Disclosed is a system for producing electricity, the system comprising a chemical recovery boiler adapted to supply superheated steam to a steam turbine driving a generator, the chemical recovery boiler comprising a first flue discharge channel with a first heat exchanger arrangement; and a lime kiln comprising a second flue discharge channel with a second heat exchanger arrangement; and a circulation for heat transfer medium between the said heat exchanger arrangements. Also disclosed is a method for producing electricity, wherein said heat transfer medium is circulated between said heat exchanger arrangements such that thermal energy may be transferred from the flue gases in the first flue charge channel and/or the second flue discharge channel into the feed water of the chemical recovery boiler and/or into a heat-consuming process.

A heat pump includes a first chamber, a second chamber fluidly coupled with the first chamber, a first and a second spray devices. The first and second chambers contain working fluid flowable between the first and second chambers via a flow passage between the first and second chambers, and a first and a second space above a portion of the working fluid that is within the first and second chambers. First spray device is coupled with the first chamber to heat or cool the first space in the first chamber. Second spray device is coupled with the second chamber to heat or cool the second space in the second chamber. At least one of the heating and cooling of the first space may cause at least one of a compression or expansion of the second space, which may drive a power-extraction unit coupled with the second chamber.

A system for enhancing overall energy production of CSPs through amplification of solar heat collection. In one embodiment, the system comprises a linear solar-thermal concentrator for concentrating solar light comprising a curved surface, two side walls, and an opening; a fluid conduit disposed within the linear solar-thermal concentrator that carries a working fluid through the linear solar-thermal concentrator; and a convection cover disposed over the opening of the linear thermal concentrator that traps heat convection energy within the linear solar-thermal concentrator.

A system for enhancing overall energy production of CSPs through amplification of solar heat collection. In one embodiment, the system comprises a linear solar-thermal concentrator for concentrating solar light comprising a curved surface, two side walls, and an opening; a fluid conduit disposed within the linear solar-thermal concentrator that carries a working fluid through the linear solar-thermal concentrator; and a convection cover disposed over the opening of the linear thermal concentrator that traps heat convection energy within the linear solar-thermal concentrator.

A system for the generation of mechanical or electrical energy from heat energy, where increasing a height or pressure in a liquid chamber of the system containing a liquid increases an efficiency of the system up to a hundred percent or increases such efficiency until a critical temperature or pressure of the vapor (gas) is reached at the bottom of liquid chamber or in the boiler of the system depending upon the increment in height, pressure and the type of liquid used in the system. An increase in height of the system for such increased efficiency can be adjusted to a smaller height by maintaining a series of liquid and gas chambers where the vapor flows through the series of chambers or by adding pressure valves. The heat energy from high to low temperature sources can be convened to mechanical and electrical energy.

Provided is an electric power generating system which exhibits favorable energy recovery efficiency compared to the prior art and, further, can generate not only cold heat but also warm heat. In an electric power generating system where working fluid is circulated in a system of a pressure resistant closed circuit while changing a state of the working fluid, power is generated by converting external heat energy given to the working fluid into kinetic energy, and electric power is generated by driving an electric power generator by the power, a pressure resistant closed circuit is formed of a main circuit and a sub circuit, the main circuit includes an evaporation chamber, an adiabatic expansion chamber, a power generating part, a warming-use heat exchange mechanism, and a liquefied working fluid return means, and the sub circuit includes a heating medium divided flow path, a liquefied auxiliary fluid supply path, a cooling equipment, a second-fluid-to-be-warmed supply path, a warming equipment, and a return flow compression means.

Provided is an electric power generating system which exhibits favorable energy recovery efficiency compared to the prior art and, further, can generate not only cold heat but also warm heat. In an electric power generating system where working fluid is circulated in a system of a pressure resistant closed circuit while changing a state of the working fluid, power is generated by converting external heat energy given to the working fluid into kinetic energy, and electric power is generated by driving an electric power generator by the power, a pressure resistant closed circuit is formed of a main circuit and a sub circuit, the main circuit includes an evaporation chamber, an adiabatic expansion chamber, a power generating part, a warming-use heat exchange mechanism, and a liquefied working fluid return means, and the sub circuit includes a heating medium divided flow path, a liquefied auxiliary fluid supply path, a cooling equipment, a second-fluid-to-be-warmed supply path, a warming equipment, and a return flow compression means.

An energy storage system is disclosed. The energy storage system includes a turbo train drive, a hot heat sink, and a reservoir. The turbo train drive is in mechanical communication with a compressor and an expander. The hot heat sink is in thermal communication between an output of the compressor and an input of the expander. The reservoir is in thermal communication between an output of the expander and an input of the compressor. The compressor and the expander, via the turbo train drive, are operable between a charging function for charging the hot heat sink and a discharging function for discharging the hot heat sink.

Systems, apparatuses and methods in interoperating with multiple clean energy sources, such as pneumatic energy, electrical energy, hydrogen energy and steam energy, with engine configurations employing theses clean energy sources dynamically and synchronously. Further embodiments including fossil fuel energies.

System for storing and using energy quantum mechanically includes an electronic device that produces heat while operating. A quantum heat engine can be in thermal contact with and electrically connected to the electronic device. The heat produced by the electronic device can dissipate to the quantum heat engine. The quantum heat engine can induce a current to bias the electronic device. Methods for storing and using memory resource to convert heat into electrical work, coherence capacitors, methods for quantum energy storage, and quantum heat engines, are also disclosed.