Implementations of the disclosed subject matter provide a window, an energy and light producing device including at least one transparent photovoltaic device and at least one non-transparent Organic Light Emitting Device (OLED) in an optical path of the window. A controller may control the operation of the non-transparent OLED of the energy and light producing device. An energy storage device may be electrically coupled to the controller and the energy and light producing device to store energy generated by the transparent photovoltaic device and to power the non-transparent OLED. In some implementations, a LED or OLED may be mounted in the frame of the window and may be powered by the energy storage device.

A bifacial photovoltaic solar panel and solar panel assembly. The panel includes at least one transparent layer; bifacial photovoltaic cells positioned and arranged to absorb irradiance incident thereon on both sides; and at least one optical element. To form the assembly, the panel is connected to a mounting assembly. When in use, the mounting assembly obscures at least a portion of the panel second side, some cells receiving less irradiance via the panel second side than other cells due to the mounting assembly obscuration, and the optical element is arranged to direct irradiance incident thereon via the panel first side onto the first sides of the subset of cells whereby at least a portion of irradiance having been prevented from reaching the second sides of the cells by the mounting assembly is compensated for by irradiance reflected by the optical element onto the first sides of the cells.

A Multiple Bifacial Photovoltaic Transparent Panels Thermal Triangles Reflective Minors Ensemble system which is configured to be oriented towards the sun and relative to the horizon, the mirrors reflecting the sunray to the bifacial PV panels front, back and underside faces. There is a plurality of rhombus or trapeze shaped sunray path openings, mounted on a small footprint, above a two axes tracking mechanism. Further, an Micro-Electric Power Station MEPS capable of obtaining energy from a plurality of Rear/Back and side sun ray reflectors sources, located in between various bifacial photovoltaic transparent solar thermal panels. The reflector sources may include an integrated laminated mirror film around the inside of a casing/envelope of a rhombus thin (e.g. glass) box or of transparent sunrays magnifying concentrator envelope balloon. The MEPS facility may be mounted above streets and traffic junctions, on a structure which may be referred to as Micro-Grid Electric Pylons MGEP.

A solar power plant comprising a pliable mat having a photovoltaic (PV) module fixed thereon by means of an attachment assembly which comprises at least one elongate module profile secured to an edge of the PV module, and a corresponding elongate mat profile attached to the mat, and the profiles are configured such that the PV module is secured to the mat by bringing the module profile into contact with the corresponding mat profile. There is also provided a method of installing a floating photovoltaic power plant.

A glass sealing system includes a glass portion and a first adhesive layer disposed along an exterior surface of the glass portion. The glass sealing system also includes a cover with a first surface secured to the first adhesive layer and a second surface opposing the first surface. The glass sealing system includes a second adhesive layer disposed on the second surface and configured to secure the cover to a support structure. The cover obscures the second adhesive layer from view of a user looking through the glass portion toward the support structure.

An impact-resistant, photovoltaic (IRPV) window system is provided. The system may include an IRPV window coupled to a structure, a controller, and an insurance computing device. The IRPV window may include an impact resistant (IR) layer, a photovoltaic (PV) material that may generate an electrical output, and an electrode coupled to the PV material that may receive the electrical output. The IRPV window may permit a portion of visible light to pass through the IRPV window. The controller may monitor the electrical output and generate a solar profile of the structure based upon the electrical output. The insurance computing device may receive the solar profile and determine if an insurance policy associated with the structure is eligible for a policy adjustment and/or an insurance reward or discount offer.

The use of photovoltaic (PV) cells to convert solar energy to electricity is becoming increasingly prevalent; however, there are still significant limitations associated with the widespread adoption of PV cells for electricity needs. There is a clear need for a high efficiency solar power system that supplies electricity at a competitive cost and that provides for an on-demand supply of electricity as well as energy storage. By combining aspects of concentrated solar power and concentrated photovoltaics, the present invention provides a device that enables the conversion of sunlight to electricity at very high efficiencies and that enables the transmission of thermal energy to heat storage devices for later use. The disclosed device enables transmissive CPV through the use of a multijunction PV cell mounted on a transparent base. The use of a multijunction cell allows for highly efficient absorption of light above the bandgap of the lowest bandgap subcell. The transparent base permits transmission of a high percentage of the remaining light below the bandgap of the lowest bandgap subcell. The present invention also discloses a method of generating electricity through the use of a transmissive CPV device. Sunlight is concentrated onto one or more surfaces of the device. High energy light is absorbed by a multijunction PV cell and converted directly to electricity, while low energy light is transmitted through the device into a thermal storage device, which may then be coupled to a heat engine to generate dispatchable electricity.

A method of producing a photovoltaic cell having a cover, comprising the steps of: providing a photovoltaic cell which comprises a crystalline silicon substrate; providing a transparent substrate; forming an antireflective coating on said transparent substrate to provide a coated transparent substrate; and covering the photovoltaic cell with said coated transparent substrate. The antireflective coating is a hybrid organic-inorganic material having an inorganic portion comprising silicon, oxygen and carbon, and further comprising an organic portion with organic groups connected to the inorganic portion. Methods of producing solar panels, coated glass substrates as well as antireflection coatings are disclosed as well as novel compositions of hybrid organic-inorganic materials.

The present disclosure provides a panel structure for receiving light and generating electricity. The panel structure comprises a panel material that has a light receiving surface. The panel material is at least partially transmissive for light having a wavelength in the visible wavelength range. The panel structure further comprises a photovoltaic material being positioned in or at the panel material. The photovoltaic material is distributed between transmissive areas that are void of the photovoltaic material such that features of the photovoltaic material are sufficiently narrow to be at least largely invisible to the naked eye.

A solar module having on the front a cover plate with an outer surface and an inner surface is described. An optical interference layer for reflecting light within a predefined wavelength range is arranged on the inner surface. The inner surface and/or the outer surface have a patterned region. The patterned region has a height profile with hills and valleys, and a portion of the patterned region is composed of flat segments that are inclined relative to a plane of the cover plate.