A high transmittance thin film solar panel includes a transparent substrate, a front electrode layer, a light absorption layer and a rear electrode layer. The light absorption layer is formed with opening patterns with the same width at positions aligned correspondingly to form at least one first opening trench, a plurality of second opening trenches with continuously and periodically sinusoidal-wave shape, and a plurality of third opening trenches parallel to, interlace with or superpose the second opening trenches, and extend in a direction orthogonal to the direction of the first opening trench. The high transmittance thin film solar panel of the present invention is mainly used for green buildings. The opening trenches of the high transmittance thin film solar panel are formed in a manner of curve shape by an oscillating laser head, and can enhance the transmittance by more than about 3% in comparison with the conventional one.

Some embodiments include a kit for supplying solar power in a battery-powered or fuel cell powered unmanned aerial vehicle (UAV) by incorporating flexible solar cells into a component of a UAV, affixing flexible solar cells to a surface of a UAV, or affixing flexible solar cells to a surface of a component of a UAV. The kit also includes a power conditioning system configured to operate the solar cells within a desired power range and configured to provide power having a voltage compatible with an electrical system of the UAV. Another embodiments include a solar sheet configured for installation on a surface of a UAV or on a surface of a component of a UAV. The solar sheet includes a plurality of solar cells and a polymer layer to which the plurality of solar cells are attached.

A balloon comprises an envelope containing a lifting gas and a concentrated solar radiation solar generator. The solar generator includes a reflector, one or two arrays of photovoltaic solar cells forming a first active face directed towards the reflector and a second active face directed towards the exterior of the envelope of the balloon. The reflector, the first active face and the second active face of the array of photovoltaic cells are configured so as to ensure the first active face and the second active face of the array both generate electrical power provided that the rollwise solar misalignment of the reflector is smaller than or equal to 10 degrees in absolute value.

Disclosed are a solar cell and a method for fabricating the same. The solar cell according to the embodiment includes a back electrode layer on a support substrate; a light absorbing layer including a glass frit having sodium on the back electrode layer; and a front electrode layer on the light absorbing layer.

Disclosed are a flexible solar cell apparatus and a method of fabricating the same. The flexible solar cell apparatus includes a support substrate including an internal region and an outer region surrounding the internal region, a plurality of solar cells on the internal region, and a protective layer on the outer region and the solar cells. A top surface of each solar cell is lower than a top surface of the outer region of the support substrate.

A method for producing a back-contacting solar-cell module and a back-contacting solar-cell module. The method includes: providing a first stacked member, wherein the first stacked member includes a first sheet member; a surface of the first sheet member is provided with a plurality of first electrically conducting sites; the first stacked member further includes electrically conducting protrusions that are formed on the first electrically conducting sites of the first sheet member, gluing and insulating space rings at the peripheries of the first electrically conducting sites; providing a second stacked member, wherein the second stacked member includes a second sheet member; a surface of second sheet member is provided with a plurality of second electrically conducting sites; stacking and laminating first stacked member and second stacked member, the electrically conducting protrusions abut second electrically conducting sites, gluing and insulating space rings glue first sheet member and second sheet member together.

A method for producing a back-contacting solar-cell module and a back-contacting solar-cell module. The method includes: providing a first stacked member, wherein the first stacked member includes a first sheet member; a surface of the first sheet member is provided with a plurality of first electrically conducting sites; the first stacked member further includes electrically conducting protrusions that are formed on the first electrically conducting sites of the first sheet member, gluing and insulating space rings at the peripheries of the first electrically conducting sites; providing a second stacked member, wherein the second stacked member includes a second sheet member; a surface of second sheet member is provided with a plurality of second electrically conducting sites; stacking and laminating first stacked member and second stacked member, the electrically conducting protrusions abut second electrically conducting sites, gluing and insulating space rings glue first sheet member and second sheet member together.

A thin film photovoltaic module includes a submodule with a first glass layer, a transparent conducting oxide layer, a thin film semiconductor layer, and a conductive back contact layer. The thin film module may further include a lamination layer and an electrically insulative backing layer. In one embodiment, the module may include a clip-less mounting feature comprising at least a first and second hole formed in the electrically insulative backing layer.

A thin film photovoltaic module includes a submodule with a first glass layer, a transparent conducting oxide layer, a thin film semiconductor layer, and a conductive back contact layer. The thin film module may further include a lamination layer and an electrically insulative backing layer. In one embodiment, the module may include a clip-less mounting feature comprising at least a first and second hole formed in the electrically insulative backing layer.

A photovoltaic module incorporates a lamination including a back-sheet, an array of solar cells supported on the back-sheet, and a transparent protective covering over the array of solar cells. The solar cells are arranged in offset or staggered patterns on the back-sheet to present a more random and less rigid industrial appearance to an observer. In some cases, cleaved solar cell segments are arranged into groups that are staggered on the back-sheet. This allows for finer control of the net voltage produced by a module. In other embodiments, full single wafer solar cells are arranged into larger groups, which themselves are staggered on the back-sheet. In either case, the result is a photovoltaic module with an appearance that is more organic and acceptable to homeowners and architects than traditional modules having cells arranged in rigid aligned rows and columns.