Abstract: This disclosure describes embodiments of a receiver component that can support a plurality of photovoltaic devices, which collectively are useful to generate electricity from sunlight. The receiver component can comprise a substrate that integrates one or more bypass elements (e.g., a diode) and a cooling mechanism coupled to the substrate to dissipate thermal energy by dispersing a cooling fluid thereon. In this manner, embodiments of the receiver component combine in a single package the features necessary to maintain performance of the photovoltaic devices, e.g., to achieve sufficient electrical output while reducing costs and manufacturing time.

Abstract: This disclosure describes embodiments of a receiver component that can support a plurality of photovoltaic devices, which collectively are useful to generate electricity from sunlight. The receiver component can comprise a substrate that integrates one or more bypass elements (e.g., a diode) and a cooling mechanism coupled to the substrate to dissipate thermal energy by dispersing a cooling fluid thereon. In this manner, embodiments of the receiver component combine in a single package the features necessary to maintain performance of the photovoltaic devices, e.g., to achieve sufficient electrical output while reducing costs and manufacturing time.

Abstract: Embodiments of an apparatus that can convert energy across a broad spectrum of wavelengths. These embodiments utilize concentrating optics in combination with one or more of an integrated filter, a cooling mechanism, and a high-efficiency low current cell architecture to form efficient and cost-effective TPV devices. During operation, these components reduce the ratio of cell area to emitter area by concentrating the energy the emitter emits, thereby reducing the total cost of materials and promoting efficiency through integrating the filter and cooling mechanism into the device design.