An energy storage canopy having solar panels and an energy storage cartridge to charge electric vehicles or the like is provided. The energy storage cartridge includes a power connector that has a power cord with a plug assembly configured to electrically could the battery of an electric vehicle to the energy storage cartridge.

A solar panel bracket with a water conducting function for carrying a plurality of solar photovoltaic panels, comprising: a plurality of first brackets, each of the first brackets is arranged in parallel with each other, each of the first brackets has a first water conducting groove; a plurality of second brackets, each of the second brackets is arranged in parallel with each other, each of the second brackets has a second water conducting groove, the second brackets and the first brackets are arranged perpendicular to each other, and the second brackets and the first brackets surround to form a plurality of square spaces, the solar photovoltaic panels are arranged on the square spaces; and a plurality of third water conducting groove groups, each of the third water conducting groove groups is disposed on the side of each of the first brackets, and each of the third water conducting groove group has a third water conducting groove, and the second water conducting grooves communicate with the third water conducting grooves.

The present invention relates to a supporting system for photovoltaic panels and, in particular, to a supporting beam for photovoltaic panels implemented so that it eases the installation phase thereof, by allowing also the use of robot for the positioning, and at the same time it allows a reduction in production and maintenance costs.

A roof integrated solar power system includes a plurality of solar modules. Each solar module carries a photovoltaic or solar panel with solar cells. Edge regions of the solar module are disposed to the sides of the solar panel and are devoid of solar cells. An electrical component such as a junction box or micro-inverter, or DC optimizer is mounted on top of the solar module within at least one of the edge regions. Cabling for interconnecting the electrical component to electrical components of others of the plurality of solar modules also is located within the side regions. In one embodiment, the electrical component and cabling is disposed within a recess within a side region and covered by a flat access panel. In another embodiment, the electrical component and cabling is located atop the side region and is covered by an access panel in the form of a protective cover strip. The solar modules are installable on a roof in aligned or staggered courses to form the solar power system, and with the installed courses of modules together forming a water barrier protecting the roof.

A roof integrated solar power system includes a plurality of solar modules. Each solar module carries a photovoltaic or solar panel with solar cells. Edge regions of the solar module are disposed to the sides of the solar panel and are devoid of solar cells. An electrical component such as a junction box or micro-inverter, or DC optimizer is mounted on top of the solar module within at least one of the edge regions. Cabling for interconnecting the electrical component to electrical components of others of the plurality of solar modules also is located within the side regions. In one embodiment, the electrical component and cabling is disposed within a recess within a side region and covered by a flat access panel. In another embodiment, the electrical component and cabling is located atop the side region and is covered by an access panel in the form of a protective cover strip. The solar modules are installable on a roof in aligned or staggered courses to form the solar power system, and with the installed courses of modules together forming a water barrier protecting the roof.

A structural support block cooperates with a cone-shaped protrusion in a roof flashing. The support block and protrusion have a through-hole allowing a fastener to secure the support block and flashing to a roof. Cooperation of the support block and the cone-shaped protrusion in the roof flashing diverts water, particularly on sloped surfaces.

A structural support block cooperates with a cone-shaped protrusion in a roof flashing. The support block and protrusion have a through-hole allowing a fastener to secure the support block and flashing to a roof. Cooperation of the support block and the cone-shaped protrusion in the roof flashing diverts water, particularly on sloped surfaces.

The present application provides methods for loading and unloading high capacity storage equipment to a solar power canopy. The methods and structures may include horizontal support members have mechanisms to engage corresponding mechanisms on a compartment housing the high capacity storage equipment. The mechanisms may include plates, flanged surfaces, rails, tracks, hook assemblies, and ridges. The methods and structures may include a superstructure that is coupled to an moves with respect to the solar power canopy frame. The superstructure may pivot and/or rotate to allow loading and unloading. The methods and structures also may include cabinets or cubicles sized to receive one or more compartments housing the high capacity storage equipment.

The present application provides methods for loading and unloading high capacity storage equipment to a solar power canopy. The methods and structures may include horizontal support members have mechanisms to engage corresponding mechanisms on a compartment housing the high capacity storage equipment. The mechanisms may include plates, flanged surfaces, rails, tracks, hook assemblies, and ridges. The methods and structures may include a superstructure that is coupled to an moves with respect to the solar power canopy frame. The superstructure may pivot and/or rotate to allow loading and unloading. The methods and structures also may include cabinets or cubicles sized to receive one or more compartments housing the high capacity storage equipment.

The present invention relates to a supporting system for photovoltaic panels and, in particular, to a supporting beam for photovoltaic panels implemented so that it eases the installation phase thereof, by allowing also the use of robot for the positioning, and at the same time it allows a reduction in production and maintenance costs.