This invention provides a light diffusion member for an interconnector that enables the amount of light incident on the surface of a solar cell to be increased compared with the related art and achieves excellent power generation efficiency, and an interconnector for solar cells that comprises the light diffusion member.

The light diffusion member for an interconnector 3 is disposed on the surface of an interconnector 1 for connecting adjacent solar cells 6 opposite to the solar cells 6, and the light diffusion member comprises a light diffusion layer 3a containing a resin and inorganic particles.

A system for collecting light energy through smaller photovoltaic cells (PV cell) such that the length of the PV cell is much greater than the width. The PV cells may be linear strung together and placed within a recess of a frame or pan that is part of a PV module. The PV module includes a lens and waveguide which provide advantages for focusing and concentrating the light energy by positioning a waveguide over the smaller PV cell and engaging the PV cell with a lens such that the lens is held by the frame.

An inflatable non-imaging non-tracking solar concentrator based Concentrating Photovoltaic (CPV) system powered airship consists of a conventional airship with an upper transparent cover and an array of inflatable non-imaging non-tracking concentrator based CPV modules. Where in, the inflatable non-imaging non-tracking solar concentrators are inflated with helium or hydrogen and fused into the structure of the airship to generate lifting force and concentrate sunlight to supply power simultaneously. The introduction of the CPV system into the airship dramatically reduces the cost and significantly raises conversion efficiency of the photovoltaic system without adding any extra weight to the airship. The expansion of the airship will both increase the buoyant force and power supply.

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.

An energy harvesting electro-optic display is disclosed comprising a photovoltaic cell that converts part of the incident light to electric current or voltage, wherein the electric current or voltage is used for the operation of the electro-optic display upon the conversion or stored in a storage component to be used for the operation of the display.

A solar cell, a method for producing a solar cell, and a solar module are provided. The solar cell includes: an N-type substrate and a P-type emitter formed on a front surface of the substrate; a first passivation layer, a second passivation layer and a third passivation layer sequentially formed over the front surface of the substrate and in a direction away from the P-type emitter, and a passivated contact structure disposed on a rear surface of the substrate. The first passivation layer includes a first Silicon oxynitride (SiO.sub.xN.sub.y) material, where x>y. The second passivation layer includes a first silicon nitride (Si.sub.mN.sub.n) material, where m>n. The third passivation layer includes a second silicon oxynitride (SiO.sub.iN.sub.j) material, where a ratio of i/j∈[0.97, 7.58].

An energy harvesting electrophoretic display is disclosed comprising a photovoltaic cell that converts part of the incident light to electric current or voltage, wherein the electric current or voltage is used for the operation of the electrophoretic display upon the conversion or stored in a storage component to be used for the operation of the electrophoretic display.

A solar power method is provided using two-stage light concentration to drive concentrating photovoltaic conversion in conjunction with thermal collection. The method concentrates light rays received in a plurality of transverse planes towards a primary linear focus in an axial plane, which is orthogonal to the transverse planes. T band wavelengths of light are transmitted to the primary linear focus. R band wavelengths of light are reflected towards a secondary linear focus in the axial plane, which is parallel to the primary linear focus. The light received at the primary linear focus is translated into thermal energy. The light received at the secondary linear focus is focused by optical elements along a plurality of tertiary linear foci, which are orthogonal to the axial plane. The focused light in each tertiary primary focus is focused into a plurality of receiving areas, and translated into electrical energy.

The process for manufacturing a photovoltaic concentrator comprising a photovoltaic substrate (2) equipped with a plurality of photovoltaic cells (5), and an optical structure (1) comprising a first optical-lens stage (4) and a second optical-lens stage (3) that are intended to optically interact with each other, includes (i) providing a mould (6); and (ii) simultaneously forming the first optical-lens stage (4) and the second optical-lens stage (3) using said provided mould (6), and implementing a step of filling said mould (6) with a material (100), especially by injecting or pouring said material (100).

Disclosed is a photovoltaic power generation module having a single layer structure in which a pattern glass and a solar cell module are integrated. The disclosed photovoltaic power generation module comprises: a pattern glass comprising a base member, and a pattern member provided thereon in which an optical pattern is formed; a solar cell module provided with a solar cell; a plurality of supportive adhering parts in a pillar shape adhered to the pattern member; and a filler filled between the supportive adhering part and the solar cell module, wherein the pattern glass and the solar cell module are integrated through the supportive adhering parts and the filler, and the height of the supportive adhering parts are configured to be greater than the height of the pattern member so that a gap for forming an air layer between the pattern member and the filler can be provided.