The present disclosure concerns a photovoltaic sandwich panel (1) comprising a photovoltaic element layer (2) provided between a protective front layer (3), and a fiber reinforced back layer (4), wherein: the protective front layer is formed from a compound comprising a first thermoplastic polymer (PI); and the fiber reinforced back layer comprises a second thermoplastic polymer (P2) with a fibrous filler material (F). The disclosure further concerns a method for manufacturing a photovoltaic sandwich panel and an assembly of said panels.

A floating solar power generation system includes a photovoltaic (“PV”) array. The PV array includes a plurality of PV modules mechanically bound together. Each of the PV modules includes solar cells for generating solar power that are embedded within a laminated structure which is compliant to folding or bending in response to wave action on a surface of a waterbody. The laminated structure of each of the PV modules floats in or on the waterbody in intimate contact with the waterbody to cool the solar cells.

A compact, three-dimensional (3D) photovoltaic charging system comprising a photovoltaic unit encased in a transparent housing, a power management unit, and a support base. The photovoltaic unit having non-coplanar photovoltaic surfaces that are positioned at a relative distance and a relative orientation. Compared to conventional flat solar panels, the 3D photovoltaic charging system can collect light vertically, therefore amplifying solar module power density, defined as power output per installation footprint area. A photo-tracking, 3D photovoltaic charging system is also described, having a photovoltaic unit encased in a transparent housing, a power management unit, and means to track a source of electromagnetic radiation. The photo-tracking, 3D photovoltaic charging system tracks a moving light source, resulting in improved light flux intake, and therefore, enhanced electric power output.

Provided herein is a solar energy light collecting device, which includes a light reflection module, a sun tracking module, and a control module. The light reflection module includes reflection units, reflection unit support beams and a support wheel frame assembly. The sun tracking module includes an angle adjustment set, a height adjustment set, and a supporter set. The control module includes a sense control unit and a driving motor. The sense control unit senses the direction of the sunlight and controls the driving motor to drive the sun tracking module, such that the light reflection module faces the direction of the sunlight. Moreover, an additional balance adjustment module can also be adopted to resolve the spatial disposition problem.

A solar panel that attains very low cost/Watt objectives is achieved by applying an optical concentrator with planar symmetry in combination with a simple 1-axis tracking system. The concentrator uses a Cassegrain optical system to provide moderate concentration factors that can be adjusted by varying the ratio of the focal lengths of the concave and convex reflecting surfaces. Concentrator dimensions can be scaled to any convenient size. They can be arrayed in parallel to form a solar panel that has the same form factor as a 1-sun solar panel. One-axis tracking is achieved by simply rotating the collector elements in synchronism so the sun is maintained in the plane of symmetry for each of the collector elements that comprise the panel.

A photovoltaic solar concentrator comprising a non-tracking lens adapted to reach the limits of Etendue conservation for acceptance of a direct and a diffuse solar insolation and to emit a focused light onto an upper surface of a luminescent solar concentrator (LSC). The LSC comprises a crystal with an un-doped semiconductor with high luminescence efficiency in the form of a waveguide that includes a top-hat multi-layer reflector to reflect photo-luminescence within an escape cone of the crystal. A mirror attached to the bottom surface. Mirrors attached to all edges of the crystal except for one of the edges. A solar cell mounted on an un-mirrored edge, or optically connected to the un-mirrored edge of the crystal by a second waveguide, to receive the photo-luminescence trapped within the waveguide.

A solar module in a concentrating solar system including: a box including a top wall, formed from an optical system, and walls; at least one photovoltaic cell placed in the box; and at least one humidity management device. At least one first wall among the walls includes a principal part contained in a plane. The humidity management device includes a housing defined between the first wall and a cover fixed to the first wall including an occultation part and an inner part forming an air film at the occultation part. A moisture-absorbing material is placed in the housing, at least part of the moisture-absorbing material is located on one side of the plane containing the occultation part.

A floating module for producing electricity, comprising: at least one photovoltaic panel, and a floating framework on which the panel is mounted, wherein the photovoltaic panel comprises an upper face and a lower face which are capable of generating electricity by photovoltaic effect, and wherein the floating module further comprises a reflective device capable of reflecting light rays towards the lower face of the panel, the reflective device comprising a plurality of floating reflective balls and/or a tarpaulin which is attached to the framework.

The combination photovoltaic and thermal energy system includes a reverse flat plate solar collector (RFPC) mounted above a ground-based thermal energy storage reservoir and a hybrid photovoltaic-thermal (PV-T) panel mounted above the absorber plate of the RFPC. Heat exchanger pipes or conduits in the RFPC and the PV-T are connected so that the heat exchange fluid is preheated in the PV-T and then passes through the RFPC absorber plate, where it is heated to intermediate temperature ranges. The PV-T panel may be a monofacial PC-T panel, a bifacial PV-T panel, or a trifacial PV-T panel.

Building integrated photovoltaic (BIPV) systems provide for solar panel arrays that can be aesthetically pleasing and appear seamless to an observer. BIPV systems can be incorporated as part of roof surfaces as built into the structure of the roof, flush or forming a substantively uniform plane with roof panels or other panels mimicking a solar panel appearance. Pans supporting BIPV solar panels can be coupled by standing seams, in both lateral and longitudinal directions, to other photovoltaic-supporting pans or pans supporting non-photovoltaic structures, having both functional and aesthetic advantages. In some configurations, adjacent photovoltaic modules may be oriented so that a boundary between an up-roof photovoltaic module and a down-roof photovoltaic module is not noticeable by observers positioned at typical viewing angles of the roof.