Abstract: New high energy operating regimes for high intensity energy transfer for beam receiving, signal acquisition, and beam or signal generation for power beaming and wireless power transmission are made possible by new direct thermal pathways for heat sinking, where an energy conversion device comprises a plurality of fins [1] originating from inside the energy conversion device; [2] formed from an energy conversion device component; and where those fins [3] individually support traffic in energy carriers essential to the function of the energy conversion device. This allows high energy thermal interfacing and high intensity energy conversion, such as for receiving and transducing extremely high intensity light shined onto a small surface semiconductor device such as a vertical multijunction photovoltaic receiver. This allows high intensity energy transfer for beam receiving, signal acquisition, and beam or signal generation for high intensity power beaming and wireless power transmission.

Abstract: Thermal, electrical and/or optical interfacing for three-dimensional optoelectronic devices, such as semiconductor device billets, allows high intensity operation, such as for receiving and transducing extremely high intensity light shined onto a small surface semiconductor optoelectronic device such as a photovoltaic receiver or cell, transducer, waveguide or splitter. This allows high intensity energy transfer for beam receiving, signal acquisition, and beam or signal generation for high intensity power beaming and wireless power transmission. Preferred embodiments include three-dimensional photovoltaic receiver billets capable of receiving thousands of suns intensity or high intensity laser light for power conversion, such as by using edge-illuminated vertical multijunction photovoltaic receivers. Heat sink holding structures assist in thermal and electromagnetic communication with opposing billet surfaces.

Abstract: Extremely fast dynamic control is allowed for hybrid PV/T (photovoltaic/thermal) distributed power production using concentrated solar power by manipulating the transmissive or reflective state of a capture element or mirror or lens that can pass highly concentrated solar light from one energy conversion device to another, such as a thermal collector and a photovoltaic receiver, such as a vertical multijunction cell array. This allows superior quality electrical backfeed into an electric utility, enhanced plant electrical production revenue, and responsiveness to a multitude of conditions to meet new stringent engineering requirements for distributed power plants. The mirror or lens can be physically articulated using fast changing of a spatial variable, or can be a fixed smart material that changes state. A mechanical jitter or variable state jitter can be applied to the capture element, including at utility electric grid line frequency.

Abstract: Provided is a solar collector assembly that can be manufactured, assembled, and maintained efficiently. A number of arrays that include one or more reflective material formed in a parabolic shape can be attached to a backbone. The backbone is attached to a polar support that is positioned at or near the center of gravity for the solar collector assembly. The polar support at or near the center of gravity allows the entire assembly to be tilted, rotated and/or lowered for various purposes (e.g., service, maintenance, safety). The solar collector assembly can be transported as modular units and/or in a partially assembled state.

Abstract: System(s) and method(s) are provided for assembling and utilizing parabolic reflectors in a solar concentrator. Parabolic reflectors assembly starts with a low-cost, flat reflective material that is bent into a parabolic or trough shape via a set of support ribs that are affixed in a support beam. The parabolic reflectors are mounted on a support frame in various panels or arrays to form a parabolic solar concentrator. Each parabolic reflector focuses light in a line segment pattern. Light beam pattern focused onto a receiver via the parabolic solar concentrator can be optimized. The receiver is attached to the support frame, opposite the parabolic reflector arrays, and includes a photovoltaic (PV) module and a heat harvesting element that enable dual-mode energy conversion operation. To increase performance of the parabolic solar concentrator, the PV module can be configured to advantageously exploit a light beam pattern optimization regardless irregularities in the pattern.

Abstract: A system (and corresponding methodology) for testing, evaluating and diagnosing quality of solar concentrator optics is provided. The innovation discloses mechanisms for evaluating the performance and quality of a solar collector via emission of modulated laser radiation upon (or near) a position of photovoltaic (PV) cells. The innovation discloses positioning two receivers at two distances from the source (e.g., solar collector or dish). These receivers are employed to collect modulated light which can be compared to standards or other thresholds thereby diagnosing quality of the collectors.

Abstract: Systems and methods that employ a vertical multi junction (VMJ) photovoltaic cell, to provide electrolysis for water and generate hydrogen and oxygen. Electrical current generated by the VMJ flows through the electrolyte (e.g., salt water) for a decomposition thereof (e.g., hydrogen and oxygen)—whenever threshold voltage of electrolysis operation is reached (e.g., 1.6 volts for water electrolysis).

Abstract: Systems and methods that employ a vertical multi junction (VMJ) photovoltaic cell, to provide electrolysis for water and generate hydrogen and oxygen. Electrical current generated by the VMJ flows through the electrolyte (e.g., salt water) for a decomposition thereof (e.g., hydrogen and oxygen)—whenever threshold voltage of electrolysis operation is reached (e.g., 1.6 volts for water electrolysis).

Abstract: A solar collector can be rotated and tilted about a polar mount. The solar collector can be designed such that the center of gravity of the collector is aligned with the axis of the polar mount facilitating the use of smaller positioning devices. The collector can be placed in a position to prevent damage by inclement weather and allow easy access for maintenance and installation.

Abstract: When using a solar concentrator to obtain energy collected from the sun, it can be beneficial to place the concentrator accurately. As the concentrator moves, a position of the concentrator with respect to gravity can be determined, such as through the use of an inclinometer. A comparison can be made of the determined position against a desired position. The comparison can be made to determine if the concentrator should move. If a positive determination is made, then the concentrator can be moved accordingly.

Abstract: Systems and methods that provide a barrier for protection of active layers associated with a vertical multi junction (VMJ) photovoltaic cell. Buffer zone(s) in form of an inactive layer(s) arrangement safe guard the active layers against induced stress or strain resulting from external forces/thermal factors (e.g., welding). The buffer zone can be in form of a rim on a surface of an end layer of a cell unit, to act as a protective boundary for such active layer, and to further partially frame the VMJ cell for ease of handling and transportation.

Abstract: Systems and methods that provide a barrier for protection of active layers associated with a vertical multi junction (VMJ) photovoltaic cell. Buffer zone(s) in form of an inactive layer(s) arrangement safe guard the active layers against induced stress or strain resulting from external forces/thermal factors (e.g., welding). The buffer zone can be in form of a rim on a surface of an end layer of a cell unit, to act as a protective boundary for such active layer, and to further partially frame the VMJ cell for ease of handling and transportation.