The present disclosure describes an expandable splice configured for reinforcing a tube of a solar owner system, the splice including a top panel, a bottom panel, a first side panel, a second side panel, and at least one beveled corner panel, wherein the first and second side panels are connected to the top and bottom panels either directly or by the at least one beveled corner panel to form a channel therebetween.

The present invention describes a polymeric solar heater that has the advantage of being able to be operated at different pressures, from low to high pressure without having to make adjustments or modifications, since it has grooved reinforcement flanges on the outside of the tank, which prevents the movement of some reinforcement elements allowing to increase the baric capacity of the tank, another advantage that characterizes the present invention is that the casing and the tank are made of polymers, which allow the temperature to be kept inside for longer, given their low coefficient of thermal conduction. Another significant advantage of the polymeric solar heater is that the collectors have integrated thermal receptors that allow them to capture thermal energy more easily, in addition to having mechanical reinforcements that increase the resistance of said collectors against impacts.

A photovoltaic module comprising: a base plate and a photovoltaic laminate that are connected together; wherein the photovoltaic module is configured to be directly connected to a roofing structure and provide roofing functions, and wherein the photovoltaic laminate is removable from the base plate without damaging the base plate and the base plate retains its roofing functions when the photovoltaic laminate is removed.

In one embodiment a solar collector is provided. The collector has a modular heat transfer component, which includes a heat transfer core to heat up a heat transfer fluid in the form of an aerogel. The heat transfer core positioned comprises a light absorption element, and a fluid transfer element in the form of an aerogel. The aero gel comprises voids shaped and dimensioned to support passive pumping of the heat transfer fluid therethrough.

A concentrating solar collector module includes improvements in performance and assemblability. In one configuration, the module includes a reflector having a reflective front surface shaped to concentrate incoming solar radiation onto a focal line, first and second rails, one rail attached to each edge of the reflector, and a set of truss connectors attached to the rails. The truss connectors and rails may form ways that enable constrained sliding engagement of the truss connectors along the rails before attachment of the truss connectors to the rails. The module may also include a plurality of framing members connected to the truss connectors and forming a structural lattice that cooperates with the reflector to lend rigidity to the solar collector module. At least some of the framing members may be disposed in front of the front reflective surface.

A support assembly for supporting one or more photovoltaic modules on a support surface, such a generally flat roof, is disclosed herein. The support assembly includes a ballast tray configured to accommodate one or more ballasts; at least one tubular member coupled to the ballast tray, the at least one tubular member configured to support one or more photovoltaic modules above a support surface; and at least one clamp member coupled to the at least one tubular member. In one or more embodiments, the support assembly further includes at least one channel member coupling said at least one tubular member to said ballast tray. A mounting system including a plurality of support assemblies is also disclosed herein.

The present disclosure describes an expandable splice configured for reinforcing a tube of a solar owner system, the splice including a top panel, a bottom panel, a first side panel, a second side panel, and at least one beveled corner panel, wherein the first and second side panels are connected to the top and bottom panels either directly or by the at least one beveled corner panel to form a channel therebetween.

The present disclosure describes an expandable splice configured for reinforcing a tube of a solar owner system, the splice including a top panel, a bottom panel, a first side panel, a second side panel, and at least one beveled corner panel, wherein the first and second side panels are connected to the top and bottom panels either directly or by the at least one beveled corner panel to form a channel therebetween.

The invention relates to a new way of stabilizing and mounting solar panels in the form of conventional heat exchangers comprising a trough and a glass cover or of a photovoltaic panel on house walls with the aid of frames made of natural or artificial stones which are made break-resistant using fiber materials and are stabilized in such a way that the panels are also break-resistant on impact and can be mounted as self-supporting structures on a wall; furthermore, the panels in particular satisfy high standards in respect of esthetics and are low-maintenance and thus permanently appealing. Multiple solar panels comprising stone frames can form entire stone-solar panel facades.

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.