Tracking modules are effectively provided that can be arranged as systems for positioning devices, such as reflectors. A preferred reflector is small and light in comparison to prior art reflectors so that components can be utilized within reflector construction and support structure that are sufficiently stiff to accurately hold a reflector in place under expected operational drive-torque, gravity and wind loads. At the same time, a single person can install a reflector, easily overcoming a retention mechanism spring force so as to positively engage a reflector in position. This is achieved without the need for any tools, through a combination of a retention mechanism and a spring feature design. Arrangements of tracking modules are included for easier manufacture, transport of systems and installment.

An solar energy harvester and method for controlling the solar energy harvester, in which an insolation collector is formed of one or more elements each having two opposite major sides, a first side and a second side, and being configured to collect energy from insolation incident on any of the first and second sides. A cradle enables installation of the insolation collector on a roof with the first side generally towards the sun independently of the form of the roof. One or more heliostats reflect insolation to the second side of the insolation collector. A controller controls the one or more heliostats to maintain reflected insolation incident on the collector and to decrease the reflected insolation incident on the collector when necessary to inhibit the insolation collector receiving insolation exceeding given threshold through its first and second sides.

The invention relates to a passive tracking device for tracking the position of the sun, which comprises a hollow parallelepiped casing through which the solar radiation entering through a first lens located at the upper end of the parallelepiped casing passes towards a discriminating reflector arranged at the lower end of the same casing; the tracking device redirects as much incoming radiation as possible towards side chambers for absorbing radiation, heating a working fluid contained in the side chamber; producing a volumetric expansion in the working fluid that, communicating with shafts for the rotation of the tracking device, allows the orientation with the normal/perpendicular position with respect to the position of the sun, and to guide the alignment direction of other tracking devices for collecting energy in devices for collecting photovoltaic and/or thermal energy that are mechanically connected to the tracking device.

In an embodiment, a solar energy system includes multiple photovoltaic modules, each oriented substantially at a same angle relative to horizontal. The angle is independent of a latitude of an installation site of the solar energy system and is greater than or equal to 15 degrees. The solar energy system defines a continuous area within a perimeter of the solar energy system. The solar energy system is configured to capture at the photovoltaic modules substantially all light incoming towards the continuous area over an entire season.

A support structure (10) for carrying a plurality of heliostats (12) is provided. The support structure (10) includes a frame (20) formed from a number of girders (22). The frame has a triangular outer perimeter and a plurality of mountings (26) for carrying the heliostats (12) are provided along the perimeter. At least one mounting (26) is provided at or near each vertex (16) of the triangular outer perimeter of the frame (20), and at least one additional mounting (26) is provided part-way along each side (17) of the triangular outer perimeter of the frame (20).

Methods, systems, and computer program products for user-preference driven control of electrical and thermal output from a photonic energy device are provided herein. A computer-implemented method includes automatically modulating an amount of thermal output and/or electrical power output generated by a solar photovoltaic module in response to an input of one or more user preferences by: adjusting at least one variable pertaining to a fluid positioned on the solar photovoltaic module based on the one or more user preferences; and adjusting at least one variable pertaining to one or more reflective surfaces physically connected to the solar photovoltaic module based on the one or more user preferences.

An energy concentrating apparatus includes: a mounting platform, a mounting support, a rotating support, a reflective mirror, an arc-shaped slide rail, a linking rod, a sliding parts, a drive device, and a pull rope. The mounting support is located on the mounting platform. A rotation shaft of each rotating support is rotatably located on the corresponding mounting support, and a rotation shaft of each reflective mirror is rotatably located on the corresponding rotating support. The arc-shaped slide rail is located on the mounting platform, and the sliding parts is slidably located in the arc-shaped slide rail, the linking rod is connected to the sliding parts and the reflective mirror respectively, and a curvature of the arc-shaped slide rail is different such that the reflective mirror rotates towards a different direction.

An energy concentrating apparatus includes: a mounting platform, a mounting support, a rotating support, a reflective mirror, an arc-shaped slide rail, a linking rod, a sliding parts, a drive device, and a pull rope. The mounting support is located on the mounting platform. A rotation shaft of each rotating support is rotatably located on the corresponding mounting support, and a rotation shaft of each reflective mirror is rotatably located on the corresponding rotating support. The arc-shaped slide rail is located on the mounting platform, and the sliding parts is slidably located in the arc-shaped slide rail, the linking rod is connected to the sliding parts and the reflective mirror respectively, and a curvature of the arc-shaped slide rail is different such that the reflective mirror rotates towards a different direction.

To position a solar oven radiation collection device, a structural extension assembly extends in a radial direction with respect to a structure. A moveable transport provides linear movement of the solar oven radiation collection device along an axis of the structural extension assembly. A linear deploy electric motor is used to control linear movement of the solar oven radiation collection device along the axis of the structural extension assembly. A solar altitude electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in solar altitude with respect to time. A solar azimuth electric motor is used to adjust orientation of the solar oven radiation collection device to take into account changes in azimuth with respect to time.

An improved system for concentrating, collecting, and transmitting sunlight, comprises: a first plurality of lens panels that is disposed in at least one location in an origin for collecting sunlight; a central collection point that receives the collected sunlight, said collected sunlight being transmitted from the collection point to at least one concentrating lens, said at least one concentrating lens generating a sharp and strong beam, which is transmitted to a first satellite; a first reflecting portion that reflects the concentrated beam to a second satellite; and a second reflecting portion that reflects the concentrated beam through a second pre-defined distance to an at least one receiver unit, said at least one receiver unit transmitting the sunlight to a receiving point that is disposed in at least one location in the destination for collecting sunlight. The sunlight collected in the destination can be used for various purposes.