Photovoltaic module assemblies are mounted onto a solar tracker array torque tube via photovoltaic module brackets. The photovoltaic module brackets provide for stacking photovoltaic module assemblies in a nested configuration. The photovoltaic module assemblies are pre-assembled off-site, at a location different than the photovoltaic array installation site, and the nested configuration allows for efficient transportation of pre-assembled photovoltaic module assemblies to the installation site.

Photovoltaic modules are mounted onto a solar tracker array torque tube via pairs or left-handed and right-handed photovoltaic array connectors or brackets. The left-handed and right-handed photovoltaic array connectors have orientation projections that couple with and extend into the interior body of the torque tube. Pairs of left-handed photovoltaic array connectors and pairs of right-handed photovoltaic array connectors of adjacent photovoltaic modules can further be fastened together, thereby securing the photovoltaic modules to the torque tube and distributing the load of the overall number of photovoltaic modules mounted on the solar tracker array.

Mounting systems are disclosed for attaching photovoltaic modules to torque tubes. Such systems can include saddle brackets that maximize space along a torque tube by sharing torque tube mounting holes between adjacent brackets. The brackets can be positionally stable on the torque tube prior to complete installation to enable a single installer to assemble a complete tracker array.

A snow guard structure has the configuration in which a first frame body holding a ridge-side end side of a solar cell panel and a second frame body holding an eaves-side end side of an adjacent solar cell panel are fixed to a roof surface such that spaces are formed under their bottom face portions, and a snow guard fitting includes an upper abutment piece abutting against upper face portions of the two frame bodies, a lower abutment piece abutting against bottom face portions of the two frame bodies, an external thread member extending upward from the lower abutment piece and penetrating through the upper abutment piece and fastening the upper abutment piece and the lower abutment piece by screwing with an internal thread between the two frame bodies, and a snow guard portion extending upward from the upper abutment piece.

Methods and apparatuses to support photovoltaic (“PV”) modules are described. A saddle bracket has a mounting surface to support one or more PV modules over a tube, a gusset coupled to the mounting surface, and a mounting feature coupled to the gusset to couple to the tube. A grounding washer has a first portion to couple to a support; and a second portion coupled to the first portion to provide a ground path to a PV module. A PV system has a saddle bracket; a PV module over the saddle bracket; and a grounding washer coupled to the saddle bracket and the PV module. Saddle brackets can be coupled to a torque tube at predetermined locations. PV modules can be coupled to the saddle brackets.

A roof comprises a solar radiation heat recovery device that is invisible from the outside. The roof is made up of supports receiving a heat transfer network which has a longitudinal groove designed to receive the male profile of the protrusion of the heat recovery modules. The supports comprise arms which exert a lateral pressure on the flexible network. The resilient deformation of the network permits the sliding thereof between the arms to the clamped position. The groove of the network closes around the protrusion, immobilizing the module and holding the assembly in the support fixed to the roof frame. The roof is particularly intended to recover solar radiation heat in a way that is aesthetically pleasing, economical, simple and easy to install.

The invention relates to a carrier structure for solar panels. The invention also relates to a beam (3) for use in a carrier structure according to the invention. The invention then relates to a carrier (4,5) for use in a carrier structure according to the invention. The invention furthermore relates to an assembly of at least one carrier structure and at least one solar panel. In addition, the invention relates to a method for producing a carrier structure according to the invention.

A mount assembly is provided for mounting a structure to a roof having a top surface. The mount includes a flashing including an aperture; a bracket including a first portion and a second portion, the first portion having an opening and a countersink extending around the opening, the second portion extending at an angle away from the flashing, the second portion including a slot configured to be coupled to the structure; a fastener extending through the aperture and through the opening of the bracket; and a seal extending around the aperture and positioned between the flashing and the first portion of the bracket, the seal engaging the countersink of the bracket and being compressed against the flashing.

Devices, methods, and systems for installing photovoltaic systems are provided that are simple and easy to install, and that minimize the number of separate components or parts needed. Such devices, methods, and systems ensure seamless mechanical and electrical connectivity by their design, and minimize the time and effort expended by tradesperson or other technicians, especially in dangerous environments.

A solar panel mounting system for forming a solar array includes longitudinal support rails mounted to a support structure such as a roof. A first solar panel disposed on the rails has a peripheral frame including a locking frame member with deformable clamping portion configured for slideably receiving a peripheral frame portion of an adjacent second solar panel. A pair of captive T-bolt sets passing through the clamping portion include T-bolts having locking heads and nuts frictionally engaged with the T-bolts to rotate the T-bolts. The heads are each inserted and rotationally locked into fastening channels of respective support rails. The second solar panel is inserted into the first panel clamping portion and the nuts are fully tightened producing a clamping action which locks the first and second panels together. Power/control cables may be routed inside covered cable compartments on rears of the panels for protection against rodent damage.