A solar panel module including a cover, a back plate, at least two solar panels, and at least a dark insulating layer is provided. The solar panels are configured between the cover and the back plate and arranged along a direction. There is a separating gap of a width arranged between the two adjacent solar panels. In addition, the dark insulating layer is disposed in the separating gap.

A solar panel module including a cover, a back plate, at least two solar panels, and at least a dark insulating layer is provided. The solar panels are configured between the cover and the back plate and arranged along a direction. There is a separating gap of a width arranged between the two adjacent solar panels. In addition, the dark insulating layer is disposed in the separating gap.

A thin-film solar module with a substrate and a layer structure applied thereon. The layer structure has a rear electrode layer, a front electrode layer, and an absorber layer arranged between the rear electrode layer and the front electrode layer. The absorber layer has doping of a first conductor type, while the front electrode layer has doping of a second conductor type. Serially connected solar cells are formed in the layer structure by patterning zones having a first patterning trench subdividing the rear electrode layer, a second patterning trench subdividing the absorber layer, and a third patterning trench subdividing the front electrode layer.

A flexible circuit that allows a standardized connection interface to connect flexible solar cell(s) for easy integration into electronics devices. This interconnection scheme does not limit the intrinsic solar cell flexibility and may conform to standard design practices in electronic device manufacturing. In an aspect, a solar module is described that includes one or more solar panels and a flexible trace or interconnect having conductive wires inside an insulation material. In another aspect, an electronic device is described that includes a circuit board, one or more solar panels and a flexible trace or interconnect having conductive wires inside an insulation material. The electronic device may be an internet-of-things (IoT) device or an unmanned aerial vehicle (UAV), for example. In yet another aspect, a lighting module is described that includes one or more lighting panels and a flexible trace or interconnect having conductive wires inside an insulation material.

A flexible circuit that allows a standardized connection interface to connect flexible solar cell(s) for easy integration into electronics devices. This interconnection scheme does not limit the intrinsic solar cell flexibility and may conform to standard design practices in electronic device manufacturing. In an aspect, a solar module is described that includes one or more solar panels and a flexible trace or interconnect having conductive wires inside an insulation material. In another aspect, an electronic device is described that includes a circuit board, one or more solar panels and a flexible trace or interconnect having conductive wires inside an insulation material. The electronic device may be an internet-of-things (IoT) device or an unmanned aerial vehicle (UAV), for example. In yet another aspect, a lighting module is described that includes one or more lighting panels and a flexible trace or interconnect having conductive wires inside an insulation material.

The present invention relates to new energy field, and more particularly to a tracking type portable thin-film solar power generating device. Conventionally, commercially available thin-film solar power generation devices have a fixed inclination angle and do not have a tracking function, which results in a low power generation capacity. Therefore, it is difficult to satisfy the needs of outdoor activities. Since photoelectric conversion rate is difficult to be effective improved in the short-term, how to increase the power generation of thin-film solar cells has become an urgent technical problem in the field of thin-film solar power generation. The present invention uses folded type and assembled type thin-film solar cells, articulated devices, and a driving device to form a movable support, so that an inclination angle of an integrated polygonal thin-film solar cell can be changed with time for tracking the sun.

The present invention relates to new energy field, and more particularly to a tracking type portable thin-film solar power generating device. Conventionally, commercially available thin-film solar power generation devices have a fixed inclination angle and do not have a tracking function, which results in a low power generation capacity. Therefore, it is difficult to satisfy the needs of outdoor activities. Since photoelectric conversion rate is difficult to be effective improved in the short-term, how to increase the power generation of thin-film solar cells has become an urgent technical problem in the field of thin-film solar power generation. The present invention uses folded type and assembled type thin-film solar cells, articulated devices, and a driving device to form a movable support, so that an inclination angle of an integrated polygonal thin-film solar cell can be changed with time for tracking the sun.

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.

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.

A solar cell assembly includes a plurality of solar cells and an inter-cell region provided between adjacent ones of the solar cells included in the plurality of solar cells. Each of the solar cells and the inter-cell region includes: a semiconductor substrate having a first conductivity type and having a first main surface and a second main surface that face away from each other; a first amorphous semiconductor layer having a second conductivity type and being provided on a first main surface side of the semiconductor substrate; an insulating layer provided on part of the first amorphous semiconductor layer; and a first transparent conductive film provided on the first amorphous semiconductor layer so as to cover the insulating layer. In a plan view of the solar cell assembly, the insulating layer is provided along the inter-cell region and partially overlapping the inter-cell region.