An energy concentration device includes a pneumatic cylinder that allows for contact with waving sea water of the nature to make a float device to drive a piston rod to achieve an effect of up and down piston movement so as to realize an effect of pressurization of air inside the pneumatic cylinder, whereby the air may achieve an effect of increase of pressurization level through multi-staged pressurization and an effect of accumulation by being stored in a high-pressure air storage device for the purposes of electrical power generation with the pressurized air and supplying pneumatic power required by other applications, such as automobiles, motorcycles, buses, and factories and also for supplying of pneumatic power to household devices, such as household appliances and pneumatically-operating doors.

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, wherein the fluid flow moves inside the central bore through the apparatus, and at least one outlet, wherein 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 wherein 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. The system using a control panel to achieve favorable mixing or fluid flow by controlling the fluid flow properties of the inlets.

A drilling and through-wall fire extinguishing device comprises a main water turbine, a forward and reverse commutator, a reducing sleeve, a hollow drill bit, a handwheel booster, a guide rail, a water separator, a vice water turbine and a high pressure water pump. The handwheel booster is connected with the main water turbine, the main water turbine is drivingly connected with the hollow drill bit through the forward and reverse commutator, the reducing sleeve is arranged between the hollow drill bit and the forward and reverse commutator, and the main water turbine and the forward and reverse commutator are fixed on the guide rail; and fire-fighting pressure water is fed by the water separator, a first water outlet of the water separator is communicated with the main water turbine, a second water outlet is communicated with the vice water turbine, and the vice water turbine is drivingly connected with the high pressure water pump.

A high building power generation device includes a plurality of water storage tanks and at least one power generation unit. The water storage tanks are arranged at specific floors of a high building so that a predetermined vertical distance is provided between adjacent ones of the water storage tanks. The water storage tanks are connected to each other with pipes. A control valve is mounted at a connection of each water storage tank with the pipes. The power generation unit is arranged at a bottom floor of the high building. The pipes connecting with the water storage tanks have a lower opening that is located above the power generation unit. The water storage tanks accumulate and store used water from multiple floors and the control valves are openable to release the used water to impact and drive the power generation unit to generate electrical power.

A fluid conduit includes an open chamber. A rotating device is mounted in the chamber. The rotating device includes a portion protruding through the open chamber and into the conduit. A plurality of fluid impingement surfaces are spaced apart on a surface of the rotating device, whereby fluid moving through the conduit impinges on the impingement surfaces and rotates the rotating device.

A water outlet device with self power generation has a fixing unit that includes an inlet waterway and at least one first outlet waterway and at least one second outlet waterway. The first outlet waterway is connected to the inlet waterway through an electric-control valve and the second outlet waterway is connected to the inlet waterway. A power generation mechanism is fixed in the fixing unit; a fast energy storage component; a control unit comprises a control circuit and a control module; the control circuit, fast energy storage component, electric-control valve and the power generation mechanism are in electric-connection, the electric energy generated by the power generation mechanism is stored by the fast energy storage component after rectification, the control circuit gets the electric energy through the fast energy storage component and controls the electric-control valve.

A hydroelectricity and compressed-air power converter system includes a first fill pool, a plurality of internal fill tanks, an external fill tank, a wave channel, a plurality of air-generator systems, a second fill pool, at least one air storage tank, and at least one generator system. The first fill pool is intermittently in fluid communication with the external fill tank through the plurality of internal fill tanks while the external fill tank is intermittently in fluid communication with the second fill pool through the wave channel. The second fill pool is selectively in fluid communication with the first fill pool through the at least one generator system so that a set amount of water can be circulated within the power converter system as it generates compressed-air from the plurality of air-generator systems and hydroelectricity from the at least one generator system.

A hydroponic container growing system is provided. The growing system provides a closed growing environment providing climate and other growing conditions suitable for year-round plant production. The growing system may include a container having a plurality of subsystems therein. The plurality of subsystems may include a plant production system, an environmental regulation system, an energy capture system, a control system, and a dosage system. The plant production system may include an Ebb and Flow irrigation system and one or more Nutrient Film Technique (NFT) irrigation systems. A single reservoir may supply the Ebb and Flow irrigation system and a NFT irrigation system to provide a dual technique, single nutrient supply source irrigation system for plant production. An energy capture system which utilizes the kinetic energy of flowing liquid to generate electrical energy may be integrated into one or more irrigation systems within the plant production system.

A generator system with a generator connected between a first preexisting pipe and a second preexisting pipe. The generating system can have a non-magnetic section of pipe, a flux guide, a plurality of coils, a non-rotating stator a rotating device, a plurality of rare earth, and a controller. Fluid flows through the first preexisting pipe flange towards the second preexisting pipe flange, which causes the rotating device to turn the rotating shaft that rotates the plurality of rare earth magnets to provide a magnetic flux energizing the plurality of coils generating a current of sufficient energy to produce at least six watts continuously.

A system includes a building, a fluid-moving system, and a turbine system. The fluid-moving system includes one or more conduits in or coupled to the data center and a pump. The pump moves fluid through the conduits. The turbine system includes a turbine and generator. The turbine has a runner in a flow of fluid in one of the conduits. The generator produces electricity from rotation of the runner.