An installation for storing thermal energy is provided. The storage is carried out by the compression and relaxation of a working gas, wherein pump and compressor can be driven by, for example, electric motors which temporarily absorb excess power generated in the power grid. The generated thermal energy is temporarily stored in a cold accumulator and a heat accumulator. According to the invention, a vapor circuit is provided to connect to the heat accumulator and the cold accumulator for discharging the installation, by which a turbine for generating electrical energy can be driven by a generator. Said circuit is implemented by means of another conduit system distinct from the circuit for charging the installation. Advantageously, thermal energy generated from overcapacities in the power grid can thus be reconverted with high yield into electrical energy via a vapor circuit.

An installation for storing thermal energy is provided. The storage is carried out by the compression and relaxation of a working gas, wherein pump and compressor can be driven by, for example, electric motors which temporarily absorb excess power generated in the power grid. The generated thermal energy is temporarily stored in a cold accumulator and a heat accumulator. According to the invention, a vapor circuit is provided to connect to the heat accumulator and the cold accumulator for discharging the installation, by which a turbine for generating electrical energy can be driven by a generator. Said circuit is implemented by means of another conduit system distinct from the circuit for charging the installation. Advantageously, thermal energy generated from overcapacities in the power grid can thus be reconverted with high yield into electrical energy via a vapor circuit.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the body. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the rotary shaft. The heat recovery system collects heat generated in the heat generator. A non-magnetic partition wall is provided in the gap between the heat generator and the magnets.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the body. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the rotary shaft. The heat recovery system collects heat generated in the heat generator. A non-magnetic partition wall is provided in the gap between the heat generator and the magnets.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the rotary shaft. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the body. The heat recovery system collects heat generated in the heat generator.

The disclosed heat generating apparatus includes: a rotary shaft, a heat generator, a plurality of permanent magnets, a magnet holder, and a heat recovery system. The rotary shaft is rotatably supported by a non-rotative body. The heat generator is fixed to the rotary shaft. The magnets are arrayed to face the heat generator with a gap such that magnetic pole arrangements of adjacent ones of the magnets are opposite to each other. The magnet holder holds the magnets and is fixed to the body. The heat recovery system collects heat generated in the heat generator.

A Device to Enhance Radiant Transfer of Heat from the Earth to Outer Space comprising a collector of energy from a renewable energy source, a storage device for the collected electrical energy in a rechargeable battery, a radiant energy emitter plate consisting of an enclosure with supports, radiant energy emitter plate, plate heating elements, insulating elements for reduction of heat loss via conduction from the enclosure and insulating elements for reduction of heat loss via convection from the enclosure, temperature sensor, and a controller device for regulating the connection and flow of gathered energy from the collector to the storage device to the radiant energy emitter plate.

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. An array of bricks incorporating internal radiation cavities is directly heated by thermal radiation. The cavities facilitate rapid, uniform heating via reradiation. Heat delivery via flowing gas establishes a thermocline which maintains high outlet temperature throughout discharge. Gas flows through structured pathways within the array, delivering heat which may be used for processes including calcination, hydrogen electrolysis, steam generation, and thermal power generation and cogeneration. Groups of thermal storage arrays may be controlled and operated at high temperatures without thermal runaway via deep-discharge sequencing. Forecast-based control enables continuous, year-round heat supply using current and advance information of weather and VRE availability. High-voltage DC power conversion and distribution circuitry improves the efficiency of VRE power transfer into the system.

Automatic wind and photovoltaic energy storage system for generation of uninterrupted electricity and energy autonomy, characterized in that it consists of wind machines (A) and photovoltaic generators (B) combined or independent which operate mechanically or electrically connected suitable compressors (Γ1, Γ2, Γ3, Γ4) that compress air at high pressure while simultaneously removing the heat generated by compression with small heat exchangers (E1, E2, E3, E4), by heating diathermic cooling oil and water stored in separate insulated tanks (H1, H2, H3, Z2) they drive it to an airtight tank-serpentine coil type tank (M), where it exits and after passing through the air flow distributor in each group of high pressure crosses the groups of heat exchangers (θ1) in which the flow flows backwards cooling oil, where its thermal charge is transferred and heats the compressed air before entering the gas turbine and expands to a certain pressure lower and temperature lower the original T2. At this point the compressed air flows coming out of the turbine and reheats in the same way as in the first re-heat, that is, by crossing another set of heat exchangers (02) similar to the first one, but at a lower pressure and re-introducing at the same pressure it exited but at the same temperature as the original Ti. To expanding again to a given pressure corresponding to the next stage according to the thermodynamic analysis. The expansion continues with the intermediate reheats according to the specified stages of the thermodynamic analysis, until after the last reheat in the last stage, inject the quantity of water vapor (steam) stored in a separate insulated tank (Z2) into the flow of compressed air expanding the common fluid (compressed air plus steam) at the same pressure and temperature into the turbine (K), achieving approximately a 20% increase in the overall turbine (K) efficiency. The turbine is equipped, by means of a rotary shaft rotary controller, to be able to modulate the supply of compressed air to the turbine head (K). And since the mass flow rate of compressed air is directly proportional to the electricity produced, the generation of electricity produced is identical to the demand Automatic wind and photovoltaic energy storage system for generation of uninterrupted electricity and energy autonomy, characterized in that it consists of wind machines (A) and photovoltaic generators (B) combined or independent which operate mechanically or electrically connected suitable compressors (IT, Γ2,Γ3,Γ4) that compress air at high pressure while simultaneously removi

In a main flow passage, a first heat exchanger, a first heat storage unit, a second heat exchanger, and a second heat storage unit are connected by a heating medium flow passage. The main flow passage allows a heating medium to be circulated. A sub flow passage includes a shortened flow passage which is a part of the heating medium flow passage and branches from the heating medium flow passage between the second heat exchanger and the second heat storage unit and extends to the first heat storage unit. The sub flow passage allows circulation of the heating medium between the first heat storage unit and the second heat exchanger. A first heating means in a middle of the shortened flow passage, the first heating means heating a passing heat medium, and a switching means conducting switching between the main flow passage and the sub flow passage are provided.