Dry cooling systems and methods are provided including at least one plastic elongated tube formed at least partially of a semi-rigid material and having a flat wall portion, a reflective material attached to said flat wall portion of the tube to reflect solar radiation, and at least one fluid channel in thermal communication with the reflective material, the fluid channel adapted to allow flow of a heat transfer fluid. Thermal power plants are provided which include a dry cooling system, one or more pipes in fluid communication with the dry cooling system, and at least one heat exchanger in fluid communication with the one or more pipes.

An apparatus for mounting and supporting one or more solar modules are provided. The apparatus can include a front wall and a rear wall. The apparatus can further include a curved surface that joins the front wall and the rear wall to form a base of the apparatus. The base of the apparatus can have a curved bottom. Furthermore, the base of the apparatus can be configured to mount and support the one or more solar modules. Related methods are also provided.

A modular ballast system for supporting objects uses tubing such as pipes of appropriate size for the required ballast. Once in place, the empty pipes are filled with a watery mix (slurry) of sand, silt, gravel, soil, cement or other generally available material to generate a majority of the ballast weight. A two piece clamping mechanism provides fixed placement attachment points suitable for attachment by supported structures. The lower piece of the clamping mechanism sits under the ballast tubing and is designed to both support and disperse the anticipated weight of the objects with minimal impact on the surface beneath it. The upper piece of the clamping mechanism mates to the lower clamping piece and completes a full 360 degree collar around the ballast tubing to create a durable clamping mechanism that both captures the weight and position of the ballast tubing and prevents the ballast tubing from shifting.

A non-slip roof attachment system for attaching structures to residential and commercial roofs without the use of penetrations to roofing shingles and sealing layers is described. The non-slip attachment system may be used to attach roof mounted systems such as solar panels. The non-slip attachment system also allows for the quick removal of such roof mounted systems rapidly and without the need for repair of penetrations. The non-slip attachment system uses, among other things, an array-stay retainer comprising a vertical member and a horizontal member. The horizontal member comprises a spiral.

A support assembly for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support assembly may comprise a the body portion including a base portion and at least one upright support member coupled to the base portion, the at least one upright support member comprising an integrally formed ballast tray slot in one side thereof for receiving an upturned edge of a ballast tray; and at least one clamp subassembly coupled to the at least one upright support member of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules. In addition to a plurality of support assemblies, the mounting system may further comprise at least one ballast tray support bracket, the ballast tray support bracket supporting a portion of a ballast tray on the support surface.

A solar array is mounted on a surface of a structure, the surface being generally planar. The solar array comprises a solar module and a support that supports the solar module a distance above the surface. The support defines a channel to receive the solar module. A locking mechanism engages the support to secure the solar module to the support, wherein the solar module extends between the support and the locking mechanism and into the channel such that the solar module is allowed to move relative to the support in a first plane generally parallel to the surface when the solar module is secured to the support. The locking mechanism and the support inhibit movement of the solar module in a second plane generally perpendicular to the surface when the solar module is secured to the support.

A non-slip roof attachment system for attaching structures to residential and commercial roofs without the use of penetrations to roofing shingles and sealing layers is described. The non-slip attachment system may be used to attach roof mounted systems such as solar panels. The non-slip attachment system also allows for the quick removal of such roof mounted systems rapidly and without the need for repair of penetrations. The non-slip attachment system uses, among other things, an array-stay retainer comprising a vertical member and a horizontal member. A high friction foam polymer padding is used to further secure the non-slip attachment system to the roof.

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.

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.

Photovoltaic system includes i) a first photovoltaic panel (11) comprising a first and a second edge (111, 112) between which the panel extends in length; ii) a support means (2) for supporting the first panel (11); the support means (2) being at least in part made of concrete, defining a ballast of the first panel (11) and including:a first and a second support zone (21, 22); the distance from the first edge (111) of the first zone (21) being smaller than the distance from the first edge (111) of the second zone (22);a third support zone (23) whose distance from the first edge (111) is intermediate with respect to the distance from the first edge (111) of the first and of the second support zone (21, 22);a first bracket (231) constrained to the third support zone (23) and protruding away from the third support zone (23); and a first gripping means (230) for gripping the first panel (11) supported by the first bracket (231).