A multi-mode subterranean energy system and a related multi-mode subterranean energy production method are disclosed. The system comprises subterranean tunnels (2, 3, 8, 9, 14) connecting an upper reservoir of water (1), an underground cavity (10) and a subterranean recipient (15), a turbine/pump unit (4), and water flow control means (5, 6, 7). The system optionally can be operated in four modes.

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.

A piezoelectric power apparatus wherein piezoelectric material forms one wall of a liquid-filled container. Water pressure within the container is made to rapidly vary either by a cam operated piston or a motor operated ball valve acting on a pressurized liquid flow. The piston reciprocates through a wall of the container to alternately increase and decrease the pressure in the liquid. The ball valve periodically interrupts the pressurized liquid flow to alternately increase and decrease the pressure in the liquid. In either case, the alternate increase and decrease in the pressure in the liquid creates pressure variations in the piezoelectric material.

The hydroelectric generator using a conduit turbine, is characterized in that at least two conduit turbine units are serially arranged in multiple levels, the conduit turbine units each comprising: a driving shaft which penetrates the center of a conduit through which a flow for electric generation passes to the inside; a conduit support main body which is provided so as to support the driving shaft, and has an arm extending towards the inner surface of the conduit; a propeller which is between two conduit support main bodies, is fixed to the driving shaft, and rotates by means of the movement of the flow; an internal gear which rotates together with the driving shaft from between the conduit support main bodies; an external gear which is driven together with a shaft, outside the conduit, as a rotational force is delivered to the internal gear; and an electric generator.

A turbine generator assembly for generating power from a fluid flow, the assembly comprising: a housing for directing fluid flow, a turbine generator having a longitudinal axis of extension, enclosed in said housing, said turbine generator comprising: a plurality of blades provided on a central rotational axis being parallel with the longitudinal axis, a rotor, and a stator arranged peripherally and annular to the rotor; at least one of the plurality of blades being provided in fixed arrangement with the rotor, and wherein the stator of the turbine generator comprises a plurality of segments each having a coil length parallel to the longitudinal axis of the turbine, and a radial coil thickness, wherein at least two stator segments have different coil lengths and/or thickness to each other.

Gravity and hydrostatic pressure are natural forces that have considerable force generating capabilities which can make significant contributions during the operation of a FFWN 24/7/365, baseload, 100% clean energy power plant. When these natural forces are combined with compressed air in the upper part of an elevated storage tank containing a liquid and the partial vacuum created by powerful pumps to produce a targeted water flow rate velocity of about 31.3 m/s through the entire length of a coiled section of pipe containing one or more helical turbines in each coil that are connected to an external generator, the electricity produced during a power producing cycle by all the turbines/generators when combined will be considerably more than the power ultimately consumed by the pumps to return the highly pressurized water in a ground level tank back to the storage tank utilizing a return tank and simple water displacement.

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.

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.

A system includes a rain gutter of a property, wherein at least a portion of the rain gutter is positioned on a roof of the property, a rain gutter power generator that is coupled to the rain gutter, and a control unit that controls the device at the property. The rain gutter power generator includes a water turbine that transforms kinetic energy of water collected by the rain gutter of the property into mechanical energy and an electromagnet that transforms the mechanical energy into electricity that powers a device at the property.

A hydraulic power generation system is provided with a control unit which controls the power supply circuit to perform a normal operation of supplying power from the power system to a predetermined electric device provided at the water channel and an autonomous operation of supplying the power generated by the electric generator to the electric device. The control unit executes the autonomous operation when the power system fails.