Photovoltaic (PV) assemblies and electrical connections for interconnecting PV modules to form PV arrays are described herein. The PV assemblies can include angled connector terminals to electrically mate with power connector ports of the PV modules. A power connector port can face a corner of a PV module. The electrical connections of the PV assemblies can simplify cable management and facilitate flexibility in arrangement and interconnection of PV modules and PV arrays.

Disclosed is a photovoltaic cell including a first electrode and a second electrode having transparency and disposed facing each other, and a photovoltaic cell layer disposed between the first and second electrodes, and configured to produce electric energy by absorbing a part of incident light, wherein the photovoltaic cell layer includes a plurality of unit cells disposed in a specific distance from each other and formed with a plurality of slits for polarizing the incident light, and a transparent insulator disposed in the plurality of slits.

Disclosed is a photovoltaic cell including a first electrode and a second electrode having transparency and disposed facing each other, and a photovoltaic cell layer disposed between the first and second electrodes, and configured to produce electric energy by absorbing a part of incident light, wherein the photovoltaic cell layer includes a plurality of unit cells disposed in a specific distance from each other and formed with a plurality of slits for polarizing the incident light, and a transparent insulator disposed in the plurality of slits.

An array of antenna assemblies each generate solar power and utilize the generated solar power at that antenna assembly, which enables large amounts of power to be generated. An antenna assembly having a flat antenna layer forming a first outer surface of said antenna assembly, a flat solar layer forming a second outer surface of said antenna assembly, and a flat structural layer having a flat support structure sandwiched between the antenna layer and the solar layer. The antenna layer has a flat antenna plate with one or more antennas at the first outer surface of the antenna assembly to communicate with Earth. The solar layer has a flat solar plate with one or more solar cells at the second outer surface of the antenna assembly to receive solar energy and generate power.

An array of antenna assemblies each generate solar power and utilize the generated solar power at that antenna assembly, which enables large amounts of power to be generated. An antenna assembly having a flat antenna layer forming a first outer surface of said antenna assembly, a flat solar layer forming a second outer surface of said antenna assembly, and a flat structural layer having a flat support structure sandwiched between the antenna layer and the solar layer. The antenna layer has a flat antenna plate with one or more antennas at the first outer surface of the antenna assembly to communicate with Earth. The solar layer has a flat solar plate with one or more solar cells at the second outer surface of the antenna assembly to receive solar energy and generate power.

The supporting structure comprises an omega-profile shaped metal support (3) with: horizontal upper portion (4), for vertically supporting photovoltaic panels (2); two flat lower portions (5) extending on both sides of upper portion (4), and connecting portions (6), connecting upper portion (4) with lower portions (5). Lower portions (5) include attaching holes (7) for attaching the lower portions (5) to ground through attaching means (8). Upper portion (4) and connecting portions (6) define inner hole (10) locating a gathering cabling (11) for gathering the electricity collected by each panel (2). The installation comprises photovoltaic panels (2) mounted on supporting structures. Preferably, albedo optimizing elements (21), attached to the metal support (3) are also included for improving capturing of albedo radiation. The invention helps to reduce foundation material, make mechanical and electrical contacts easier and raising gathering efficiency.

A photovoltaic panel wire cover assembly, used with a PV panel having a perimeter trim piece, includes clips, an elongate wire cover and fastener structure. Each clip includes a proximal end and long and short legs, the long leg parallel with and joined to the short leg at the clip proximal end. A gap between the long and short legs is sized for receipt of the trim piece. The wire cover includes a wire-covering housing defining a housing interior and having first and second opposite sides and a first flange extending from the first opposite side and positioned against the long leg. The fastener structure engages the short leg and the first flange to bias the first flange and the long leg therewith towards the short leg. The wire cover can be fastened to the trim piece through the clips without penetrating the PV panel.

Systems and methods for a self-powered wireless wearable sensor system include a photovoltaic (PV) panel array, used as a power source for a wearable sensor. The PV panel array may be attached to an area of the human body exposed to a light source. Exposure to a light source may generate an electric field and power a wearable device sufficiently to support data transmission and continuous monitoring. An integrated self-powered wireless wearable sensor system may include a microfluidic sweat sensor patch that may be connected to lower-power wireless sensor circuitry for regulating power efficiently and may be powered by the PV panel array.

Systems and methods for a self-powered wireless wearable sensor system include a photovoltaic (PV) panel array, used as a power source for a wearable sensor. The PV panel array may be attached to an area of the human body exposed to a light source. Exposure to a light source may generate an electric field and power a wearable device sufficiently to support data transmission and continuous monitoring. An integrated self-powered wireless wearable sensor system may include a microfluidic sweat sensor patch that may be connected to lower-power wireless sensor circuitry for regulating power efficiently and may be powered by the PV panel array.

In various representative aspects, an apparatus for securing conduit to solar panel arrays that are typically installed on roof structures. More specifically, the assembly comprises a mount that is coupled to a solar panel module or a rail-less wire conduit structure for securing wire conduit alongside the perimeter of an array of solar panel modules.