Disclosed is a tandem solar cell according to an aspect including: a silicon lower cell; a perovskite upper cell disposed on the silicon lower cell; and a bonding layer for bonding the silicon lower cell and the perovskite upper cell between the silicon lower cell and the perovskite upper cell, wherein the front surface portion of the silicon lower cell being in contact with the bonding layer includes a texture structure, the bonding layer includes a first transparent electrode layer formed on the sidewall of the texture structure, a buried layer filling concave portions of the texture structure on the first transparent electrode layer, and a second transparent electrode layer on top surfaces of the buried layer, the first transparent electrode layer and the texture structure.

A colored solar module is provided, in which at least one solar cell is embedded in an encapsulation layer, and a transparent plate is disposed on the encapsulation layer. The transparent plate has a single coating layer containing quartz for attaching onto the encapsulation layer so as to reflect the desired color light.

Apparatus, methods and systems of wireless power distribution are disclosed. Embodiments involve the redirection of collimated energy to a converter, which stores or converts the energy into a more suitable form of energy for at least one specific point-of-use that is coupled to the converter.

The solar cell includes a plurality of light-receiving-side finger electrodes on a light-receiving surface of a photoelectric conversion section having a semiconductor junction. The light-receiving surface of the photoelectric conversion section is covered with a first insulating layer. Each light-receiving-side finger electrodes include: a first metal seed layer provided between the photoelectric conversion section and the first insulating layer; and a first plating metal layer being conduction with the first metal seed layer through openings formed in the first insulating layer. The solar cell includes an isolated plating metal layer pieces contacting neither the light-receiving-side finger electrodes nor the back-side finger electrodes. On the surface of the first insulating layer, an isolated plating metal crowded region is present in a form of a band-shape extending parallel to an extending direction of the light-receiving-side finger electrodes.

A photovoltaic (“PV”) module may comprise an array of freeform micro-optics and an array of PV cells. The PV module may be a flat panel with a nominal thickness smaller than the length and width of the flat panel. An array of lenses may be embedded in an array substrate. The lenses may be coupled to light pipes. The lenses may concentrate light through the light pipes to multi-junction cells. Diffuse light may be transferred through the array substrate to a silicon cell. The lenses and light pipes may be manufactured using a molding and drawing process.

A transparent photovoltaic cell is proposed. The transparent photovoltaic cell may include a transparent substrate, a plurality of micro-pillars arranged on an upper part of the transparent substrate and formed with respective transparent windows, through which incident sunlight transmits, on respective upper parts thereof. The transparent photovoltaic cell may also include a photoelectric converter formed on an upper surface of the transparent substrate between each of the plurality of micro-pillars and on side surfaces of each micro-pillar, and configured to generate power through absorption of incident sunlight.

The present disclosure relates generally to electromagnetic coupling modules employed along the outer periphery of floating solar collector pods that can be introduced onto the surface of a body of water that operate to automatically connect to one another so that proximate pods form a reversible self-assembled physically and electrically coupled array that operate to harvest incident solar radiation and also operate to reduce the degree of evaporative water loss from that body of water. Electromagnetic coupling modules are disclosed featuring normally open electrical connection elements that permit electronic coupling under magnetic attraction for improved electrical safety. Electromagnetic coupling modules are disclosed that are gimbaled to provide for increase flexibility and interconnectivity under angular displacement, such as when a floating solar pod array is subject to strong current, wind and wave forces.

A photovoltaic cell includes a front layer, a rear layer, and an absorber layer between the front layer and the rear layer. The front layer, the rear layer, or both includes a multiplicity of nanostructures having dimensions in a range of about 1 nm to about 1000 nm.

The present invention relates to a method of making a light converting optical system. The method involves providing a first optical layer having a microstructured front surface comprising an array of linear grooves that reflect first light rays using total internal reflection and deflect second light rays using refraction. A thin sheet of reflective light scattering material is positioned parallel to the first optical layer. A second optical layer is provided with a microstructured front surface. A continuous photoabsorptive film layer comprising a light converting semiconductor material is positioned between the first optical layer and the reflective material, with a thickness less than the minimum thickness required for absorbing all light traversing through the film layer. The method further involves providing a light source and positioning the second optical layer on the light path between the light source and the photoabsorptive film layer.

An integrated laminate structure adapted for application in the context of solar technology, wafer technology, cooling channels, greenhouse illumination, window illumination, street lighting, traffic lighting, traffic reflectors or security films, includes a first carrier element such as a piece of plastic or glass, optionally having optically substantially transparent material enabling light transmission therethrough, a second carrier element provided with at least one surface relief pattern including a number of surface relief forms and having at least one predetermined optical function relative to incident light, the second carrier element optionally including optically substantially transparent material enabling light transmission therethrough, the first and second carrier elements being laminated together such that the at least one surface relief pattern has been embedded within the established laminate structure and a number of related cavities have been formed at the interface of the first and second carrier elements. An applicable method of manufacture is presented.