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.

A collector element for collecting solar energy. The collector element is made of metal and comprises at least one elongated central ridge comprising at least one internal flow channel for a heat transfer medium, first and second elongated side ridges at opposite sides of the at least one central ridge and an elongated depression between each two adjacent ridges. At least one side ridge comprises at least one fastening element by means of which at least one substantially solar radiation permeable covering element is to be fastened to the collector element for covering at least the at least one elongated central ridge of the collector element.

Thin film housing structures for collecting solar energy, and associated systems and methods. A representative system includes an enclosure having an interior region, the enclosure further having a support structure that includes a plurality of curved portions. The system further includes a flexible, thin film carried by, and fixed relative to, the curved portions, the thin film being positioned to transmit solar radiation into the interior region. A receiver is positioned in the interior region, the receiver carrying a working fluid. A solar concentrator is positioned in the interior region to direct the solar radiation to the receiver to heat the working fluid. A controller is operatively coupled to the solar concentrator and is configured to adjust a position of the solar concentrator based at least in part on a position of the sun.

Common solar radiation receivers are equipped with a chamber for transmission of an operating gas which is directed along to an absorber for solar radiation for thermal absorption. The absorber has a dome-shaped entry window made of quartz glass, wherein the inner side facing the absorber assumes a nominal interior temperature Ti of at least 950 C. during proper use, preferably at least 1000 C., whereas the outer side facing away from the absorber is exposed to the environment and subject to risk of devitrification. The invention relates to modifying the known solar radiation receiver so that a high absorber temperature can be set and thus a high efficiency of the solar thermal heating is enabled, without increasing the risk of devitrification in the region of the outer side of the entry window.

A heat exchange assembly for heating a pool includes a housing that defines an internal space. The housing has a top that is open. A lid, which is complementary to the top and substantially transparent, is sealably couplable to the housing to cover the top. A tube is loopedly positioned in the internal space. The tube has opposing endpoints that are positioned through the housing. Each of a pair of couplers is coupled singly to the endpoints of the tube. The lid is configured to allow sunlight to pass through the lid into the internal space, wherein the internal space is heated relative to the ambient environment. The tube is configured to transfer heat from the internal space to liquid passing through the tube. The couplers are configured to couple the tube to a reservoir of liquid, such as a pool.

A heliostat contained within a mechanical enclosure is described that optimizes the heliostat for domestic applications by emphasizing features of durability, protection from outside weather, low cost of manufacture, self-powering, light-weight, and aesthetics.

An apparatus for storing and/or converting solar energy into a mechanical and/or electrical energy product in a continuous manner, twenty-four hours a day. The apparatus includes an enclosed volume chamber having a wall formed from transparent material capable of allowing solar energy beams to enter into the chamber, the wall of the chamber having a reflective inner surface for trapping and reflecting the solar energy beams within the chamber, a heat absorbing member located within the chamber for receiving at least a portion of the solar energy beams, an inlet for feeding air into the chamber wherein the air becomes heated, an outlet for allowing the heated air to exit the chamber, and a conversion device for cooperating with the outlet for receiving the heated air and for converting the heated air to mechanical and/or electrical energy. The conversion device can be a plurality of thermophotovoltaic cells or a turbine.

A solar collector that comprises a conduit for a working fluid, and a parabolic trough reflector arranged to focus reflected sunlight onto the conduit. The parabolic trough reflector is arranged to pivot around the conduit.

A heliostat contained within a mechanical enclosure is described that optimizes the heliostat for domestic applications by emphasizing features of durability, protection from outside weather, low cost of manufacture, self-powering, light-weight, and aesthetics.

A heliostat contained within a mechanical enclosure is described that optimizes the heliostat for domestic applications by emphasizing features of durability, protection from outside weather, low cost of manufacture, self-powering, light-weight, and aesthetics.