A system for extracting work from the expansion of a working fluid includes a vessel having at least a portion of the working fluid, a heating device in thermal communication with the portion of the working fluid in the vessel for heating the portion of the working fluid in the vessel and expanding the working fluid, and a conversion tool. The conversion tool is in fluid communication with the vessel and is configured to receive working fluid from the vessel when the working fluid expands. The conversion tool is further configured to extract work from the expanded working fluid.

A light turbine, turbine, and turbine housing are described, in which the turbine housing can include a main housing and a chimney. The main housing and chimney define a circular path within which vanes located on the ends of spokes can move. Movement of the vanes can cause rotation of a shaft attached to the spokes. The chimney can be removably attached to the main housing to allow access to the vanes, which can be removably attached to the spokes. The turbine housing and turbine can be configured such that various compositions and/or configurations of vanes can be evaluated in conjunction with one or more forms of energy sources, such as an electromagnetic radiation source. The turbine housing can enable selective evaluation within ambient air, a partial vacuum, and/or the like.

A light turbine, turbine, and turbine housing are described, in which the turbine housing can include a main housing and a chimney. The main housing and chimney define a circular path within which vanes located on the ends of spokes can move. Movement of the vanes can cause rotation of a shaft attached to the spokes. The chimney can be removably attached to the main housing to allow access to the vanes, which can be removably attached to the spokes. The turbine housing and turbine can be configured such that various compositions and/or configurations of vanes can be evaluated in conjunction with one or more forms of energy sources, such as an electromagnetic radiation source. The turbine housing can enable selective evaluation within ambient air, a partial vacuum, and/or the like.

An energy storage system converts variable renewable electricity (VRE) to continuous heat at over 1000° C. Intermittent electrical energy heats a solid medium. Heat from the solid medium is delivered continuously on demand. Heat delivery via flowing gas establishes a thermocline which maintains high outlet temperature throughout discharge. The delivered heat which may be used for processes including power generation and cogeneration. In one application, the energy storage system provides higher-temperature heat to a conventional lower-temperature heat source to boost the temperature of a thermal power cycle working fluid to a turbine, thereby increasing efficiency of the power cycle.

Disclosed is an energy supply system using hot waste water that controls a supply of energy required according to a situation of agricultural facilities. The energy supply system includes a hot waste water pipe connecting a power plant and at least one facility so as to supply thermal energy to the at least one facility through hot waste water discharged from the power plant; a ground heat exchanger buried under a ground and connected to the at least one facility so as to supply geothermal energy to the at least one facility; at least one solar cell module disposed in the at least one facility and supplying electric energy to the at least one facility; and a server configured to individually control the thermal energy, the geothermal energy and the electrical energy supplied to the at least one facility according to an environmental state of the at least one facility.

A stand-alone long-distance closed-loop heat energy capture, conveyance, and delivery system, comprises three closed-loop modules in serial communication. The first module is in communication with a first closed-loop piping infrastructure interconnected with a source of heat energy, and has a LBP liquid circulating therein whereby the LBP liquid is converted into its gas phase when flowing through the source of heat energy thereby capturing a portion of heat energy therefrom, and is converted into its liquid phase when flowing through a first heat exchanger that transfers the captured-heat energy to a second closed-loop piping infrastructure wherein also is circulating a LBP liquid. The second closed-loop module may extend for long distances. The captured-heat energy in the second module is transferred to a third closed-loop piping infrastructure wherein is also circulating a LBP liquid. The captured-heat energy is transferred from the third module to a delivery site.

Solar thermal power generation equipment is equipped with a wind turbine, a compressor, a heat receiver that receives sunlight to heat a compressed medium from the compressor, a turbine driven by the compressed medium heated with the heat receiver, a power generator that performs power generation by driving of the turbine, a transmission mechanism that transmits the rotation of the wind turbine to the power generator, and a tower which supports these components. The wind turbine, the compressor, the turbine, and the power generator each constitute an array apparatus. The plurality of array apparatuses are arranged in a vertical direction.

Solar thermal power generation equipment is equipped with a wind turbine, a compressor, a heat receiver that receives sunlight to heat a compressed medium from the compressor, a turbine driven by the compressed medium heated with the heat receiver, a power generator that performs power generation by driving of the turbine, a transmission mechanism that transmits the rotation of the wind turbine to the power generator, and a tower which supports these components. The wind turbine, the compressor, the turbine, and the power generator each constitute an array apparatus. The plurality of array apparatuses are arranged in a vertical direction.

An energy storage system (TES) converts variable renewable electricity (VRE) to continuous heat at over 1000° C. Intermittent electrical energy heats a solid medium. Heat from the solid medium is delivered continuously on demand. Heat delivery via flowing gas establishes a thermocline which maintains high outlet temperature throughout discharge. The delivered heat which may be used for processes including power generation and cogeneration. In one application, the energy storage system provides higher-temperature heat to a solid oxide electrolysis system to maintain in an electrolysis operating temperature range during operation and nonoperation, thereby increasing the efficiency of the temperature control.

A gravitational atmospheric solar pump is provided. The gravitational atmospheric solar pump has a (preferably) cylindrical tube which is placed in a vertical orientation. Air enters the cylindrical tube at the top of the tube and travels downward exiting the opening at the bottom of the tube. An air flow initiator, such as a fan, creates the pressure needed to move the air downward. Blades located within the tube are rotated by the moving air. The pump captures energy by converting the motion of the blades to electricity through a connection to a generator. Throughout the tube, the air remains at a generally consistent density and temperature. The tube represents an open-air system, and air discharged at the bottom of the tube is returned to a higher elevation using solar energy separate from the energy requirements of the apparatus.