In accordance with various exemplary embodiments, solar energy shade structures and methods of design and revenue generation are disclosed. These systems comprise structures capable of supporting solar panel at heights greater than 18 feet above their mounting surface. These systems may be installed in confined spaces. These systems also comprise structures that are customizable, allowing an installation to be configured with a desired lighting and environmental effect. The methods discussed herein describe processes for achieving desired design effects based on natural elements. Moreover, the methods discussed herein describe processes for reducing the costs of generating solar energy and/or reducing the costs of providing a solar structure.

In accordance with various exemplary embodiments, solar energy shade structures and support systems are disclosed that have electrical components concealed or screened within columns located under the structure. For example, a solar energy structure may comprise: a solar panel support structure, a plurality of solar panels supported by the solar panel support structure, a plurality of vertical supports connected to the solar panel support structure for supporting the solar panel support structure elevated above a surface, and a column, located under the solar panel support structure. The column comprises an electrical component mounted to the column in a screened manner, wherein the electrical component comprises at least one of a string inverter, a combiner, and a battery.

In accordance with various exemplary embodiments, solar energy shade structures and methods of design and revenue generation are disclosed. These systems comprise structures capable of supporting solar panel at heights greater than 18 feet above their mounting surface. These systems may be installed in confined spaces. These systems also comprise structures that are customizable, allowing an installation to be configured with a desired lighting and environmental effect. The methods discussed herein describe processes for achieving desired design effects based on natural elements. Moreover, the methods discussed herein describe processes for reducing the costs of generating solar energy and/or reducing the costs of providing a solar structure.

In accordance with various exemplary embodiments, solar energy shade structures and support systems are disclosed that have electrical components concealed or screened within columns located under the structure. For example, a solar energy structure may comprise: a solar panel support structure, a plurality of solar panels supported by the solar panel support structure, a plurality of vertical supports connected to the solar panel support structure for supporting the solar panel support structure elevated above a surface, and a column, located under the solar panel support structure. The column comprises an electrical component mounted to the column in a screened manner, wherein the electrical component comprises at least one of a string inverter, a combiner, and a battery.

In accordance with various exemplary embodiments, solar energy shade structures and support systems are disclosed that have electrical components concealed or screened within columns located under the structure. For example, a solar energy structure may comprise: a solar panel support structure, a plurality of solar panels supported by the solar panel support structure, a plurality of vertical supports connected to the solar panel support structure for supporting the solar panel support structure elevated above a surface, and a column, located under the solar panel support structure. The column comprises an electrical component mounted to the column in a screened manner, wherein the electrical component comprises at least one of a string inverter, a combiner, and a battery.

Solar energy shade structures and methods of designing and installing the same are disclosed. These structures are capable of supporting a contiguous planar solar panel support structure at heights greater than 18 feet above their mounting surface. The planar solar panel support structure may contiguously cover at least two areas of different area types, including parking spaces and driving aisles, and may be at least 64 feet long by 64 feet wide. The planar solar panel support structure may have a high panel density defined in that an arrangement of the plurality of solar panels that is uninterrupted by service or access lanes. The majority of the plurality of solar panels may be fixed at an angle that would be non-optimal for energy generation in each individual panel of the majority of the plurality of solar panels, but results in optimal power density for the entire solar energy shade structure.

In accordance with various exemplary embodiments, solar energy shade structures and methods of design and revenue generation are disclosed. These systems comprise structures capable of supporting solar panel at heights greater than 18 feet above their mounting surface. These systems may be installed in confined spaces. These systems also comprise structures that are customizable, allowing an installation to be configured with a desired lighting and environmental effect. The methods discussed herein describe processes for achieving desired design effects based on natural elements. Moreover, the methods discussed herein describe processes for reducing the costs of generating solar energy and/or reducing the costs of providing a solar structure.

Solar energy shade structures and methods of designing and installing the same are disclosed. These structures are capable of supporting a contiguous planar solar panel support structure at heights greater than 18 feet above their mounting surface. The planar solar panel support structure may contiguously cover at least two areas of different area types, including parking spaces and driving aisles, and may be at least 64 feet long by 64 feet wide. The planar solar panel support structure may have a high panel density defined in that an arrangement of the plurality of solar panels that is uninterrupted by service or access lanes. The majority of the plurality of solar panels may be fixed at an angle that would be non-optimal for energy generation in each individual panel of the majority of the plurality of solar panels, but results in optimal power density for the entire solar energy shade structure.

A solar cell device includes an information display, a protective substrate that protects an information display surface of the information display, and a photoelectric conversion element. The photoelectric conversion element is disposed on a surface of the protective substrate. The surface faces the information display surface of the information display. The photoelectric conversion element includes a first electrode including a transparent electrode material, a second electrode including a transparent electrode material, a photoelectric conversion layer disposed between the first electrode and the second electrode and including an organic-inorganic perovskite compound, an electron transport layer, disposed between the first electrode and the photoelectric conversion layer, and a hole transport layer, disposed between the photoelectric conversion layer and the second electrode.

In accordance with various exemplary embodiments, solar energy shade structures and support systems are disclosed that have electrical components concealed or screened within columns located under the structure. For example, a solar energy structure may comprise: a solar panel support structure, a plurality of solar panels supported by the solar panel support structure, a plurality of vertical supports connected to the solar panel support structure for supporting the solar panel support structure elevated above a surface, and a column, located under the solar panel support structure. The column comprises an electrical component mounted to the column in a screened manner, wherein the electrical component comprises at least one of a string inverter, a combiner, and a battery.