An adjusting device for adjusting orientation of an energy conversion board comprises a first frame member, a second frame member, a third frame member and a base. The first frame member contains the energy conversion board. The second frame member holds the first frame member. The third frame member holds the second frame member. The base supports the third frame including the other frames and the energy conversion board. The first frame member is rotatable relative to the second frame member, the second frame member is rotatable relative to the third frame, and the third frame member is rotatable relative to the base. The first rotating axis is perpendicular to the second rotating axis, and the third rotating axis is coaxial with the first rotating axis.

A novel portable solar energy system includes a solar concentrator, a thermal storage device, an azimuth adjustment system, an elevation system, and a heat exchanger, all mounted on a rotatable support frame. In a particular embodiment, the thermal storage device remains at a fixed vertical height and fixed tilt orientation when adjustments are made to the azimuth adjustment system and/or the elevation adjustment system.

The present invention relates to methods and systems for identifying PV system and solar irradiance sensor orientation and tilt based on energy production, energy received, simulated energy production, estimated energy received, production skew, and energy received skew. The present invention relates to systems and methods for detecting orientation and tilt of a PV system based on energy production and simulated energy production; for detecting the orientation and tilt of a solar irradiance sensor based on solar irradiance observation and simulated solar irradiance observation; for detecting orientation of a PV system based on energy production and energy production skew; and for detecting orientation of a solar irradiance sensor based on solar irradiance observation and solar irradiance observation skew.

Liquid-based adjusting device (100) for a solar system comprising at least one holding element (1) for attaching at least one solar element, a swivel device (2), designed and intended for swiveling the holding element (1) around at least one swivel axis (S) and/or along a guiding curve (F) of the holding element (1), wherein one floating body (1A) of the holding element (1) is at least partially arranged below a filling level (30A) of the liquid tank (3A) and only by the buoyancy thereof the holding element (1) is swivel-mounted relative to one longitudinal axis (L) of the liquid tank (3A) around the swivel axis (S) and/or along the guiding curve (F) and mounted above the filling level (30A) directly on the rim (31A) of the liquid tank (3A), wherein the filling level (30A) of the liquid tank (3A) can be varied by means of a piping system (4) of the swivel device (1).

An energy capturing device is positionable above a roof of a building, structure, or object. Each of a plurality of lifting components has a short leg with an inner end coupled to the building, structure, or object and has a long leg with an upper end positionable above the building, structure or object. An upper pivot member couples the upper ends of the long legs to the energy capturing device. A lower pivot member pivots the energy capturing device between a raised operative orientation above the building, structure, or object and a lowered inoperative orientation beneath the building, structure, or object. A control system allows positioning the energy capturing device with respect to the building, structure, or object.

An integrated drive leg and mount suitable for solar power devices, such as trough solar concentrators or PV panels. A drive system including a linear actuator is integrated into the support structure. A pulley assembly converts the linear force into rotational motion, thereby providing tracking adjustments for a solar power device following the sun avoiding larger external electric drive motor which are situated between successive solar power devices. The integrated nature enables a smaller gap between solar power devices in solar installations, reduces the effect of induced shadowing, and enables greater collection of solar energy.

Apparatus for a concentrating solar collector is disclosed, comprising: A nested main frame and reflector carriage with vertically folding one-piece preformed reflector support panels, to which individually replaceable pieces of mirror-like material of various kinds may be mounted to make a Fresnel-type array. A hand-winch operated cable system provides for a full range of reflector altitude adjustment. An alignment guide allows assessment of solar tracking alignment without gazing toward the focal area. A griddle-like flattop receiver is used for frying foods, and an adjustable rack facilitates suspension of cooking pots in the focal area to receive unobstructed, concentrated solar energy. Also described is a method for making the reflector support panels. One embodiment of the apparatus has a lower frame portion substantially forming a rolling chassis. An additional embodiment describes lower frame structure for a fixed location installation.

An assembly of units comprised of mirrors assembled along at least one parabolic arc, each mirror having two opposing lateral edges and opposing longitudinal internal and external edges, each of the two mirrors being longitudinally secured to the other mirror along their respective longitudinal internal edges by at least one securing device positioned at the centre of the parabolic arc; and secured at each lateral edge to the wheel supports.

A solar tracking system with a plurality of tracking assemblies moved by a single motor. A method and system that prevents overloading the motor or tripping a circuit breaker due to an obstructed or impeded tracker includes sensing movement of the tracker assemblies and entering into obstruction clearing modes. Obstruction clearing mode 1 (OCM1) is a high frequency adjustable mode that prompts movement for an adjustable period of time. If movement commences, the system returns to a normal mode. If there is no movement, the system enters into an obstruction clearing mode 2 (OCM2) with is an adjustable lower frequency series of attempts. If there is no movement, no further attempts are made. Each of these steps are monitored and controlled remotely. There are two types of secure connections for drivelines, torque tubes or affixing driveline linkages for high torque conditions.

Provided are a heliostat calibration, device and a heliostat calibration method that can suppress time-change-dependent control error increases and can reduce calibration frequency. The present invention is provided with: an initial position information acquisition unit that acquires initial position information for a heliostat; a theoretical value calculating unit that calculates from the heliostat initial position information and sun position information a theoretical value that is related to the orientation of the heliostat; a deviation calculation unit that, using as input an actual measured value for the orientation of the heliostat, calculates the deviation between the theoretical value and the actual measured value at least two times a day; and a coordinate calibration unit that, when the deviation exceeds a threshold value, calibrates the coordinates of the heliostat such that the deviation is at or below the threshold value.