Abstract: Apparatuses, systems, and methods are provided for controlling one or more assemblies of an energy generation system. The method may include selecting at least a portion of the one or more assemblies, transmitting at least one control signal associated with the selected at least a portion of the one or more assemblies, receiving the control signal at a communication module of the one or more assemblies, and modifying an operational parameter of the one or more assemblies responsive to the received control signal to avoid contact between the one or more assemblies and livestock. The operational parameter may be associated with a position of the at least a portion of the one or more assemblies relative to a ground surface. The operational parameter may additionally or alternatively be a range of angle of the at least a portion of the one or more assemblies.

Abstract: Apparatuses, systems, and methods are provided for controlling one or more assemblies of an energy generation system. The method may include selecting at least a portion of the one or more assemblies, transmitting at least one control signal associated with the selected at least a portion of the one or more assemblies, receiving the control signal at a communication module of the one or more assemblies, and modifying an operational parameter of the one or more assemblies responsive to the received control signal to avoid contact between the one or more assemblies and livestock. The operational parameter may be associated with a position of the at least a portion of the one or more assemblies relative to a ground surface. The operational parameter may additionally or alternatively be a range of angle of the at least a portion of the one or more assemblies.

Abstract: One embodiment can provide a non-flat photovoltaic roof tile. The non-flat photovoltaic roof tile can include a transparent front cover, a back cover, and a plurality of Si-based photovoltaic structures. The transparent front cover can include a first side and a second side, with the first side comprising at least one non-flat portion and the second side comprising a plurality of flat facets. The flat facets are arranged to follow the contour of the at least one non-flat portion. A respective Si-based photovoltaic structure is positioned between a flat facet of the transparent front cover and the back cover.

Abstract: One embodiment can provide a non-flat photovoltaic roof tile. The non-flat photovoltaic roof tile can include a transparent front cover, a back cover, and a plurality of Si-based photovoltaic structures. The transparent front cover can include a first side and a second side, with the first side comprising at least one non-flat portion and the second side comprising a plurality of flat facets. The flat facets are arranged to follow the contour of the at least one non-flat portion. A respective Si-based photovoltaic structure is positioned between a flat facet of the transparent front cover and the back cover.

Abstract: Photovoltaic modules are constructed having separate positive and negative junction boxes positioned at the corners of each photovoltaic module. A photovoltaic array assembled from these photovoltaic modules can be aligned such that the positive and negative junction boxes connect in an arrangement that minimizes the amount of wire needed to install the photovoltaic array. The arrangement of photovoltaic modules connecting the positive and negative junction boxes on adjacent photovoltaic modules leads to successive rows of photovoltaic modules in the photovoltaic array are oriented in opposing directions.

Abstract: Photovoltaic modules are constructed having separate positive and negative junction boxes positioned at the corners of each photovoltaic module. A photovoltaic array assembled from these photovoltaic modules can be aligned such that the positive and negative junction boxes connect in an arrangement that minimizes the amount of wire needed to install the photovoltaic array. The arrangement of photovoltaic modules connecting the positive and negative junction boxes on adjacent photovoltaic modules leads to successive rows of photovoltaic modules in the photovoltaic array are oriented in opposing directions.

Abstract: A wafer-holding apparatus for electroplating of a solar cell wafer is provided. The wafer has chamfered corners and comprises a plurality of busbar areas, wherein at least one busbar area is near an edge of the wafer. The wafer-holding apparatus includes a plurality of wafer-holding mechanisms for maintaining contact with a wafer. One of the plurality of wafer-holding mechanisms can be longer than at least one other wafer-holding mechanism, thereby facilitating secure contact with the busbar area near the edge of the wafer, which is shorter than other busbar areas on the wafer due to the chamfered corners.

Abstract: The present invention generally relates to a system that can be used to form a photovoltaic device, or solar cell, using processing modules that are adapted to perform one or more steps in the solar cell formation process. The automated solar cell fab is generally an arrangement of automated processing modules and automation equipment that is used to form solar cell devices. The automated solar fab will thus generally comprise a substrate receiving module that is adapted to receive a substrate, one or more absorbing layer deposition cluster tools having at least one processing chamber that is adapted to deposit a silicon-containing layer on a surface of the substrate, one or more back contact deposition chambers, one or more material removal chambers, a solar cell encapsulation device, an autoclave module, an automated junction box attaching module, and one or more quality assurance modules that are adapted to test and qualify the completely formed solar cell device.

Abstract: The present invention generally relates to a sectioning module positioned within an automated solar cell device fabrication system. The solar cell device fabrication system is adapted to receive a single large substrate and form multiple silicon thin film solar cell devices from the single large substrate.

Abstract: The present invention generally relates to a system that can be used to form a photovoltaic device, or solar cell, using processing modules that are adapted to perform one or more steps in the solar cell formation process. The automated solar cell fab is generally an arrangement of automated processing modules and automation equipment that is used to form solar cell devices. The automated solar fab will thus generally comprise a substrate receiving module that is adapted to receive a substrate, one or more absorbing layer deposition cluster tools having at least one processing chamber that is adapted to deposit a silicon-containing layer on a surface of the substrate, one or more back contact deposition chambers, one or more material removal chambers, a solar cell encapsulation device, an autoclave module, an automated junction box attaching module, and one or more quality assurance modules that are adapted to test and qualify the completely formed solar cell device.