A hybrid solar thermal and photovoltaic panel based cogeneration system and heat pump and non-tracking non-imaging solar concentrator based CSP stabilized power generation system comprises a hybrid solar thermal and photovoltaic panel based cogeneration subsystem to cogenerate electricity and heat, a heat pump subsystem to raise the temperature of the cogenerated heat, a non-tracking non-imaging solar concentrator based CSP subsystem to further upgrade the cogenerated thermal energy, a thermal storage to store the cogenerated heat, and a thermal power regeneration system to take the stored cogenerated heat to regenerate power. The power output of the cogeneration subsystem supplemented with the power output from the thermal power regeneration system realizes stabilized power output.

A solar energy device includes a solar panel array including a plurality of solar panels, each of the solar panels being divided into solar sub-panels. The solar sub-panels have unequal shapes but equal areas. Wires electrically connect the solar sub-panels and connect the solar panels. The solar panels are secured on a base which is formed with cutouts to receive the wires. The wires are fixed to the solar sub-panels but are free to move with respect to the base.

A solar thermal cladding structure includes a frame, a membrane extending along the frame, the membrane having a first layer and a second layer, and an inflation blower connected to the membrane and in fluid communication with a space between the first layer and the second layer of the membrane. The frame includes a plurality of connectors and a plurality of beam struts. The plurality of connectors connect the plurality of beam struts together.

A system and method for collecting solar energy wherein the system comprising a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and a plurality of solar panels secured to an outside periphery of the tower. The method comprises providing a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and securing a plurality of solar panels to and around an outside periphery of the tower.

A hybrid solar thermal and photovoltaic panel based cogeneration system and heat pump and non-tracking non-imaging solar concentrator based CSP stabilized power generation system comprises a hybrid solar thermal and photovoltaic panel based cogeneration subsystem to cogenerate electricity and heat, a heat pump subsystem to raise the temperature of the cogenerated heat, a non-tracking non-imaging solar concentrator based CSP subsystem to further upgrade the cogenerated thermal energy, a thermal storage to store the cogenerated heat, and a thermal power regeneration system, to take the stored cogenerated heat to regenerate power. The power output of the cogeneration subsystem supplemented with the power output from the thermal power regeneration system realizes stabilized power output.

A curved surface absorber type solar fluid heater having radially spaced curved surfaces, preferably hemispherical and closed at bottom periphery, defining a closed chamber termed as collector which receives a fluid to be heated. The curved surface absorber type solar fluid heater encompasses two radially spaced transparent curved surfaces preferably hemispherical, closed at bottom periphery, placed over collector termed as a glazing, and an insulated hemispherical hot fluid tank, placed within the cavity of inner curved surface of the collector and bottom insulation. A plurality of plumbing connections is made between the collector and the hot fluid tank with arrangement of non-return valves to prevent backflow of fluid from hot fluid tank towards the collector. An air vent is located at the highest position of the collector. A drain plug is located at a lowest position on the collector.

A solar energy device includes a solar panel array including a plurality of solar panels, each of the solar panels being divided into solar sub-panels. The solar sub-panels have unequal shapes but equal areas. Wires electrically connect the solar sub-panels and connect the solar panels. The solar panels are secured on a base which is formed with cutouts to receive the wires. The wires are fixed to the solar sub-panels but are free to move with respect to the base.

A solar module construction comprises at least one pyramidal support unit with a triangular base and triangular lateral planes as well as photovoltaic units provided on at least one of the lateral planes of the support unit. The support unit includes a supporting frame which spans the triangular base by means of base struts and the lateral planes by means of lateral struts. At least one of the lateral planes is stretched over with a flexible material. On at least one lateral plane photovoltaic units in the form of flexible solar modules are installed on the membrane. A multiplicity of such solar module constructions together forms a solar module array, preferably with solar module pairs, which are composed of two solar module constructions and form a parallelogram.

An integral collector storage solar water heat collecting apparatus comprises an integral solar heat collecting and storage apparatus having one or more solar ray and ambient temperature heat absorbing and storage material(s) which hold said energy within an enclosure, said enclosure having within it one or more heat exchange coils with pressurized water to be heated for the end-user or client from said heat storage. Said heat collector is combined with other system components to provide heated water to users.

A solar window system for a building is provided. The solar window system includes multiple heat generation encasements. Air inside each heat generation encasement is heated by solar energy. The solar window system further includes a storage tank for storing heat from the heated air. The solar window system also includes a set of connection pipes, wherein the set of connection pipes draw cold air from an indoor space inside the building into the plurality of heat generation encasements, connect each of the heat generation encasements to at least two other heat generation encasements, and transfer the heated air from the set of heat generation encasements to the storage tank.