The invention relates to a carrier structure (1) for solar panels. The invention also relates to a carrier (6) for use in a carrier structure (1) according to the invention. The invention then relates to an accessory (3) for use in a carrier structure (1) according to the invention. The invention furthermore relates to an assembly of at least one carrier structure (1) and at least one solar panel. In addition, the invention relates to a method for producing a carrier structure (1) according to the invention.

A node for a solar frame including an elongate portion having a channel extending through it in which a structural element is disposed or a solid elongate portion on to which a structural element is disposed. The node comprises a fin extending radially outward from the elongate portion where at least 5% of the volume of the fin is replaced by at least a single void extending essentially in parallel with the channel or the extrusion direction of the solid elongate portion. An apparatus for transmitting torque in a solar frame having structural elements and a support. A system for solar mirrors. A node for a solar frame. A method for connecting a structural element with a strut having a strut end piece of a solar mirror support frame. A method for producing a node for solar mirror frame.

A node for a solar frame including an elongate portion having a channel extending through it in which a structural element is disposed or a solid elongate portion on to which a structural element is disposed. The node comprises a fin extending radially outward from the elongate portion where at least 5% of the volume of the fin is replaced by at least a single void extending essentially in parallel with the channel or the extrusion direction of the solid elongate portion. An apparatus for transmitting torque in a solar frame having structural elements and a support. A system for solar mirrors. A node for a solar frame. A method for connecting a structural element with a strut having a strut end piece of a solar mirror support frame. A method for producing a node for solar mirror frame.

A structure and support device for photovoltaic arrays is provided. The device provides a structural connection between photovoltaic modules, wind deflectors and similar hardware. The invention provides an advantage of quick and easy installation of hardware components and associated parts, and meets the demand for a single device capable of combining solar energy associated hardware into photovoltaic arrays.

A structure and support device for photovoltaic arrays is provided. The device provides a structural connection between photovoltaic modules, wind deflectors and similar hardware. The invention provides an advantage of quick and easy installation of hardware components and associated parts, and meets the demand for a single device capable of combining solar energy associated hardware into photovoltaic arrays.

An integral, monolithic mounting bracket supports a corner of a photovoltaic module. The bracket includes a ballast tray for holding one or more ballast blocks, and includes a plurality of monolithic support legs that are disposed at acute angles from a plane of the ballast tray and that are integral with the ballast tray. The bracket can be manufactured by stamping at least two identical sections of metal from the sheet and then bending-up each section on its remaining uncut fourth side into a near-vertical position, so that each bent-up section forms a monolithic support leg.

An integral, monolithic mounting bracket supports a corner of a photovoltaic module. The bracket includes a ballast tray for holding one or more ballast blocks, and includes a plurality of monolithic support legs that are disposed at acute angles from a plane of the ballast tray and that are integral with the ballast tray. The bracket can be manufactured by stamping at least two identical sections of metal from the sheet and then bending-up each section on its remaining uncut fourth side into a near-vertical position, so that each bent-up section forms a monolithic support leg.

A photovoltaic system, comprising: a photovoltaic module attached to a photovoltaic rectangular mount frame; a deflector having a first end rotatably coupled to the mount frame so as to pivot the deflector from a nested position under the photovoltaic module in the mount frame to an installation position raising at least a first side of the mount frame; and a mount foot rotatably coupled to a second end of the deflector so as to pivot the mount foot from a nesting position in a mount foot nesting indention in the deflector to an installation position planar to a mounting surface.

A photovoltaic system, comprising: a photovoltaic module attached to a photovoltaic rectangular mount frame; a deflector having a first end rotatably coupled to the mount frame so as to pivot the deflector from a nested position under the photovoltaic module in the mount frame to an installation position raising at least a first side of the mount frame; and a mount foot rotatably coupled to a second end of the deflector so as to pivot the mount foot from a nesting position in a mount foot nesting indention in the deflector to an installation position planar to a mounting surface.

Mounting components of photovoltaic (PV) modules and PV module assemblies are described, including PV module couplings and PV module mounting chassis. In an example, a PV module includes a PV module coupling having a toe portion extending from a PV module frame, and a PV module mounting chassis includes a toe slot to receive the toe. The toe and toe slot construction allows for the PV module frame to be assembled to the PV module mounting chassis without using tools, and thus, permits a PV module assembly to be quickly constructed during installation of a PV module system. Furthermore, the toe and toe slot construction accommodates thermal expansion and other environmental loads seen after installation, while providing a grounding connection for the PV module assembly.