Abstract: A protective transparent enclosure (such as a glasshouse or a greenhouse) encloses a concentrated solar power system. The concentrated solar power system includes one or more solar concentrators and one or more solar receivers. Thermal power is provided to an industrial process, electrical power is provided to an electrical distribution grid, or both. In some embodiments, the solar concentrators are parabolic trough concentrators with one or more lateral extensions. In some embodiments, the lateral extension is a unilateral extension of the primary parabolic trough shape. In some embodiments, the lateral extensions are movably connected to the primary portion. In some embodiments, the lateral extensions have a focal line separate from the focal line of the base portion. In some embodiments, the greenhouse is a Dutch Venlo style greenhouse.

Abstract: A mechanical solar tracking and solar concentrating system having a Fresnel lens, moving frame, track, retaining mechanism, and solar collector. The lens focuses solar energy at the collector; the frame holds the collector and lens, keeping them aligned as the frame rotates; the track guides the frame to maintain a perpendicular orientation to the Sun; the solar collector receives the Sun's rays; and the retaining mechanism releases at established intervals, allowing the frame to rotate to the next location. The cycle repeats, tracking the Sun and concentrating its rays at a focal point, to generate temperatures at the focal point in excess of 500° C. These high temperatures can be exploited in several applications, such as producing drinking water from dirty water; cooking food; disinfecting medical instruments; accelerating fermentation of certain types of flora to produce electricity; generating work for generic purposes; etc.

Abstract: A heliostat optimized to be positioned near a skylight or other aperture is disclosed. The heliostat comprises a plurality of reflective elements arranged in a substantially planar array, each element being mounted so as to be rotatable about a longitudinal axis of rotation. A first motor rotates the array about an axis substantially perpendicular to the plane of the array; and a second motor rotates the reflective elements about their respective axes of rotation. A processor provides control signals to operate the first motor as required to orient the array such that the respective axes of rotation of the reflective elements are substantially perpendicular to an azimuth to the sun and to operate the second motor as required to rotate the reflective elements about their respective axes of rotation to position the reflective element to reflect the sun's light to a target area.

Abstract: A passive solar tracking system to enhance solar cell output is provided. The passive solar tracking system includes a panel having at least one solar cell for solar-to-electric conversion and an actuator that is arranged for moving the panel to provide the variable facing direction of the panel. The actuator is directly driven by light such as sunlight to provide artificial heliotropism-type movements of the panel, so that the panel passively tracks and continuously faces the sun. The actuator may be made from a composite material including a matrix of liquid crystal elastomer material incorporating single-wall or multi-wall carbon nanotubes and an elastic skeleton defined by a 3D polyurethane fiber-network. An actuator housing may be arranged with respect to the actuator for enhancing delivery of stimulus to the actuator. The actuator housing may include a heat collector and a light concentrator for facilitating actuation of the actuator.

Abstract: A heliostat optimized to be positioned near a skylight or other aperture is disclosed. The heliostat comprises a plurality of reflective elements arranged in a substantially planar array, each element being mounted so as to be rotatable about a longitudinal axis of rotation. A first motor rotates the array about an axis substantially perpendicular to the plane of the array; and a second motor rotates the reflective elements about their respective axes of rotation. A processor provides control signals to operate the first motor as required to orient the array such that the respective axes of rotation of the reflective elements are substantially perpendicular to an azimuth to the sun and to operate the second motor as required to rotate the reflective elements about their respective axes of rotation to position the reflective element to reflect the sun's light to a target area.

Abstract: The invention is a system and method for heliostat mirror control. Here, each heliostat mirror generates a low intensity “signal beam”, directed at an angle off from the heliostat mirror's high intensity and sensor blinding “main beam” of reflected solar energy. The low intensity signal beams may be created by reflecting a small portion of the incident solar light at an angle from the main beam, by reflected artificial light, or from lasers shinning onto mirrors from known locations. The signal beams are detected by optical sensors mounted way from the main heliostat receiver focus, and can be used in a closed loop control system to efficiently ensure that individual heliostat mirrors in a heliostat array accurately track sunlight and direct the sunlight to a central receiver. Because heliostat mirrors need not be taken “off sun” for positioning, the system allows heliostat arrays to be run at high efficiency.

Abstract: A solar tracking sensor and methods of tracking the sun. In one embodiment, the solar tracking sensor includes a housing, an inclinometer to output a signal indicative of the angle of the housing relative to the gravitational pull of the Earth, and first and second photosensors located on a first plane located within the housing. An opening on one side of the housing allows solar radiation to pass through the housing and reach the first and second photosensors. A difference calculating module is coupled to the first photosensor and the second photosensor. The difference calculating module determines a photosensor difference value using signals from the photosensors and outputs a photosensor difference value. The photosensor difference value can be used by a controller. The controller is coupled to the inclinometer determines whether the opening is aligned with the Sun based on the photosensor difference value and information or signal from the inclinometer.

Abstract: A system for and method of reducing the effects of preheat period variation in shape memory alloy actuation, include sensing the removal of motion delay due to slack, backlash, and/or compliance in the actuator and drive-train of the system, and determining actuator activation, as a result thereof.

Abstract: The invention relates to systems and methods for controlling angular position of a pivotable platform relative to a radiation source. In one embodiment, an apparatus for controlling angular position of a pivotable platform relative to a radiation source includes a frame, a thermal actuation element coupled to the frame, a pivotable platform positioned between the radiation source and the thermal actuation element so as to at least partially block energy from the radiation source from impinging on the thermal actuation element, and apparatus for pivoting the pivotable platform in response to a thermally controlled deformation of the thermal actuation element.

Abstract: Apparatus and methods related to solar energy are provided. A system includes a solar array supported to be angularly repositionable. A shuttle and linkage arrangement is coupled to the solar array. Thermally activated actuators sequentially control the linear translation of the shuttle such that the solar array is incrementally angularly repositioned over the course of a daylight period. Concentrated solar energy is used to heat the actuators in their sequential order. Systems for generating electrical and/or thermal energy, embodied as panels or other form-factors, are contemplated.

Abstract: The invention discloses a novel and efficient drive mechanism for use in a variety of applications. This novel mechanism replaces traditional stepper motors or another analogous art with shape memory alloys. The drive mechanism so disclosed provides substantial operational benefits over conventional motors and other such traditional drive mechanisms that would be used in similar applications. The drive mechanism includes a high gear-ratio worm gear and worm drive which further provides precise, controlled movement of an output shaft. In the illustrative use elaborated upon herein, the motor is used to drive a photovoltaic panel so that the panel may remain in appropriate alignment with the sun throughout the day.

Abstract: The invention discloses a novel and efficient drive mechanism for use in a variety of applications. This novel mechanism replaces traditional stepper motors or another analogous art with shape memory alloys. The drive mechanism so disclosed provides substantial operational benefits over conventional motors and other such traditional drive mechanisms that would be used in similar applications. The drive mechanism includes a high gear-ratio worm gear and worm drive which further provides precise, controlled movement of an output shaft. In the illustrative use elaborated upon herein, the motor is used to drive a photovoltaic panel so that the panel may remain in appropriate alignment with the sun throughout the day.

Abstract: In a first embodiment a framed solar panel is retained by a rod inserted through a hole in the panel frame. The rod is attached to the top of a bracket, which is mounted at its bottom to a substantially flat surface. In a second embodiment, a framed solar collector panel is retained by a clip which is designed to fit over the top edge of the frame. The clip is then attached to the top of a second bracket. In a fourth embodiment a tether is fastened between the through hole and the flat surface. These embodiments may be used at either or both ends of the frame. Each embodiment may include a safety tether that is connected between the frame and the bracket.

Abstract: An autonomous heliostat (1) having an independent autonomous control function and eliminating the need for a complicated control by a computer or the like is provided. The heliostat includes a target sensor (19) for controlling reflected light (R) from a mirror component (5) to direct it to the target sensor 19, and a search sensor (12) for catching sunlight (S) to guide reflected light from the mirror component to the target sensor, thereby to autonomously start control by the target sensor.

Abstract: Solar collector device constituted by a pyramid-shaped structure comprising three faces 1, 2, 3 or more and a base 4. The face 1, on which various solar energy collecting means are mounted, is the only face used as a planar solar collector, the other faces 2, 3 serving merely to protect the overall device from the wind. The solar collector device is also provided with two different tracking systems: a first system, which operates in azimuth, enabling the pyramid-shaped structure, by a rotation about a vertical axis V, to maintain face 1 in the direction of the sun, and a second system, which operates in elevation, enabling face 1, by a rotation about a horizontal axis H, to keep an inclination normal to the sun's rays.

Abstract: In order to generate sufficient electricity in a small light converging solar module, a power generation solar cell is provided with four movement solar cells, situated around it. Below the respective movement solar cells, electromagnets are situated, connected to corresponding movement solar cells. The power generation solar cell, the movement solar cells, and the electromagnets are all mounted on a cell holder, around which a permanent magnet in the form of a ring is provided. When a converged spot moves its position from on the power generation solar cell to a position off the power generation solar cell, and onto one of the movement solar cells, electricity is supplied to the corresponding electromagnet, thereby moving the cell holder due to attracting forces generated between the electromagnet and the permanent magnet. After the cell holder is moved to such a point where the converged spot correctly falls on the power generation solar cell, the cell holder stops its movement.