The glass panel unit includes a first glass substrate, a second glass substrate, a sealing member, an inside space, and a plurality of spacers. The inside space is hermetically enclosed by the first glass substrate, the second glass substrate, and the sealing member, and has reduced pressure. The plurality of spacers are placed in the inside space. At least one of the first glass substrate and the second glass substrate is a wire-embedded glass panel with a wire structure embedded therein. The plurality of spacers are arranged so as to overlap with part of the wire structure in a plan view.

A thermal engine includes a thermal battery with a thermal mass for storing regenerative wind and solar energy using a solar lens and mechanical friction generated by the rotation of a wind turbine. The thermal engine comprises a thermal battery; a thermal engine; means of charging the thermal battery using natural energy including a solar lens; a wind turbine; and charging by electrical means. The invention further comprises a means of converting stored thermal energy to mechanical power using non-combustible fluids to drive devices such as an electric generator, a water pump; a means of using said thermal energy to directly heat homes and industrial facilities; a means of using said thermal energy for cooling homes and industrial facilities.

An energy collector is disclosed. The energy collector contains an absorber and a working fluid. The working fluid is held in a state of two-phase equilibrium to minimize sensible heating and thus heat losses to the environment. The energy collector may be held under a vacuum to further prevent heat losses to the ambient environment. One or more energy collectors may be connected to other energy collectors, end uses, or thermal energy storage.

An energy collector is disclosed. The energy collector contains an absorber and a working fluid. The working fluid is held in a state of two-phase equilibrium to minimize sensible heating and thus heat losses to the environment. The energy collector may be held under a vacuum to further prevent heat losses to the ambient environment. One or more energy collectors may be connected to other energy collectors, end uses, or thermal energy storage.

A solar thermal collector comprises a solar heat collector tube and a Fresnel reflector film configured to focus incident solar light on the solar heat collector tube. A solar thermal collector assembly, a solar thermal collector module, a cooling apparatus, and a solar cooker comprising the solar thermal collector are also provided. Also provided is a use of a Fresnel reflector film for collecting solar thermal energy.

A solar thermal collector comprises a solar heat collector tube and a Fresnel reflector film configured to focus incident solar light on the solar heat collector tube. A solar thermal collector assembly, a solar thermal collector module, a cooling apparatus, and a solar cooker comprising the solar thermal collector are also provided. Also provided is a use of a Fresnel reflector film for collecting solar thermal energy.

The present invention provides a vacuum heat transfer type efficient solar panel heat absorption system, including a flat plate collector, wherein a heat absorption coil is arranged in the flat plate collector, and a heat absorption coil valve is arranged on the heat absorption coil stretching out from the flat plate collector; a heat exchange coil is arranged in a pressure bearing water tank, a water inlet and a water outlet are formed in the pressure bearing water tank, a vacuum pump is arranged on a heat transfer pipeline, the heat absorption coil, the heat transfer pipeline and the heat exchange coil are all copper tubes, the interiors of the copper tubes are in vacuum states, and heat absorption coating is coated on an outer surface of the heat absorption coil. In the present invention, the interiors of the copper tubes are vacuumized, when a part of energy radiated by the sun is transferred onto the copper tubes in a heat collection plate, this part of energy is directly, quickly and efficiently transferred to a copper coil in the water tank through the copper tubes, as the interiors of the copper tubes are vacuumized, and the polyurethane at the outside of the tubes preserve the heat in the process, the heat transfer efficiency is greatly improved, and the heat loss during the heat transfer of a flowing medium in the tubes in a circulation process is greatly reduced.

There is provided in a first form of an illustrative embodiment a method. The method includes providing a quantity of carbon dioxide in gaseous form within an interior volume of an vessel and contacting the carbon dioxide gas with a heat exchanger disposed within the interior volume of the vessel. The vessel is exposed to solar radiation, wherein the carbon dioxide absorbs radiation in one or more vibration bands of the carbon dioxide, the absorbed radiation obtained from the solar radiation. Heat within the first quantity of carbon dioxide produced by collisional thermalization of the absorbed radiation is transferred, via the heat exchanger, to a heat transfer medium within the heat exchanger and in fluid communication with an external environment of the vessel.

Provided is a vacuum solar thermal collector module including a case having an open top and an internal space, a vacuum thermal collector panel provided inside the case and having a vacuum inside, and an insulation disposed between the vacuum thermal collector panel and the case to block heat transfer, wherein the vacuum thermal collector panel is plural and arranged in a horizontal direction inside the case.

Provided is a vacuum solar thermal collector module including a case having an open top and an internal space, a vacuum thermal collector panel provided inside the case and having a vacuum inside, and an insulation disposed between the vacuum thermal collector panel and the case to block heat transfer, wherein the vacuum thermal collector panel is plural and arranged in a horizontal direction inside the case.