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.

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.

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 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.

A strut end piece for a strut for connecting with a fin of a sleeve for a solar mirror frame support. A strut for receiving a strut end piece for a solar mirror frame support. A sleeve for connecting with a chord and a strut end piece for a solar mirror frame support having a main portion having an opening for receiving the chord. A method for connecting a sleeve to a chord and a strut end piece for a solar mirror frame support.

Photovoltaic modules are mounted onto a solar tracker array torque tube via pairs or left-handed and right-handed photovoltaic array connectors having spring latch assemblies. 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. The orientation projections on the spring latch assemblies of each pair of left-handed and right-handed photovoltaic array connector allow for the photovoltaic array connectors to fit over and settle on a torque tube, and thereby support and mount a photovoltaic module as part of a solar tracker array.

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 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 concentrator and a solar light router for converting light energy into electrical, photochemical and thermal energy, among other possible forms of usable energy, comprising a fixed body (1) and a movable part (2), wherein the fixed body (1) has an upper side with a converging lens (4) through which the sun rays (R1) enter, and a lower side where a mirror (5) is arranged. The mobile part 2 has a support arm 7 having a lower leg 8 coupled to a movement unit 10, and an upper leg 9 extending above the converging lens 4, in which is displaceable mounted a module (11) receptor/router of convergent solar rays (R4) that emerges from the fixed body (1). The support (7) is connected to angular displacement means housed in the movement unit (10) so that the angle traveled by its arm (9) encompasses a virtual surface (17), defined between the converging lens (4) and the module (11), where a focal point (19) incise of the convergent rays (R4), that travels according to the curvilinear paths (18n) in accordance with the displacement of the sunlight captured by the converging lens (4). The module (11) presents a lower face (13) through which the converging solar rays (R4) enters, and an upper face (14) from which concentrated solar rays (R5) are emitted which are directed, for example, towards a solar energy converter receiver (20) arranged in a tower (T) spaced from the device. The module (11) is connected to translation means along the upper section (9) of the support (7) and to rotating means with respect to its axis (E1) transverse to the defined plane by the converging lens (4) and includes means detecting the positions of the focal point (19), which together with the angular arm displacement means (7) and the translational and rotational means of the module (11) are connected to a module position control and control unit (11) to maintain it facing the focal point (19) and facing the receiver/solar energy converter (20) of the tower (T). In an alternate realization, the module (11) may act as a solar energy receiver/converter, for which it may include solar cells, a thermoelectric motor, or other solar energy converters.

The invention relates to a facet for solar concentrators, suitable for its use as reflective element of a heliostat, the facet comprising a main body defining a front surface and a back surface. Advantageously, the back surface of the main body is attached to at least three substantially linear ribs, which are arranged substantially parallel along said back surface, and wherein at least one of the three ribs is configured with adjustable anchoring means adapted for their connection to the structure of a solar concentrator. Moreover, the anchoring means are adapted such that the distance between at least one of the three ribs and the structure of a solar concentrator can be varied. The invention also relates to a solar concentrator comprising said facet, and to a method of installation thereof.