A universal mounting system for supporting a plurality of photovoltaic modules on a sloped support surface, such as a sloped roof, is disclosed herein. The universal mounting system may include one or more support surface attachment devices, each support surface attachment device configured to attach one or more photovoltaic modules to a support surface; and one or more module coupling devices, each module coupling device configured to couple a plurality of photovoltaic modules to one another.

A functional roof construction arrangement for a roof frame of a building, includes a plurality of functional roof modules being assembled together. Each of the functional roof modules includes a module housing and a roof functional unit which includes three different roof functional panel units selectively supported by the module housing at different levels thereof to provide different functions for the building. The roof functional panel units are selectively configured for selectively providing multiple functions of solar energy collection, thermal insulation, sound insulation, wireless network system, and the like.

A functional roof construction arrangement for a roof frame of a building, includes a plurality of functional roof modules being assembled together. Each of the functional roof modules includes a module housing and a roof functional unit which includes three different roof functional panel units selectively supported by the module housing at different levels thereof to provide different functions for the building. The roof functional panel units are selectively configured for selectively providing multiple functions of solar energy collection, thermal insulation, sound insulation, wireless network system, and the like.

Roof panel comprising a photovoltaic module having a top surface, a bottom surface and lateral edges, and at least one rib fixedly connected to the photovoltaic module and transversely, preferably perpendicularly, projecting away from the bottom surface and extending along a lateral edge of the photovoltaic module. The height (h, h1, h2) of the at least one rib increases, preferably continuously increases, in direction along the lateral edge, such that the lower edge of the at least one rib is inclined with respect to the bottom surface and/or the top surface of the photovoltaic module.

A recoverable and renewable heat recovery system includes a variable speed inverter compressor in fluid connection with a first heat exchanger and a second heat exchanger via a fluid circuit. The system further includes a solar thermal collection module positioned on top of the compressor and in fluid communication with the compressor, the first heat exchanger and the second heat exchanger via the fluid circuit. A light intensity sensor is configured to determine light intensity on the solar thermal collection module. The solar thermal collection module is configured to retain solar energy thermal energy to increase fluid pressure in the compressor.

A modular solar-energy and rainwater collection apparatus (10) comprising: a collector mount (12) adapted both for securement to a building and to an angularly-adjustable support (110); a plurality of rainwater collectors (14) supportable by the collector mount (12), each rainwater collector (14) having a base (18), and at least one solar-cell retainer (20), for securing at least one solar cell (22) relative to the base (18) of at least one said rainwater collector (14); and connection means (16), for rigidly interconnecting a plurality of like rainwater collectors (14) so that the bases (18) are in abutted liquid communication with each other thus forming a modular rainwater collection area (36).

A modular solar-energy and rainwater collection apparatus (10) comprising: a collector mount (12) adapted both for securement to a building and to an angularly-adjustable support (110); a plurality of rainwater collectors (14) supportable by the collector mount (12), each rainwater collector (14) having a base (18), and at least one solar-cell retainer (20), for securing at least one solar cell (22) relative to the base (18) of at least one said rainwater collector (14); and connection means (16), for rigidly interconnecting a plurality of like rainwater collectors (14) so that the bases (18) are in abutted liquid communication with each other thus forming a modular rainwater collection area (36).

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

Watertight fastening devices and systems and methods for the employment thereof are disclosed. The disclosed watertight fastening device includes a head, a shank extending away from the head toward a distal end, and a cover extending outwardly and away from the head in the direction of the shank and defining a hollow region between the shank and an inner surface of the cover. The watertight fastening device may be used in conjunction with a solar power installation system that includes a base plate configured to be positioned against an installation surface. The base plate includes an aperture for receiving the shank of the fastener and protrusion surrounding the aperture configured to be received in the hollow region of the fastener, thereby providing an enhanced barrier against moisture reaching the installation surface.