An apparatus for harvesting energy, such as solar, wind, wave, thermal, and the like, including a solar panel and a duct supporting the solar panel at an operational angle. The duct comprises a bottom shroud and side shrouds, therein forming a large aperture, a small aperture, and an oblique frustum shaped cavity. The oblique frustum shaped cavity is configured to direct a flow of fluid from the large aperture to the small aperture. A flow energy generator, such as a turbine, located at the small aperture is configured to collect flow energy. Temperature differences between the solar panel and the environment may be used to harvest thermal energy with a thermoelectric generator. Fluid flow under the solar panel may decrease the panel temperature and increase the efficiency. Generators may be operated in reverse to lower the solar panel temperature and increase efficiency.

A photovoltaic system includes a photovoltaic cell including a sun tracker, a top surface configured to generate electrical energy from the incident sunlight, and a bottom surface configured to thermally dispel heat generated by the photovoltaic cell; at least one mirror including a reflective surface; a plurality of actuators securing the at least one mirror the photovoltaic cell; at least one actuator pump connected to the plurality of actuators and configured to extend or retract the plurality of actuators and adjust the distance of the at least one mirror from the top surface; a heat exchanger thermally coupled to the bottom surface of the photovoltaic cell; and a fluid pump connected to the heat exchanger and configured to circulate the fluid through the heat exchanger.

An integrated photovoltaic (PV) panel-water sorption layer system that includes a PV panel having a front face that is configured to receive solar light for generating electrical current, and a back face that is opposite to the front face; and an atmospheric water harvesting device attached to the back face of the PV panel. The atmospheric water harvesting device is configured to cool down the PV panel by evaporating absorbed atmospheric water based on heat received from the PV panel.

An apparatus for generating electricity from solar energy has a large dish reflector with a fly's eye receiver positioned near the focus of the dish reflector, held by a dual axis tracking structure. The fly's eye receiver includes a field lens that concentrates sunlight into an image of the dish reflector, a two-dimensional fly's eye array of contiguous convex lenses extending across the dish image, and a photovoltaic cell behind each convex lens of the fly's eye array. Two imaging stages are provided. First, the dish reflector and the field lens concentrate the sunlight in the form of an image of the dish that is stabilized against pointing errors of the tracking mechanism. Second, the contiguous array of convex lenses divides the sunlight energy of the dish image into portions, one per convex lens, each portion being further concentrated by the respective convex lens onto a corresponding photovoltaic cell.

A photovoltaic system includes a photovoltaic cell including a sun tracker, a top surface configured to generate electrical energy from the incident sunlight, and a bottom surface configured to thermally dispel heat generated by the photovoltaic cell; at least one mirror including a reflective surface; a plurality of actuators securing the at least one mirror the photovoltaic cell; at least one actuator pump connected to the plurality of actuators and configured to extend or retract the plurality of actuators and adjust the distance of the at least one mirror from the top surface; a heat exchanger thermally coupled to the bottom surface of the photovoltaic cell; and a fluid pump connected to the heat exchanger and configured to circulate the fluid through the heat exchanger.

The present invention relates to a photo-electrochemical device for production of a gas, liquid or solid using concentrated electromagnetic irradiation. The device comprises a photovoltaic component configured to generate charge carriers from the concentrated electromagnetic irradiation; and an electrochemical component configured to carry out electrolysis of a reactant. The photovoltaic component contacts the electrochemical component at a solid interface to form an integrated photo-electrochemical device; and further includes at least one reactant channel or a plurality of reactant channels extending between the photovoltaic component and the electrochemical component to transfer heat and the reactant from the photovoltaic component to the electrochemical component. The integrated photo-electrochemical device and auxiliary devices (such as concentrator, flow controllers) build a system which can flexibly react to changes in operating condition and guarantee best performance.

An all-in-one solar panel-based generator case is disclosed. The case has a hinged lid having a solar panel. The contents of the case include multiple components. These components include a battery bank, a temperature controller for a vent fan, an electric vent fan unit for circulating air throughout the all-in-one solar panel-based generator case, a set of DC circuit breakers for DC accessory connectors, a lid charge controller, an auxiliary solar array charge controller, a power inverter, and a set of DC circuit breakers for solar power input.

A thermoelectric power generation system includes a solar panel array on a first side of a tower to absorb solar radiation and generate electrical energy and waste heat and a panel on a second side, opposite the first side, of the tower. A plurality of thermoelectric elements of the tower are interposed between the solar panel array and the panel. The plurality of thermoelectric elements converts conductive heat flow of the waste heat from the solar panel directed toward the panel to electrical energy. A conductive base supports the tower and to conduct heat away from the panel.

The invention relates to a photovoltaic module comprising a front bonding layer to photovoltaic cells are attached, such that the front side of each photovoltaic cell is attached to the front bonding layer. The photovoltaic module further comprises an open container containing a dielectric heat transfer fluid. The container comprises a bottom wall and side walls wherein the front bonding layer is disposed on top of the open container in order to close the container such that at least part of the backside (6a) of each photovoltaic cell is in contact with the dielectric heat transfer fluid.

A method of passive cooling for a high concentrating photovoltaic, the high concentrating photovoltaic, includes a photovoltaic receiver, a parabolic dish reflector and a plurality of thermally conductive heat pipes having a direct thermal contact between the receiver and the reflector to transfer excessive heat. The method includes receiving sunlight by the parabolic dish reflector, reflecting the sunlight towards the photovoltaic receiver that converts the sunlight into electricity and heat, transferring the heat through the thermally conductive heat pipes and absorbing the heat by the reflector serving a dual purpose as a heat sink. A reduction in weight and cost is accomplished by incorporating the flat heat pipes.