A geothermal energy system utilizes a Catherine Wheel that spins around an axle to produce power. The Catherine Wheel has a plurality of wheel arms extending radially out from the axle. A fin portion extends from the radial portion at an offset angle, to an exhaust end. A first working fluid, such as supercritical carbon dioxide flows through an arm conduit within the wheel arm and second working fluid, such as a simply hydrocarbon mixes with the first working fluid and both flow through a turbine. The turbine is configured within the wheel arm conduit and it turns as the combined working fluids vaporize. The fluids are expelled and the second working fluid may be condensed and recirculated while the first working fluid may be expelled back into a geothermal reservoir. The geothermal energy system efficiently and effectively produces power by using geothermal energy to vaporize a hydrocarbon.

A device 10 for installation within or on a structure for transferring kinetic energy from a load moving across the structure to a pneumatic or hydraulic system 3 for harvesting this wasted energy. A rocker having an upper surface for passage of the load is pivotally or slidably mounted in a cradle, the cradle housing at least one pneumatic or hydraulic pipe disposed between the rocker and the cradle.

Apparatus for extracting useful work or electricity from low grade thermal sources comprising a chamber, a source of heated dense heat transfer fluid in communication with the chamber, a source of motive fluid in communication with the chamber, wherein the motive fluid comprises a liquid phase, a flow control mechanism cooperating with the source of heated dense heat transfer fluid and with the source of motive fluid to deliver said fluids into the chamber in a manner that said fluids come into direct contact with each other in the chamber to effect a phase change of the motive fluid from liquid to gas to increase the pressure within the chamber to yield pressurized fluids, and a work extracting mechanism in communication with the chamber that extracts work from the pressurized fluids by way of pressure let down.

Systems, methods, and devices for energy storage are provided. A system for energy storage includes a thermomechanical-electrical conversion subsystem for converting energy formats and a mechanical and thermal storage unit for storing energy formats. The thermomechanical-electrical conversion subsystem includes a storage subsystem including a compressor and a first thermal energy exchanger and a generation subsystem including a power generator and a second thermal energy exchanger. The storage subsystem compresses a fluid to generate compressed fluid and thermal energy. The generation subsystem generates power from the compressed fluid and the thermal energy. The mechanical and thermal storage unit includes a pressure vessel for storing the compressed fluid and a thermal energy storage for storing the thermal energy generated by the fluid compression and for providing the thermal energy to the generation subsystem for generating power.

An artificial cilium device includes a substrate and a voltage-actuated cilia-shaped structure attached at a proximal end to the substrate. The voltage-actuated cilia-shaped structure has a first layer of a first material and a second layer of a second material. The second layer of the second material includes an exposed surface that causes the cilia-shaped structure to, in a working medium, (a) change shape from a first shape to a second shape responsive to application of a first voltage and (b) change shape from the second shape to the first shape responsive to application of a second voltage different than the first voltage.

Systems, methods, and devices for energy storage are provided. A system for energy storage includes a thermomechanical-electrical conversion subsystem for converting energy formats and a mechanical and thermal storage unit for storing energy formats. The thermomechanical-electrical conversion subsystem includes a storage subsystem including a compressor and a first thermal energy exchanger and a generation subsystem including a power generator and a second thermal energy exchanger. The storage subsystem compresses a fluid to generate compressed fluid and thermal energy. The generation subsystem generates power from the compressed fluid and the thermal energy. The mechanical and thermal storage unit includes a pressure vessel for storing the compressed fluid and a thermal energy storage for storing the thermal energy generated by the fluid compression and for providing the thermal energy to the generation subsystem for generating power.

The present disclosure is intended to prevent blockage of a path that allows a fluid to flow to a predetermined position where a pressure of the fluid is applied to a cell unit. An electrochemical compressor according to an embodiment includes first and second members, an elastic body, a fluid chamber, and a fluid path. The elastic body exerts an elastic force in a direction in which the first member and the second member are pushed apart from each other, and thereby presses a stack of electrochemical cells. The fluid chamber has the elastic body disposed therein and receives boosted gas flowing thereinto, the fluid chamber allowing the boosted gas to apply a pressure to push the first member and the second member apart from each other. The fluid path connects the fluid chamber to a flow path into which the boosted gas is discharged from the electrochemical cells.

The present disclosure is intended to provide an electrochemical compressor capable of preventing a liquid, such as water, from accumulating inside a piston. An electrochemical compressor according to an embodiment includes a housing chamber and a drain path. The housing chamber houses an elastic body that presses an electrochemical cell with its elastic force, and is configured to receive part of a gas compressed by the electrochemical cell, the part of the gas flowing into the housing chamber. In the electrochemical cell, the gas is supplied to an anode side of a solid polymer electrolyte membrane as a partition wall, and is compressed by being moved by electricity to a cathode side opposite to the anode side. The drain path allows a liquid in the housing chamber to be drained out of the housing chamber.

An artificial cilium device includes a substrate and a voltage-actuated cilia-shaped structure attached at a proximal end to the substrate. The voltage-actuated cilia-shaped structure has a first layer of a first material and a second layer of a second material. The second layer of the second material includes an exposed surface that causes the cilia-shaped structure to, in a working medium, (a) change shape from a first shape to a second shape responsive to application of a first voltage and (b) change shape from the second shape to the first shape responsive to application of a second voltage different than the first voltage.

In some embodiments, electrochemical actuators include a sealed electrolytic chamber with two or more electrodes disposed therein and associated reservoirs. In some embodiments, the electrochemical actuators include one or more rigid structures that are overmolded onto one or more electrodes to form the electrolytic chambers. In some embodiments, multiple rigid structures that are overmolded onto two separate electrodes may be connected to form one or more electrolytic chambers with a desired configuration of electrodes contained therein. In some embodiments, manufacturing methods and structures relate to the formation of an array of electrochemical actuators.