A solar tracker system is a system and method to integrate the solar cells to a greenhouse. The solar tracker system comprises solar tracker modules that include solar cells, racks, gears, pinons, motors, and mounting brackets to efficiently and conveniently be installed to the roofs and walls of a new greenhouse and/or an existing greenhouse for retrofit application. Additionally, the solar tracker system uses various sensors to provide real-time conditions to the greenhouse. The method uses actual or system default values to adjust the angle and position of solar cells according to various environmental factors, such as DLI, weather, date, time, direction of sunlight, or type of plant.

Solar tracker systems include a torque tube, a column supporting the torque tube, a solar panel connected to the torque tube, and a locking assembly. The locking assembly includes a first end pivotably connected to the torque tube and a second end pivotably connected to the column. A shell defines a fluid chamber and a piston is positioned within the shell. The piston includes a seal and defines compression and extension portions of the fluid chamber. A flow path extends between the compression portion and the extension portions. A first valve assembly controls fluid flow in a first direction through the flow path and a second valve assembly controls fluid flow in a second direction through the flow path. The valve assemblies are each passively moveable from an unlocked state to a locked state in response to movement of the piston.

Solar tracker systems include a torque tube, a column supporting the torque tube, a solar panel connected to the torque tube, and a locking assembly. The locking assembly includes a first end pivotably connected to the torque tube and a second end pivotably connected to the column. A shell defines a fluid chamber and a piston is positioned within the shell. The piston includes a seal and defines compression and extension portions of the fluid chamber. A flow path extends between the compression portion and the extension portions. A first valve assembly controls fluid flow in a first direction through the flow path and a second valve assembly controls fluid flow in a second direction through the flow path. The valve assemblies are each passively moveable from an unlocked state to a locked state in response to movement of the piston.

A header for photovoltaic module support system and a photovoltatic module support system is disclosed. In various embodiments the header includes a beam and a plurality of strongback mounting tabs attached to the beam, each of the plurality of strongback mounting tabs attached to the beam such that the mounting tabs have an upward face that is mounted generally flush with an upward surface of the beam such that the upward face of the mounting tab and the upward surface of the beam define a support surface for an attachable strongback. In various embodiments the header includes a standoff and stabilizing rod attached to a downward surface of the beam, the stabilizing rod having a first end and second end attached to the downward surface of the beam with a main body that extends lengthwise with the beam and radially outward over the standoff.

A header for photovoltaic module support system and a photovoltatic module support system is disclosed. In various embodiments the header includes a beam and a plurality of strongback mounting tabs attached to the beam, each of the plurality of strongback mounting tabs attached to the beam such that the mounting tabs have an upward face that is mounted generally flush with an upward surface of the beam such that the upward face of the mounting tab and the upward surface of the beam define a support surface for an attachable strongback. In various embodiments the header includes a standoff and stabilizing rod attached to a downward surface of the beam, the stabilizing rod having a first end and second end attached to the downward surface of the beam with a main body that extends lengthwise with the beam and radially outward over the standoff.

According to one or more embodiments, an intelligent solar racking system is provided. The intelligent solar racking system includes a racking frame that receives and mechanically supports solar modules. The intelligent solar racking system includes sensors distributed throughout the racking frame. Each of the sensors detects and reports parameter data by generating output signals. The sensors include module sensors positioned to associate with each of the solar modules and detect a module presence as the parameter data for the solar modules. The intelligent solar racking system includes a computing device that receives, stores, and analyzes the output signals to determine and monitor operations of the intelligent solar racking system.

According to one or more embodiments, an intelligent solar racking system is provided. The intelligent solar racking system includes a racking frame that receives and mechanically supports solar modules. The intelligent solar racking system includes sensors distributed throughout the racking frame. Each of the sensors detects and reports parameter data by generating output signals. The sensors include module sensors positioned to associate with each of the solar modules and detect a module presence as the parameter data for the solar modules. The intelligent solar racking system includes a computing device that receives, stores, and analyzes the output signals to determine and monitor operations of the intelligent solar racking system.

A method of installing on a horizontal or near-horizontal support surface a solar panel array including multiple solar panels may include, at the deployment site, fabricating from metal coil stock longitudinally continuous rack channels each having upstanding legs of different heights, locating the channels in parallel rows with a spacing determined by a width of the solar panels with interior spaces of the channels facing upwardly, weighing the channels down on the support surface by placing ballast in the channel spaces, and positioning the solar panels each with an edge supported by a high leg of one channel of the channels and an opposite edge supported by a low leg of an adjacent channel of the channels.

A method of installing on a horizontal or near-horizontal support surface a solar panel array including multiple solar panels may include, at the deployment site, fabricating from metal coil stock longitudinally continuous rack channels each having upstanding legs of different heights, locating the channels in parallel rows with a spacing determined by a width of the solar panels with interior spaces of the channels facing upwardly, weighing the channels down on the support surface by placing ballast in the channel spaces, and positioning the solar panels each with an edge supported by a high leg of one channel of the channels and an opposite edge supported by a low leg of an adjacent channel of the channels.

A system includes a first photovoltaic module and a second photovoltaic module, each having a first end, an opposite second end, a first side extending from the first end to the second end, a second side opposite the first side and extending from the first end to the second end, a first surface and a second surface opposite the first surface, at least one solar cell, an encapsulant encapsulating the at least one solar cell, and a frontsheet juxtaposed with a first surface of the encapsulant. A second surface of the first photovoltaic module proximate to a second side thereof is attached to the first surface of the second photovoltaic module proximate to the first side thereof. A second surface of the first photovoltaic module proximate to a second end thereof is attached to the first surface of the second photovoltaic module proximate to the first end thereof.