ribs and crank arm pivot in the direction of the undulation, causing rotation of the crankshaft. The generator thus converts the linear motion of the fluid to circular motion to produce renewable energy.

A device is provided having a fermentation chamber having one or more inlets to receive a mixed stream to be fermented and an outlet to release fermented product; a distillation vessel surrounding the fermentation chamber having communication with the fermentation chamber outlet to receive fermented product to be distilled and a turbine located within the outlet of the fermentation chamber, the turbine having a rotor rotatable by force of flow of fermented product from the fermentation chamber to the distillation vessel, to generate electricity. A sidewall common to both the fermentation chamber and distillation vessel allows for heat transfer of heat generated from fermentation to the distillation vessel to heat the product to be distilled. A method of fermenting and distilling a product is also provided. The method involves receiving in a fermentation chamber a mixed stream to be fermented; transferring heat energy generated by fermentation to a distillation vessel surrounding the fermentation chamber; allowing pressurized fermented product to flow from the fermentation chamber into the distillation vessel via a turbine and rotating a rotor of the turbine by a force of flow of the fermented product to the distiller to generate electricity.