An equipment mounting system for mounting equipment to a support structure is described. An equipment mounting system including: (i) a mounting plate having defined therein a plate aperture of a particular shape; (ii) a bolt having a shaft portion including a threaded portion and a non-threaded portion that is of a complementary shape that complements the particular shape of the plate aperture; and (iii) a washer having defined therein a scored aperture that includes multiple radially extending scorings. In an assembled configuration of the mounting plate, the bolt and the washer, the plate aperture of the particular shape aligns with the scoring aperture such that both of the plate aperture and the scoring aperture receive the non-threaded portion of the complementary shape, and the particular shape of the mounting plate engages with the complementary shape of the bolt to prevent rotational displacement of the bolt around the mounting plate.

A system includes a containment vessel configured to receive and retain equipment to be decontaminated. The system also includes a solar reflector configured to reflect solar energy towards the containment vessel in order to heat the containment vessel. The system further includes end supports configured to receive and retain the solar reflector and the containment vessel. The system also includes a base having or coupled to multiple side supports, where each side support is configured to contact and support a corresponding one of the end supports. In addition, the system includes one or more semi-transparent solar shades configured to reduce the solar energy reaching the solar reflector and the containment vessel.

The apparatus may include a ridge member, a first arm rotatably coupled to the ridge member and extending outward, relative to the ridge member, in a first plane angled relative to a first pitch of a roof structure. Also, the apparatus may include a second arm rotatably coupled to the ridge member and extending outward, relative to the ridge member, in a second plane angled relative to a second pitch of the roof structure. The ridge member may be positioned at an apex between the first pitch and the second pitch along a ridge of the roof structure. Further, materials for installation may be placed on at least one of the first arm and the second arm positioned between the roof structure and the materials. Additionally, the apparatus may include a load arm coupled at each respective end portion of the first arm and the second arm.

The disclosure concerns a body-mounted solar panel carrier comprising a support assembly configured to be worn with a harness, a panel-receiving assembly configured to receive and secure one or more solar panel(s), and a plurality of support linkages configured to connect the support assembly to the panel-receiving assembly such that the panels are offset from the user's body. The panel-receiving assembly is adapted to sit at a position removed from the support assembly but maintains the weight of the solar panel therein to be evenly distributed across a person's body via the shoulder straps, and lumbar support. This allows a user to: (i) secure a solar panel to the carrier at the panel-receiving assembly, (ii) don the body-mounted solar panel carrier via the pair of shoulder straps and lumbar support of the support assembly, (iii) safely walk with the carrier and solar panel, and (iv) safely ascend a ladder while maintaining four points of contact, with said body-mounted solar panel carrier and solar panel in tow.

An inflatable non-imaging solar concentrator water desalination system comprises an inflatable non-imaging stationary solar concentrator and shallow black basin type evaporator. The evaporator is made into a semi-close structure house like a stadium to surround the concentrator. An absorber made of black coating or porous absorption materials is placed on the basin of the concentrator. The evaporator consists of an inner holder, a outer holder, a freshwater collector, and a condenser to form a space for water to evaporate, and to be condensed and collected. The inflatable non-imaging solar concentrator is assembled with the evaporator in such a way that the output aperture of the solar concentrator is directly over the surface of the absorber

A solar array lifting assembly and method. The device and method use a support pole, a pole bracket for supporting a solar array made up of a frame and solar panels, a pole bracket securing mechanism for securing the pole bracket at a predetermined height, and a lifting assembly for lifting the pole bracket and solar array along the support pole.

A photovoltaic support includes a first vertical upright column (110) and a second vertical upright column (120) on a foundation, and a beam (10) respectively hinged with a first end of the first vertical upright column (110) and a first end of the second vertical upright column (120). The photovoltaic support further includes a first movable connecting piece (140) provided on the foundation and connected with a second end of the first vertical upright column (110). The first movable connecting piece (140) is automatically adjusted according to the wind intensity, such that the first vertical upright column (110) moves in a vertical direction to adjust an inclination angle of the beam (130). The photovoltaic support can adjust the angle adaptively in the case of a strong wind, and restore automatically after the strong wind has passed.

A tower for a concentrated solar power plant includes: an upper external platform on which is arranged an essentially cylindrical solar receiver with an external side surface and an upper base, the side surface of the receiver including a plurality of removably mounted receiving panels; and a placement and maintenance system for the receiving panels. The placement and maintenance system for the receiving panels includes a crane mounted so as to be rotatable 360 and guided using at least two concentric rails, on the upper base of the receiver.

A folded down support (12) allows for stronger solar panels (10) and the support replaces most of the solar racking required for solar installation which further reduces the cost of the photovoltaic solar system. The solar panels (10) can be arranged so that solar panels form a solar collector solar panel array. The solar panel (10) can be set on a surface by itself or with ballast (43). It can also be attached to the surface by fastening the solar panel to the side supports. If the solar panel frame and supports are electrically conductive, the design allows for self electrical grounding between these conductive parts when the side supports are pivoted to the down position. The folded up support allows for high density storage and shipping.

A photovoltaic apparatus includes: a power generation part; an angle changeable mechanism configured to support the power generation part so as to be able to change an elevation of the power generation part; a post configured to support the power generation part and the angle changeable mechanism; and a hinge mechanism configured to support the post so as to be able to change an angle of the post relative to an installation surface for the photovoltaic apparatus.