A method of determining a reflector parameter of a concentrating solar collector's reflector surface. An image is captured of the reflected receiver tube in the reflector surface, with an image capturing device, e.g. a camera, and processed to put together image data related to the reflected receiver tube. Further, the method comprises determining a location of the image capturing device at a capturing time of the captured image, and determining a position on the reflector surface based on the determined location of the image capturing device and the image data. The method comprises also calculating the reflector parameter at the determined position based on the image data. By numeric calculation of reflector parameters, such as slope, defects, e.g. caused by impacts or material imperfections, may be identified at an early stage before installing the solar collectors, which may reduce service needs.

A method of determining a reflector parameter of a concentrating solar collector's reflector surface. An image is captured of the reflected receiver tube in the reflector surface, with an image capturing device, e.g. a camera, and processed to put together image data related to the reflected receiver tube. Further, the method comprises determining a location of the image capturing device at a capturing time of the captured image, and determining a position on the reflector surface based on the determined location of the image capturing device and the image data. The method comprises also calculating the reflector parameter at the determined position based on the image data. By numeric calculation of reflector parameters, such as slope, defects, e.g. caused by impacts or material imperfections, may be identified at an early stage before installing the solar collectors, which may reduce service needs.

Technologies are disclosed herein for a thin heat exchanger through which coolant may be pumped. The heat exchanger may include an envelope and a heat conduction layer provided over the envelope. The envelope may include one or more channels formed therein. The channels formed between the envelope and the conduction layer may extend the length of the heat exchange layer and be configured to carry coolant therethrough. The heat exchange layer may include an inlet manifold on a first end and an outlet manifold on another end opposing the first end. The inlet manifold may allow the flow of coolant into the heat exchange layer and the outlet manifold may allow the removal of the coolant from the heat exchange layer. Coolant flow may be controlled by a suction pump operating under computer control based at least in part on sensor data.

Technologies are disclosed herein for a thin heat exchanger through which coolant may be pumped. The heat exchanger may include an envelope and a heat conduction layer provided over the envelope. The envelope may include one or more channels formed therein. The channels formed between the envelope and the conduction layer may extend the length of the heat exchange layer and be configured to carry coolant therethrough. The heat exchange layer may include an inlet manifold on a first end and an outlet manifold on another end opposing the first end. The inlet manifold may allow the flow of coolant into the heat exchange layer and the outlet manifold may allow the removal of the coolant from the heat exchange layer. Coolant flow may be controlled by a suction pump operating under computer control based at least in part on sensor data.

The present invention pertains to a fluid-flow control system (O) that renders an exergy-based optimal output based on the maximization of the total exergy at any given time via control, and suffices an innovative, exergy-based purpose function which instantly optimizes flow in/into any system (S) of power and/or heat generation, industrial or all kinds of manufacturing systems where liquid, gas, and/or one or more phases of fluid is/are involved. Systemic, environmental, technical factors such as equipment performance, losses, demand/supply inputs, temperature and pressure data are considered within the optimization system with the particular help of instrumentation and data control units, and flow control units such as the variable flow/displacement pumps.

A heat collector device is provided. The heat collector includes an exterior surface exposed to an environment, and an interior surface. Side walls separate the exterior and interior surfaces. A heat insulation interposes the exterior and interior surfaces. Each hot air duct includes a first portion interfacing with the external surface and a second portion interfacing with the heat insulation. Each cold air duct is encompassed by the heat insulation. A first chamber formed by a first side wall provides fluidic communication between the air ducts at a first end portion of each respective duct. A second chamber formed by a second side wall provides fluidic communication between the air ducts at a second end portion of each respective duct. A heat exchange mechanism disposed in the second chamber removes heat from a first fluidic medium of the air ducts, the first chamber, and the second chamber.

A solar actuator comprises a top coupler, a bottom coupler, and a plurality of fluidic bellows actuators, wherein a fluidic bellows actuator of the plurality of fluidic bellows actuators moves the top coupler relative to the bottom coupler.

A solar actuator comprises a top coupler, a bottom coupler, and a plurality of fluidic bellows actuators, wherein a fluidic bellows actuator of the plurality of fluidic bellows actuators moves the top coupler relative to the bottom coupler.

A method for controlling the orientation of a single-axis solar tracker orientable about an axis of rotation, including observing the evolution over time of the cloud coverage above the solar tracker; determining the evolution over time of an optimum inclination angle of the solar tracker substantially corresponding to a maximum of solar radiation on the solar tracker, depending on the observed cloud coverage; predicting the future evolution of the cloud coverage based on the observed prior evolution of the cloud coverage; calculating the future evolution of the optimum inclination angle according to the prediction of the future evolution of the cloud coverage; servo-controlling the orientation of the solar tracker according to the prior evolution of the optimum inclination angle and depending on the future evolution of the optimum inclination angle.

A method for controlling the orientation of a single-axis solar tracker orientable about an axis of rotation, including observing the evolution over time of the cloud coverage above the solar tracker; determining the evolution over time of an optimum inclination angle of the solar tracker substantially corresponding to a maximum of solar radiation on the solar tracker, depending on the observed cloud coverage; predicting the future evolution of the cloud coverage based on the observed prior evolution of the cloud coverage; calculating the future evolution of the optimum inclination angle according to the prediction of the future evolution of the cloud coverage; servo-controlling the orientation of the solar tracker according to the prior evolution of the optimum inclination angle and depending on the future evolution of the optimum inclination angle.