A geothermal power plant related maintenance support system comprises: a thermodynamic calculation module for determining performance of specified geothermal power plant components; a plurality of. embedded sensors, each of which is embedded in a different geothermal power plant location and adapted to sense a corresponding real-time geothermal power plant parameter; a plurality of environmental sensors adapted to sense ambient conditions in the vicinity of the geothermal power plant; and a processor in data communication with each of said embedded sensors and environmental sensors.

An actuator device for a wind turbine, in particular for a rotor blade of a wind turbine, and also to an associated wind turbine and a method of assembly, with an actuator component and a control component, wherein the actuator component has at least one actuator layer with a preferential direction and, substantially parallel to the actuator layer, at least one exciting layer, wherein the actuator layer comprises a photoactuator, wherein the photoactuator is designed to change a strain and/or stress of the actuator layer in the preferential direction on the basis of excitation light, wherein the exciting layer is designed to guide excitation light into the actuator layer, wherein the control component comprises a light source and a light guide, wherein the light source is arranged away from the exciting layer and is connected to the exciting layer by means of the light guide and wherein the light guide runs in different directions through the exciting layer.

A modular power plant system may include a plurality of thermal energy conversion elements installed in multiple cavities in the bottom of the well or along the well. The thermal energy conversion elements may convert geothermal heat directly to electricity. A surface infrastructure may consist of electricity distribution racks and pumps that drive cooling liquid in closed or open loops to cool the thermal energy conversion elements. AC or DC voltage may be communicated from each of the thermal energy conversion elements to the surface infrastructure for the distribution of electricity in a decentralized power grid.

Previous electrochemically-powered yarn muscles cannot be usefully operated between extreme negative and extreme positive potentials, since strokes during electron injection and during hole injection partially cancel because they are in the same direction. Unipolar-stroke carbon nanotube yarn muscles are described in which muscle strokes are additive between extreme negative and extreme positive potentials, and stroke increases with potential scan rate. These electrochemical artificial muscles include an electrically conducting twisted or coiled yarn and a material that dramatically shifts the potential of zero charge of the electrochemically actuated yarn.

Systems and methods for generating and a controller for controlling generation of geothermal power in an organic Rankine cycle (ORC) operation in the vicinity of a wellhead during hydrocarbon production to thereby supply electrical power to one or more of in-field operational equipment, a grid power structure, and an energy storage device. In an embodiment, during hydrocarbon production, a temperature of a flow of wellhead fluid from the wellhead or working fluid may be determined. If the temperature is above a vaporous phase change threshold of the working fluid, heat exchanger valves may be opened to divert flow of wellhead fluid to heat exchangers to facilitate heat transfer from the flow of wellhead fluid to working fluid through the heat exchangers, thereby to cause the working fluid to change from a liquid to vapor, the vapor to cause a generator to generate electrical power via rotation of an expander.

A vehicle incorporates a gravity-assist energy harvesting suspension system including one or more gravitational positive displacement pumps. The positive displacement pump has a cylinder and a reciprocating piston inside the cylinder. The piston is adapted for movement along a compression stroke and an opposite extension stroke in response to a gravitational bounce of the vehicle when in motion. A turbine comprising a rotor shaft and attached blades is mounted relative to a distal end of a fluid outlet hose connected to the pump. Fluid discharged through the outlet hose acts on the blades, thereby moving and imparting rotational energy to the rotor shaft. A generator is operatively connected to the turbine, and is adapted for converting the rotational energy generated by the rotor shaft to electrical energy.

A vehicle incorporates a gravity-assist energy harvesting suspension system including one or more gravitational positive displacement pumps. The positive displacement pump has a cylinder and a reciprocating piston inside the cylinder. The piston is adapted for movement along a compression stroke and an opposite extension stroke in response to a gravitational bounce of the vehicle when in motion. A turbine comprising a rotor shaft and attached blades is mounted relative to a distal end of a fluid outlet hose connected to the pump. Fluid discharged through the outlet hose acts on the blades, thereby moving and imparting rotational energy to the rotor shaft. A generator is operatively connected to the turbine, and is adapted for converting the rotational energy generated by the rotor shaft to electrical energy.

The present application relates to a method and a motor for performing work using osmosis. The method comprises the steps of providing a motor comprising a supply chamber, a pressure chamber comprising at least one inlet and at least one outlet, and a membrane permeable to fluid and at least partially impermeable to salt ions and enabling fluid communication between the supply chamber and the pressure chamber; then providing low salt concentration fluid in the supply chamber, closing the outlet of the pressure chamber; flowing high salt concentration fluid into the pressure chamber; allowing the pressure within the pressure chamber to increase as fluid crosses the membrane into the pressure chamber and using the increased pressure within the pressure chamber to perform work; then opening the outlet of the pressure chamber and allowing the fluid to drain from the pressure chamber and the pressure in the pressure chamber to decrease.

This invention describes a method for producing highly controllable motion in electroactive materials and electroactive actuators capable of pronounced contraction and expansion, which act as synthetic muscle, tendon, fascia, perimysium, epimysium, and skin that wrinkles, comprising ion-containing, cross-linked electroactive material(s); solvent(s); electrode(s); attachments to levers or other objects; and coating(s). Restriction of movement in undesired direction(s) produces pronounced movement in the desired direction(s). The electroactive material itself or the electroactive actuator may be used individually or grouped to produce movement when activated by electricity. This invention can provide for human-like motion, durability, toughness, speed, and strength. The electroactive materials and electroactive actuators, with highly controllable motion, can be attached to objects and devices to produce motion with no metal pulleys, gears, or motors needed.

A brine saturation process is disclosed. The process comprises increasing the salinity of an unsaturated saline stream (15) by passage through a brine saturator (5) in which salt is dissolved into the unsaturated saline stream (15) to produce a high salinity stream (11); and then converting latent osmotic energy present in said high salinity stream (11) into power by passage through an osmotic power unit (20). The process further comprises using an output stream derived from the high salinity stream (11) following passage through the osmotic power unit (12) as the unsaturated saline stream (15).