Abstract: A solar actuator system comprising at least one actuator assembly. The actuator assembly includes: a top coupler; an angled bottom coupler having a top-end and respective first and second faces on opposing first and second sides of the top-end, the angled bottom coupler coupled to the top coupler via a one-degree-of-freedom joint between the top coupler and the angled bottom coupler; and at least a first and second actuator, with the first actuator disposed on the first side of the angled bottom coupler and the second actuator disposed on the second side of the angled bottom coupler.

Abstract: A series of photovoltaic panels (PV) arranged on a planar, horizontal support platform so as to form a PV array that is pivotally connected to a PV array support structure that can pivotally raise, angle and support the PV array above agricultural fields at heights that allow the passage of large mechanized farm equipment to pass beneath. The PV array support structure pivotally raises its PV array into its operating elevation and positional range with a system of motorized pivot arms operationally positioned between its array columns and the members of the support frame. Once in place, these PV arrays may be horizontally moved by tilting or angling the array columns within a specified operating range (by computer positioning known as dynamic shifting). At the same time, the PV panels may all be optimally tilted for sun sharing and sun shading for both the generation of electricity and to increase the agricultural efficiency of the underlying land.

Abstract: Prior art solar energy arrangements are typically structurally complex, have a limited concentration factor and temperature, and their dimensions are large. There is provided a solar energy arrangement and corresponding method for utilizing solar energy by directing sunrays or sunbeams with at least one solar concentrator towards at least one application, device or equipment utilizing solar energy, and a corresponding method, system and computer program product for implementing an arrangement for utilizing solar energy.

Abstract: A pneumatically actuated solar panel array system that includes a plurality of separate actuator assemblies that each have a top plate and bottom plate and a first and second bellows that each extend between and are coupled to the top and bottom plates at a respective top head and bottom head, the first and second bellows being configured to be separately pneumatically inflated, where the pneumatic inflation expands the bellows along a length. The pneumatically actuated solar panel array system can also include a plurality of solar panels coupled to the actuator assemblies with the solar panels being configured to be actuated based on inflation of one or more bellows associated with the plurality of actuator assembles.

Abstract: A solar power generation assembly includes a vertical support column; a canopy including a plurality of solar modules for solar power generation; a first brace and a second brace on a first side of the support column to support the canopy; a third brace and a fourth brace on a second side of the support column to support the canopy; and a gutter system integrated into the canopy and directing precipitation along one or more of the second brace and the fourth brace to the support column. One or more of the first brace and the third brace manage electrical cables extending from the canopy to the support column.

Abstract: A vapor extractor device includes a vapor extractor hood, and a drive motor for retracting and extending the vapor extractor hood. The drive motor is hereby controlled to reduce a retraction speed of the vapor extractor hood from a first predetermined retraction position, when the vapor extractor hood is retracted.

Abstract: A solar energy collector and/or concentrator, a thermal energy storage and retrieval system including the same, and methods of storing and recovering thermal energy are disclosed. The solar energy collector and/or concentrator may include an array of lenses configured to concentrate solar energy, a plurality of conduits through which a heat storage or heat transport fluid flows, and one or more heat transfer elements on each of the conduits, configured to receive the concentrated solar energy from the lenses and transfer the concentrated solar energy to the heat storage/transport fluid. The conduits are configured to move in at least first and second angular dimensions. The thermal energy storage and retrieval system may include the solar energy collector and/or concentrator, a thermodynamic cycle, and a heat storage and retrieval subsystem. Heat is transferred from the heat storage/transport fluid to the heat storage and retrieval subsystem and/or the thermodynamic cycle.

Abstract: Methods, systems, and computer readable media are disclosed for thermal management of a system of one or more electric components. In some examples, the system includes a housing, one or more electric components, one or more temperature sensors on or in the housing, and a thermal management circuit coupled to the electric components and the temperature sensors. The thermal management circuit is configured to monitor the temperature sensors and, based on monitoring the temperature sensors, cause at least a first electric component to curtail power consumption, thereby reducing heat generating by the first electric component.

Abstract: Disclosed is a controlling apparatus for use in a photovoltaic system. The photovoltaic system includes a solar cell array, an inverter and a solar tracker. The solar tracker includes a solar position sensor, a controller connected to the solar position sensor, a first motor connected to the controller for rotating the solar cell array according to the azimuth of the sun and a second motor connected to the controller for tilting the solar cell array according to the elevation of the sun. The controlling apparatus includes a central unit, a basic unit, a diagnosis unit, a maintenance unit, a security unit and a check unit.

Abstract: A machine for tracking the sun's movement and concentrating sunlight consists of a main frame which pivots in the north and south direction on a base having conduit for a heat medium (a liquid usually of the Glycol family the main frame supports the mirror frame that pivots 360 degrees East to West allowing the mirror to focus the sunlight onto the conduit heating the liquid medium producing a very high and concentrated amount of heat during the entire daylight period and can be used for a small business or residential heating. An optional prism can be attached to the mirror frame to focus sun rays onto the conduit for added heat.

Abstract: A solar module arrangement for, in particular, solar-thermal and/or photovoltaic energy production, comprising at least three solar module elements (2) which are arranged in a substantially horizontal, flat composite and are each inclined relative to one another with respect to the horizontal plane (H) in such a way that side edges (4) which frame the solar module arrangement (1) are lower or higher than a substantially middle central region (6) relative to the horizontal plane (H). Furthermore, a roof arrangement with a plurality of solar module arrangements of the above-mentioned type, wherein the solar module arrangements (1) are arranged on subsections (22), which run substantially parallel to one another, of the side borders (4) of adjacent solar module arrangements (1) to form an, in particular, diamond-shaped, roof arrangement (30).

Abstract: Disclosed is a solar water heating apparatus comprising a central tank and one or more outer layers wherein at least part of the exterior of the outermost layer is adapted to be exposed to the sun. The outer layers also form water pathways such that, when the tank is substantially filled with water, said water is able to circulate around a path formed by said central tank and the outer layers. A pulsing pump may help circulate the water. An auxiliary heating element may be also provided, such as a small gas burner.

Abstract: A tracking system is provided for a roof-mounted solar array. The system includes a sensor mechanism for sensing an orientation of the sun relative to the solar array, and a controller connected to the sensor mechanism that generates a signal that represents an optimal tilt angle of the solar array relative to the orientation of the sun. An actuator connected to the controller receives the signal from the controller and adjusts the tilt angle of the solar array in response to the received signal.

Abstract: A control system includes a control module and one or more input sources. The control module is coupled to an output of the solar module in order to operate the solar panel so that an output of the solar panel is at a maximum power level. The control module is able to selectively decrease a current level of the solar panel's output in response to a condition that is indicative of a temperature of the solar panel while maintaining the power output of the solar panel at or within a designated percentage of the maximum level. The input source is coupled to the control module to provide an input that is indicative of the temperature.

Abstract: Adherence to flux or resultant measurable parameter limits, ranges, or patterns can be achieved by directing heliostat mounted mirrors to focus on aiming points designated on the surface of a solar receiver. Different heliostats can be directed to different aiming points, and a heliostat can be directed to different aiming points at different times. The cumulative flux distribution resulting from directing a plurality of heliostats to any aiming point on a receiver surface can be predicted by using statistical methods to calculate the expected beam projection for each individual heliostat or alternatively for a group of heliostats. Control of the heliostats in a solar power system can include designating aiming points on a receiver from time to time and assigning heliostats to aiming points from time to time in accordance with an optimization goal.

Abstract: A combined diurnal tracking, concentrator, photovoltaic plus domestic hot water solar thermal system is mountable on flat roof industrial buildings or multi-unit apartment buildings for diurnal tracking, and on pitched roofs of single family residences. The systems are configured to reduce the number of solar cells required for given power output, and increased generated heat by a concentration of the sun's insolation on the solar cells. The increased heat is drawn off by anti-freeze fluid circulated in an aluminum extrusion attached to the solar cells and concentrator reflectors for the dual purpose of providing domestic hot water or space heating and maintaining the solar cells cool to enhance their efficiency.

Abstract: An automatic sunlight redirector comprises of a device which redirects sunlight to a place of user's choice. This is a universal model and does not need data and microprocessor to track the sun at different latitudes, nor does it need any computer to calculate the angle of reflectance. This device works on principle of arranging incident sun-ray, target-line and the mirror-axis as sides of an isosceles triangle and is realized by the devices of sun-tracking director-bar, a slide fitted on this director-bar, and a groove on the mirror-axis pipe/bar (5) for free movement of the director-bar (10) which not only tracks the sun but continuously adjusts the position of the mirror such that the light is reflected on the fixed target. The declination-setter (8) and time-setter (15) track the daily changes in the declination of the sun and the length of the day respectively.

Abstract: A solar lighting apparatus of the sun tracking type for guiding sunlight into a building by using light reflecting means (30), the apparatus comprising the light reflecting means (30) for reflecting sunlight, drive means (60) for driving the light reflecting means, control means (70) for controlling the drive means to orient the light reflecting means toward the direction of the sun, and power source means (20) for supplying electric power to the drive means and the control means. The power source means (20) comprises a main power source unit (22) chargeable by a solar cell panel (40) for supplying electric power to the drive means (60) and the control means (70), and a backup secondary cell (24) chargeable with the electric power from the main power source unit for supplying electric power to the control means (70).

Abstract: A camouflaged structure and a method of camouflaging a structure against a background having a generally uniform composition of hue, saturation and brightness. In one embodiment, the camouflaged structures comprises a cell tower (100) camouflaged to decrease its visual impact when viewed by a viewer against a background sky (122) from an expected vantage point (102) using camouflaging techniques according to various aspects of the present invention. In a first aspect, the camouflage technique of the present invention comprises applying regions of color to one or more components of cell tower, wherein the colors are selected to match the composition (hue, saturation and brightness) of the background sky. In a seconds aspect, the camouflage technique of the present invention comprises providing one or more components of cell tower with reflectors that reflect light from an ambient sky (124) to a viewer.

Abstract: A tracking type photovoltaic power generator includes a clock for clocking a time and a sun direction sensor for outputting a signal indicative of a sun direction, a controller which calculates a first time when the sun the sun arrives at a culmination azimuth on the basis of the time clocked by the clock, detects a culmination azimuth on the basis of a difference between a second time when the culmination azimuth is detected and the first time. Accordingly, the generator automatically corrects the error of the time clocked by the clock.