A photovoltaic module for a satellite solar generator, and a flexible satellite solar generator are disclosed including a module having a printed circuit board comprising a substrate made of an insulating material and conductive traces, at least two chains of photovoltaic cells mounted on the face of the substrate supporting the electrically conductive traces and which are connected to the traces such that the traces establish an electrical connection between the chains of cells, and a protective layer that is optically transparent within a range of wavelengths corresponding to the cells' range of photovoltaic conversion, the layer being attached to the printed circuit board so as to cover at least all of the photovoltaic cells and all of the electrically conductive traces of the printed circuit board.

A photovoltaic module for a satellite solar generator, and a flexible satellite solar generator are disclosed including a module having a printed circuit board comprising a substrate made of an insulating material and conductive traces, at least two chains of photovoltaic cells mounted on the face of the substrate supporting the electrically conductive traces and which are connected to the traces such that the traces establish an electrical connection between the chains of cells, and a protective layer that is optically transparent within a range of wavelengths corresponding to the cells' range of photovoltaic conversion, the layer being attached to the printed circuit board so as to cover at least all of the photovoltaic cells and all of the electrically conductive traces of the printed circuit board.

Provided are a photovoltaic module, comprising a solar cell string having a plurality of solar cells arranged in sequence, adjacent solar cells being connected by solder strips, the solder strip being connected to a front surface of one solar cell and to a back surface of the other solar cell, a long-side dimension of the solar cell being within a range of 150 mm to 220 mm; two protective adhesive layers respectively covering front and back surfaces of the solar cell string, a dimensional difference between thicknesses of one protective adhesive layer and the solder strip being defined as first thickness, a ratio of the first thickness to the thickness of one protective adhesive layer being not less than 0 and not greater than 20%; a transparent plate covering the protective adhesive layer on the front surface; and a back plate covering the protective adhesive layer on the back surface.

A photovoltaic assembly includes a cell unit layer, a backplate and a reflective layer. The backplate is provided on a back side of the cell unit layer, and one side of the backplate away from the cell unit layer is provided with at least one junction box. The reflective layer is disposed between the cell unit layer and the backplate. The reflective layer includes a plurality of reflective longitudinal strips. Each of the plurality of reflective longitudinal strips covers edges of cell chips within at least one cell string. At least one of the plurality of reflective longitudinal strips is broken at a location adjacent to a cell chip covered by the junction box so as to form at least one opening.

A photovoltaic assembly includes a cell unit layer, a backplate and a reflective layer. The backplate is provided on a back side of the cell unit layer, and one side of the backplate away from the cell unit layer is provided with at least one junction box. The reflective layer is disposed between the cell unit layer and the backplate. The reflective layer includes a plurality of reflective longitudinal strips. Each of the plurality of reflective longitudinal strips covers edges of cell chips within at least one cell string. At least one of the plurality of reflective longitudinal strips is broken at a location adjacent to a cell chip covered by the junction box so as to form at least one opening.

The disclosure provides a solar cell and a back contact structure thereof, a photovoltaic module, and a photovoltaic system. The back contact structure includes a first doped region having an opposite polarity to a silicon substrate and a second doped region having a same polarity as the silicon substrate. An isolation region is arranged between the first doped region and the second doped region. The protective region arranged on the first doped region includes an insulation layer and a third doped layer having a same polarity as the second doped region. An opening is provided in the protective region to connect the first conductive layer to the first doped region. In the present invention, scratches caused by belt transmission in an existing cell fabrication process is resolved.

A solar cell including at least a first layer made of a semiconductor material for absorbing photons from light radiation and releasing charge carriers, and at least one conductive layer, overlapping the first layer, adapted to allow the light radiation to enter into the solar cell towards the first layer and to collect the charge carriers released by the first layer, the solar cell where the conductive layer includes at least three overlapped layers, including a transparent intermediate metal layer, made of metal, and two transparent oxide layers, made of a conductive oxide, where the two oxide layers are an inner oxide layer and an outer oxide layer surrounding the transparent intermediate metal layer to provide a low resistance path for the electrical charges and to maximize the amount of light radiation entering the solar cell. The embodiments also include a solar cells module including said solar cell.

A tandem solar cell according to an embodiment includes a top cell string, a bottom cell string, a top cell module, a first string connection, a bottom cell module, and a second string connection. The top cell string is formed by electrically connecting a plurality of top cells. The bottom cell string is formed by electrically connecting a plurality of bottom cells. The bottom cell string is arranged so as to overlap the top cell string in a plan view in a thickness direction of the top cell. The first string connection includes a first extending portion extending to an outside of the top cell module in the plan view. A plurality of bottom cell strings are electrically connected to the bottom cell module. The first extending portion and the second extending portion are arranged apart from each other in the plan view.

A tandem solar cell according to an embodiment includes a top cell string, a bottom cell string, a top cell module, a first string connection, a bottom cell module, and a second string connection. The top cell string is formed by electrically connecting a plurality of top cells. The bottom cell string is formed by electrically connecting a plurality of bottom cells. The bottom cell string is arranged so as to overlap the top cell string in a plan view in a thickness direction of the top cell. The first string connection includes a first extending portion extending to an outside of the top cell module in the plan view. A plurality of bottom cell strings are electrically connected to the bottom cell module. The first extending portion and the second extending portion are arranged apart from each other in the plan view.

In an example, the present invention provides a method of manufacturing a solar module. The method includes providing a substrate member having a surface region, the surface region comprising a spatial region, a first end strip comprising a first edge region and a first interior region, the first interior region comprising a first bus bar, a plurality of strips, a second end strip comprising a second edge region and a second interior region, the second edge region comprising a second bus bar, the first end strip, the plurality of strips, and the second end strip arranged in parallel to each other and occupying the spatial region such that the first end strip, the second end strip, and the plurality of strips consists of a total number of five (5) strips. The method includes separating each of the plurality of strips, arranging the plurality of strips in a string configuration, and using the string in the solar module.