A dispatchable storage combined cycle power plant comprises a topping cycle that combusts fuel to generate electricity and produce hot exhaust gases, a steam power system, a heat source other than the topping cycle, and a thermal energy storage system. Heat from the heat source, from the thermal energy storage system, or from the heat source and the thermal energy storage system is used to generate steam in the steam power system. Heat from the topping cycle may be used in series with or in parallel with the thermal energy storage system and/or the heat source to generate the steam, and additionally to super heat the steam.

According to examples of the disclosure there is provided a heat-driven pumping system and a method of pumping. The heat-driven pumping system comprises a closed circuit for a first liquid. The closed circuit comprises a vaporization portion. The vaporization portion is configured to receive heat from an external source. The vaporization portion is configured to cause vaporization of first liquid within the vaporization portion. Vaporization of first liquid within the vaporization portion thereby increases an amount of gas in the closed circuit. The closed circuit is sealed such that the increase in the amount of gas increases a pressure exerted on the first liquid. The heat-driven pumping system comprises a transfer means. The transfer means is configured to convert the pressure exerted on the first liquid into a pumping force. The pumping force is transferred to a pumping vessel for pumping a second liquid.

Disclosed herein is a method comprising heating a strontium-containing compound using radiation in a first reactor; decomposing the strontium-containing compound into an oxide and carbon dioxide as a result of heat generated by the exposure to the radiation; reacting the oxide and the carbon dioxide in a second reactor; where the oxide and carbon dioxide react to produce heat; heating a working fluid using the heat produced in the second reactor; and driving a turbine with the heated working fluid to generate energy. Disclosed herein too is a composition comprising strontium carbonate; and strontium zirconate; where the mass ratio of strontium carbonate to strontium zirconate 2:8 to 8:2.

A system and method removes thermal decomposition components from biphenyl and/or diphenyl oxide-based heat transfer fluids. Light, volatile decomposition components including benzene, water, hydrogen and phenol leave the system for vapor recovery, chemical adsorption or thermal decomposition. Dimerized and polymerized heavy components such as biphenyl phenyl ether, terphenyl and related isomers are concentrated and recovered. The system can be a continuous, semi-continuous or batch operation. Solar electric plants employing the system can use solar field fluids and heating to operate the system during generator operation hours. A wash system operating at or near atmospheric pressure concentrates heavy thermal decomposition components while allowing removal of light, volatile decomposition components for separation from the majority of the thermal fluid components. Temperature-controlled condensation of the majority of the thermal fluid components allows collection of the thermal fluid, while allowing light, volatile decomposition components to be removed prior to vent processing.

An apparatus including a photovoltaic panel; a first fluid container thermally attached to a bottom of the photovoltaic panel; and a temperature sensor for sensing temperature of a fluid inside the first fluid container is part of a sub-system for a power generation system using solar energy. The sub-system further includes a heating assembly, including a second fluid container, a second temperature sensor, and an electrical heating element. The second fluid container is fluidically connected to the first fluid container. The heating element is configured to heat the pre-heated fluid in the second fluid container to its vapor state. The sub-system additionally includes a turbine generator fluidically connected to the second fluid container to generate AC power from the vapor. A system employing a plurality of sub-systems and a method for using the sub-systems are also provided.

An apparatus including a photovoltaic panel; a first fluid container thermally attached to a bottom of the photovoltaic panel; and a temperature sensor for sensing temperature of a fluid inside the first fluid container is part of a sub-system for a power generation system using solar energy. The sub-system further includes a heating assembly, including a second fluid container, a second temperature sensor, and an electrical heating element. The second fluid container is fluidically connected to the first fluid container. The heating element is configured to heat the pre-heated fluid in the second fluid container to its vapor state. The sub-system additionally includes a turbine generator fluidically connected to the second fluid container to generate AC power from the vapor. A system employing a plurality of sub-systems and a method for using the sub-systems are also provided.

Methods, systems, and devices are provided for thermal enhancement. Thermal enhancement may include absorbing heat from one or more devices. In some cases, this may improve the efficiency of the one or more devices. In general, a phase transition may be induced in a storage material. The storage material may be combined with a freeze point suppressant in order to reduce its melt point. The mixture may be used to boost the performance of device, such as an electrical generator, a heat engine, a refrigerator, and/or a freezer. The freeze point suppressant and storage material may be separated. By delaying the periods between each stage by prescribed amounts, the methods, systems, and devices may be able to shift the availability of electricity to the user and/or otherwise boost a device at different times in some cases.

A solar energy capture, conversion and storage system for use on a roof of a building for capturing and converting incident solar radiation to heat and electricity. The invention provides an optimized solar energy capture and conversion system that monitors immediately available incident radiation comprising a mounting structure which supports a matrix in which is embedded a conduit containing a working fluid. The fluid or fluid mixture includes at least one hydro-fluoro-ether (HFE). Valves are arranged to open/close ports which connect the solar energy capture system to either a combined heat/electrical generating system or an energy storage system that incorporates a phase change material to store heat energy. Control of the valves is supervised by an energy management system.

The invention relates to a device and a method for preventing floods in the event of a river carrying floodwater. At least one mainline is provided which leads from the region of the floodplain to a collection basin and has one or more pumps in order to pump part of the floodwater through said mainline to the aforementioned collection basin in the event of floodwater, the base of said collection basin lying at a higher level than the riverbed such that electric energy is converted into potential energy of the water during the operation of the at least one pump. According to the method, the electric energy for operating the at least one pump is drawn from a local energy store or is converted in situ from a third energy form which differs from electric energy and hydropower. This is achieved using a device for drawing the electric energy for operating the at least one pump from a local energy store or converting the electric energy in situ from a third energy form which differs from electric energy and hydropower.

A thermobimetal heat driven turbine having a rotor, and a series of vanes extending from the rotor wherein the vanes comprise two or more separate materials laminated together, said two separate materials having different coefficients of expansion whereby exposure to a heat source causes the two separate materials to expand at different rates thereby re-shaping the vanes to drive the rotor. The rotating turbine is thus able to generate power using direct heat from an energy source. The heat source may be radiant, convection and/or conduction type heat.