The invention relates to a system and a method for mounting at least one solar panel on a substantially flat mounting surface. The system comprises thereto a base element, a support structure configured for supporting at least part of at least one solar panel, which is connected to the base element and wherein the support structure comprises a retaining element for retaining at least part of an upper edge of the solar panel and a clamping element configured for clampingly engaging at least part of a lower edge the solar panel.

A mufti-surface stand is disclosed. The stand may comprise a main body, a rotation body connected to the main body and configured to rotate in a horizontal plane, an arm shaft connected to the rotation body, a main arm connected the arm shaft and configured to tilt in a vertical direction, a v-clamp connected to the main arm, a pan knob inserted into the main body and configured to be tightened to cause the rotation body to be prevented from rotating, a leg rotatably connected to the main body, the leg including a hollow portion configured to store therein a stake or auger having a base portion, and an integrated rotatable foot, configured to rotate between a folded position and a ground mount position.

A mechanically powered solar tracking system is disclosed. The mechanically powered solar tracking system may include a carriage, a carriage mount connected to the carriage, a pivot shaft including a pivot gear connected to the carriage or, a complex gearbox, a base including legs, a tracker disposed on the base, the tracker including a mechanical energy storage system and a movement modulating system. The mechanical energy storage system may be configured to store mechanical energy as the carriage is rotated from a first position to a second position, and the movement modulation system may be configured to modulate a rotation of the carriage from the second position to the first position as the mechanical energy storage system exerts a rotational force on the carriage.

A solar tracking system is disclosed. The solar tracking system may comprise at least one processor, a memory coupled to the at least one processor, a carriage mount, a carriage, an altitude motor connected to the carriage, an azimuth motor connected to the carriage, and a tracking application, residing in the memory and executed by the at least one processor. The tracking application may be configured to run the altitude motor and azimuth motor in a predictive manner, such that a solar panel connected to the carriage is positioned in a way to increase solar irradiation of the solar panel.

In an example, the present invention provides a solar tracker apparatus configured with an off-set drive assembly. In an example, the apparatus has an inner race structure, which has a cylindrical region coupled to a main body region, the main body comprising an off-set open region. The cylindrical region is an annular sleeve structure coupled to the main body region, which occupies the spatial region within the cylindrical region. In an example, the apparatus has an outer race structure coupled to enclose the inner race structure, configured to couple the inner race structure to allow the inner race structure to move in a rotational manner about a spatial arc region; and configured to allow the inner race structure to pivot about a region normal to a direction of the spatial arc region. In an example, the solar tracker has a clamp assembly that is configured to pivot a torque tube.

In an example, the present invention provides a solar tracker apparatus configured with an off-set drive assembly. In an example, the apparatus has an inner race structure, which has a cylindrical region coupled to a main body region, the main body comprising an off-set open region. The cylindrical region is an annular sleeve structure coupled to the main body region, which occupies the spatial region within the cylindrical region. In an example, the apparatus has an outer race structure coupled to enclose the inner race structure, configured to couple the inner race structure to allow the inner race structure to move in a rotational manner about a spatial arc region; and configured to allow the inner race structure to pivot about a region normal to a direction of the spatial arc region. In an example, the solar tracker has a clamp assembly that is configured to pivot a torque tube.

In an example, the present invention provides a solar tracker apparatus configured with an off-set drive assembly. In an example, the apparatus has an inner race structure, which has a cylindrical region coupled to a main body region, the main body comprising an off-set open region. The cylindrical region is an annular sleeve structure coupled to the main body region, which occupies the spatial region within the cylindrical region. In an example, the apparatus has an outer race structure coupled to enclose the inner race structure, configured to couple the inner race structure to allow the inner race structure to move in a rotational manner about a spatial arc region; and configured to allow the inner race structure to pivot about a region normal to a direction of the spatial arc region. In an example, the solar tracker has a clamp assembly that is configured to pivot a torque tube.

In an example, the present invention provides a solar tracker apparatus configured with an off-set drive assembly. In an example, the apparatus has an inner race structure, which has a cylindrical region coupled to a main body region, the main body comprising an off-set open region. The cylindrical region is an annular sleeve structure coupled to the main body region, which occupies the spatial region within the cylindrical region. In an example, the apparatus has an outer race structure coupled to enclose the inner race structure, configured to couple the inner race structure to allow the inner race structure to move in a rotational manner about a spatial arc region; and configured to allow the inner race structure to pivot about a region normal to a direction of the spatial arc region. In an example, the solar tracker has a clamp assembly that is configured to pivot a torque tube.

A system and method for collecting solar energy wherein the system comprising a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and a plurality of solar panels secured to an outside periphery of the tower. The method comprises providing a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and securing a plurality of solar panels to and around an outside periphery of the tower.

A system and method for collecting solar energy wherein the system comprising a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and a plurality of solar panels secured to an outside periphery of the tower. The method comprises providing a tower formed having a plurality of stories, the tower formed of a plurality of structural members extending between hub connectors to form a space frame providing a vertical airflow path therethrough and securing a plurality of solar panels to and around an outside periphery of the tower.