A solar energy harvesting assembly having a unique attachment that can be arranged, mounted, moved and attached to new or existing structures. Solar rings are mounted on any vertical structure that may benefit from solar power using an aesthetically pleasing design that is resistant to wind load. The assembly does not require the need for pitch, azimuth or bearing measurements. The assembly is also capable of energy harvesting from reflected light below with the use of bifacial photovoltaic panels. The mounting design allows the solar energy harvest device to be installed on any vertical structure, including light poles, power poles, parking structures and other minimal load bearing structures. Further, the assembly can be attached to water towers, existing radio towers (guyed, monopole, stealth, self-supporting towers) all used to create vast amounts of unshaded vertical space for solar energy harvesting.

A solar energy harvesting assembly having a unique attachment that can be arranged, mounted, moved and attached to new or existing structures. Solar rings are mounted on any vertical structure that may benefit from solar power using an aesthetically pleasing design that is resistant to wind load. The assembly does not require the need for pitch, azimuth or bearing measurements. The assembly is also capable of energy harvesting from reflected light below with the use of bifacial photovoltaic panels. The mounting design allows the solar energy harvest device to be installed on any vertical structure, including light poles, power poles, parking structures and other minimal load bearing structures. Further, the assembly can be attached to water towers, existing radio towers (guyed, monopole, stealth, self-supporting towers) all used to create vast amounts of unshaded vertical space for solar energy harvesting.

Foldable solar power systems are disclosed herein. In some embodiments, a solar power system includes a support structure mounted to an intermediate bulk container (IBC) or other tank structure. A plurality of solar panels are mounted to the support structure. The support structure is movable between (a) a first configuration for storage and transport and (b) a second configuration for energy generation. In the first configuration, the solar panels are folded adjacent to a sidewall of the IBC. In the second configuration, the solar panels are opened/expanded and generally coplanar with one another. The solar panels can be aligned with a solar energy source in the second configuration to generate electrical energy. The IBC can be filled with a ballast material to anchor the solar panels in the second configuration.

Foldable solar power systems are disclosed herein. In some embodiments, a solar power system includes a support structure mounted to an intermediate bulk container (IBC) or other tank structure. A plurality of solar panels are mounted to the support structure. The support structure is movable between (a) a first configuration for storage and transport and (b) a second configuration for energy generation. In the first configuration, the solar panels are folded adjacent to a sidewall of the IBC. In the second configuration, the solar panels are opened/expanded and generally coplanar with one another. The solar panels can be aligned with a solar energy source in the second configuration to generate electrical energy. The IBC can be filled with a ballast material to anchor the solar panels in the second configuration.

A system for estimating a real-time renewable energy generation quantity according to an embodiment of the present disclosure includes a site setting unit for setting a benchmarking group based on geographical locations of a plurality of renewable energy generation sites and setting a benchmarking site for each benchmarking group, a site generation quantity calculation unit for calculating a real-time generation quantity prediction value of each of sites except the benchmarking site among the sites included in the benchmarking group by using a preset prediction model based on a real-time generation quantity actual-measurement value of the corresponding benchmarking site, and a total generation quantity estimation unit for estimating a total real-time generation quantity of all the sites by summing the calculated real-time generation quantity prediction values for the respective sites and the real-time generation quantity actual-measurement value of the benchmarking site.

A controller of a power generation system provides, in response to a request or a determination to initiate a heating mode for a photovoltaic (PV) array, a first instruction to an inverter coupled between the PV array and a power grid to apply an initial backfeed voltage on PV modules of the PV array. The PV array comprises a plurality of strings of PV modules coupled in parallel, and a first subset of the strings of PV modules are online and a second subset of the strings of PV modules are offline. The controller monitors current data from a set of current sensors that each measure current provided from a corresponding set of strings of PV modules of the plurality of strings of PV modules of the PV array. The controller also provides a second command to the inverter to adjust the backfeed voltage.

A controller of a power generation system provides, in response to a request or a determination to initiate a heating mode for a photovoltaic (PV) array, a first instruction to an inverter coupled between the PV array and a power grid to apply an initial backfeed voltage on PV modules of the PV array. The PV array comprises a plurality of strings of PV modules coupled in parallel, and a first subset of the strings of PV modules are online and a second subset of the strings of PV modules are offline. The controller monitors current data from a set of current sensors that each measure current provided from a corresponding set of strings of PV modules of the plurality of strings of PV modules of the PV array. The controller also provides a second command to the inverter to adjust the backfeed voltage.

The disclosed apparatus, system and method may include at least the delivery of device power to a single or plurality of workstations, which may include at least one power storage unit suitable to supply power to the plurality of workstations; a plurality of control units each associated with one of the plurality of workstations, wherein each of the control units receives power from the at least one power unit, is communicatively associated with the at least one power unit, and comprises a plurality of power outputs suitable to output power from the power unit to devices associated with the respective workstation; and may include at least one ambient energy collector suitable to provide accumulated power to the at least one power unit.

The disclosed apparatus, system and method may include at least the delivery of device power to a single or plurality of workstations, which may include at least one power storage unit suitable to supply power to the plurality of workstations; a plurality of control units each associated with one of the plurality of workstations, wherein each of the control units receives power from the at least one power unit, is communicatively associated with the at least one power unit, and comprises a plurality of power outputs suitable to output power from the power unit to devices associated with the respective workstation; and may include at least one ambient energy collector suitable to provide accumulated power to the at least one power unit.

This specification describes automated reel processes for producing solar modules and solar module reels. In some examples, a method includes receiving a continuous feed of photovoltaic devices on a photovoltaic device sheet. The method includes locating and bypassing one or more defective photovoltaic devices on the photovoltaic device sheet. The method includes installing bussing for the photovoltaic devices on the photovoltaic device sheet. The method includes feeding the photovoltaic device sheet to an encapsulation system to output a photovoltaic module sheet.