A spectrum splitting, transmissive concentrating photovoltaic (tCPV) module is proposed and designed for a hybrid photovoltaic-solar thermal (PV/T) system. The system may be able to fully utilize the full spectrum of incoming sunlight. By utilizing III-V triple junction solar cells with bandgaps of approximately 2.1 eV, 1.7 eV, and 1.4 eV in the module, ultraviolet (UV) and visible light (in-band light) are absorbed and converted to electricity, while infrared (IR) light (out-of-band light) passes through and is captured by a solar thermal receiver and stored as heat. The stored heat energy may be dispatched as electricity or process heat as needed. The tCPV module may have an overall power conversion efficiency exceeding 43.5% for above bandgap (in-band) light under a standard AM1.5D solar spectrum with an average concentration ratio of 400 suns. Passive and/or active cooling methods may be used to keep cells below 110 C. while transmitting >75% of out-of-band light to the thermal receiver, which may attain thermal energy capture at temperatures as high as 500 C. or more. A transparent active cooling system may improve the CPV module efficiency by about 1% (absolute) relative to a passive cooling system by reducing the maximum cell working temperature by about 16 C.

An energy storage type solar device comprises a light convergence device (110), a photoelectric conversion device (120), a rechargeable battery (130), a thermal energy storage device (140), and a heat dissipation-insulation control mechanism (150). A heat storage substance (141) of the thermal energy storage device (140) is in thermally conductive connection with the photoelectric conversion device (120) and the rechargeable battery (130). In the energy storage type solar device, the thermal energy storage device (140) is used to store thermal energy, and the heat dissipation-insulation control mechanism (150) is used to controllably at least partially allow or prevent heat exchange between the heat storage substance (141) and an external environment, such that the photoelectric conversion device (120) and the battery can be cooled down in a hot weather condition and thermal insulation of the battery can be performed in a cold weather condition.

A coolant loop for trough-reflector solar energy conversion systems has open coolant supply and discharge reservoirs. Coolant is driven by siphoning pressure through cooling channels which have attached solar cell arrays. The siphoning pressure is produced by maintaining the free surface of coolant in a coolant supply reservoir at a higher elevation than the free surface of coolant in a coolant discharge reservoir. The cooling channels have air evacuation and air inlet ports to facilitate initiation and termination of siphon-pressure-driven coolant flow. The cooling channels also have in-line flow control valves that respond to control signals generated by coolant temperature sensors.

Various embodiments of the present disclosure relate to systems and processes for collecting solar energy. According to particular embodiments, a solar collector device comprises one or more primary reflectors, and a receiver assembly mounted on a frame structure. The receiver assembly comprises one or more secondary concentrators and a heat transfer tube. Each primary reflector comprises a flat elongated mirror mounted on a structural backing that is rotatably coupled to the frame structure such that each primary reflector may pivot around a pivot axis. The receiver assembly may translate along the frame structure in a direction that is parallel to the pivot axes of the one or more primary reflectors. The one or more primary reflectors reflect light focused upon the receiver assembly such that heat energy from the reflected light is transferred to a heat transfer fluid in the heat transfer tube.

A blocking diode board (BDB) for use with a rollable solar power module (RSPM) array is disclosed. The DBD includes a blocking diode, first flat electrical conductor, second flat electrical conductor, first tubular hook, and second tubular hook.

Techniques for cooling concentrating solar collector systems are provided. In one aspect, an apparatus for cooling a photovoltaic cell includes a heat exchanger having a metal plate with a bend therein that positions a first surface of the metal plate at an angle of from about 100 degrees to about 150 degrees relative to a second surface of the metal plate, and a plurality of fins attached to a side of the metal plate opposite the first surface and the second surface; a vapor chamber extending along the first surface and the second surface of the metal plate, crossing the bend; and a cladding material between the vapor chamber and the heat exchanger, wherein the cladding material is configured to thermally couple the vapor chamber to the heat exchanger. A photovoltaic system and method for operating a photovoltaic system are also provided.

A solar thermophotovoltaic system includes a heat exchange pipe containing a heat exchange fluid, and a thin-film integrated spectrally-selective plasmonic absorber emitter (ISSAE) in direct contact with an outer surface of the heat exchange pipe, the ISSAE including an ultra-thin non-shiny metal layer comprising a metal strongly absorbing in a solar spectral range and strongly reflective in an infrared spectral range, the metal layer having an inner surface in direct contact with an outer surface of the heat exchange pipe. The system further includes a photovoltaic cell support structure having an inner surface in a concentric configuration surrounding at least a portion of the ISSAE; and an airgap separating the support structure and the outer surface of the metal layer. The support structure includes a plurality of photovoltaic cells arranged on a portion of the inner surface of the support structure and configured to receive emissions from the ISSAE, and a solar energy collector/concentrator configured to allow solar radiation to impinge a portion of the metal layer.

Methods and systems are provided for air conditioning, capturing combustion contaminants, desalination, and other processes using liquid desiccants.

A fluid cooled photovoltaic module in which a polymer heat exchanger transfers heat from the photovoltaic module to a circulated fluid. The photovoltaic module is maintained at a cool temperature enabling increased power output while the heat transferred to the circulated fluid can be useful for applications that require heat. A polymer heat exchanger is specifically utilized to achieve a robust design that is cost effective; high performance; easily adaptable to various photovoltaic module types and sizes; compatible with conventional photovoltaic module balance of systems; light weight; resistant to water sanitizers and other chemicals; resistant to lime-scale buildup and heat exchanger fouling; corrosion resistant; easily transported, assembled, installed, and maintained; and leverages high production manufacturing methods.

In one embodiment, a photovoltaic module includes a stack of layers, the module having an active layer and a planar heat sink positioned within the stack of layers adjacent the active layer, the heat sink being adapted to laterally remove heat from the active layer and the module.