A water producing system for a photovoltaic panel may include a moisture collection layer, a liquid transfer mat, and a moisture collection substrate. The moisture collection layer may collect moisture from condensation and direct moisture away from the photovoltaic panel. The liquid transfer mat may include a plurality of tubes through which a chilled heat transfer liquid passes. The moisture collection substrate may include a thermally conductive material. The chilled heat transfer liquid within the liquid transfer mat may absorb heat from the photovoltaic panel and from ambient air through the moisture collection substrate, thereby reducing a temperature of the photovoltaic panel and condensing water on the moisture collection substrate to produce water.

A method of passive cooling for a high concentrating photovoltaic, the high concentrating photovoltaic, includes a photovoltaic receiver, a parabolic dish reflector and a plurality of thermally conductive heat pipes having a direct thermal contact between the receiver and the reflector to transfer excessive heat. The method includes receiving sunlight by the parabolic dish reflector, reflecting the sunlight towards the photovoltaic receiver that converts the sunlight into electricity and heat, transferring the heat through the thermally conductive heat pipes and absorbing the heat by the reflector serving a dual purpose as a heat sink. A reduction in weight and cost is accomplished by incorporating the flat heat pipes.

A system for mounting roof tiles, such as solar tiles 108, is disclosed. The system includes a plurality of base mounting sections 200, a plurality of pin joint 102 and a plurality of overhang sections 104. The base mounting sections are fixed to deck 302 horizontally in spaced disposition parallel to a deck ridge 304, and the pin joints 102 and the overhang sections 104 are fixed to two proximal and distal sides of tiles 108 by adhesives. The tiles 108 are removably installed over a pair of adjacent base mounting sections 200 with the overhang section 104 fastened to the proximal base mounting section 200 and the pin joints 102 fastened to the distal base mounting section 200. After installation, the overhang section 104 overlaps with the tiles 108 of adjacent row on the proximal side thereby preventing ingress of water.

The present disclosure provides a cooling system facilitating thermal management in a solar photovoltaic (PV) module. The cooling system includes an exhaust fan, operatively coupled to an outlet of a central air conditioning module, the outlet carries waste air from the central air conditioning module. A supporting structure is placed at a predefined distance in front of the exhaust fan to support one or more solar panels. The one or more solar panels are tilted at a predefined angle and a predefined azimuth configured to provide maximum surface area of the back units of the one or more solar panels. The exhaust fan is further configured to direct the waste air and surrounding air towards the back units of the one or more solar panels at a predefined temperature.

The present disclosure relates to a simple, lightweight, cost-effective, aesthetically pleasing, and strong system for mounting solar panel tiles (or other tiles/panels) over a roof (surface). The system includes frames (footage) parallelly positioned over the surface using reference bars passing through the frames, and bolts/screws to couple the frames to the surface. The frames include C-shaped grooves at both ends. Each groove is configured with a flat spring that is coupled to the grooves using a spring fixing bracket. Further, Z-shaped clamps are coupled at the bottom surface of the tiles to form a tile assembly. The spring is adapted to be pressed upon application of a force while mounting the tile assembly in the frames, which allows one side of the tile assembly, and the Z-shaped clamp on the other side of the tile assembly to be accommodated and locked in the two opposite C-shaped grooves of the frames.

The invented optical chamber is sealed and encapsulated by a transparent element, a connection element and a transparent substrate or another transparent element. The optical chamber is filled with a transparent fluid and equipped with an electronic sensing and execution component. The surface state, the position and the inclination of the optical chamber are adjusted by the electronic sensing and execution component or through a movable part of the connection element, thereby adjusting the output direction and the focal length of the light beam. The optical chambers are combined in series or in array to constitute an operational solar concentrator adapted to output more than one controlled convergent light beam or a directional light beam to support various light energy applications, such as long-distance lighting, heating, light energy and signal transmission, increased electric energy production, and weather control. The invention is provided to adjust the internal temperature and pressure to adapt to extremely high power and extreme environments. Biotechnology is useful for obtaining the same structure and function.

This application relates to the ventilation of a solar roof. For example, a solar roof can include a solar roof tile and a spacer, batten or other ventilating components to space the solar roof tile from the roof deck, and provide ventilation to the solar roof tile, for reduced operating temperatures and improved efficiency in electricity generation.

A ventilated solar panel system mounted on a roof of a building (1), comprising a plurality of joists (12, 112) arranged substantially normal to an upper ridge (14) of the roof, and extending from the upper ridge (14) to a lower region of the roof, and a set of rectangular solar panels (2, 13), arranged on and supported by the joists (12, 112). The system further comprises a set of electrical fans (25), each fan (25) being arranged in the lower region of the roof and being aligned with one of the joists (12, 112), wherein each fan (25) is configured to create a flow of air towards the ridge (14), and wherein each joist (12, 112), in an end facing one of the fans (25), is formed with a dividing edge (32, 132) configured to divide the flow of air into two sub-flows (26a, 26b), a first sub-flow (26a), directed to a first side of the joist (12, 112), and a second sub-flow (26b) directed to a second side of the joist (12, 112), opposite to the first side.

A connector (7) includes: a first connector part (10) having a first module side connection part connected to one end of an OSFP module in the front (F), having a first substrate side connection part connected to a substrate, and installed on the substrate; a second connector part (20) provided at a position such that the first module side connection part is interposed between the substrate and the second connector part (20), having a second module side connection part connected to one end of an OSFP module at the front (F), having a second substrate side connection part connected to the substrate, and stacked on the first connector part (10); and an intermediate part (30) provided between the first connector part (10) and the second connector part (20), and a cooling flow path in which air flows from the front (F) side toward the rear (R) side of the connector (7) is formed in the intermediate part (30).

A waste heat recovery system for a photovoltaic panel may include an open loop system and a closed loop system. The open loop system includes an electric insulator layer and a moisture collection layer. The moisture collection layer may collect moisture from condensation and to direct moisture away from the photovoltaic panel. The closed loop system may be positioned adjacent to the open loop system. The closed loop system may include a liquid transfer mat that has a plurality of tubes through which a liquid passes to absorb heat from the photovoltaic panel. The open loop system is configured to encourage heat transfer from the photovoltaic panel to the closed loop system.