A cooling system for a photovoltaic panel including micro flat heat pipes (HP) integrated with thermoelectric generators (TEG) and a cooled water reservoir for cooling the working fluid in heat pipes. The cooled water in the reservoir is pumped from the condensate pan of an air conditioner. Experimental results show that cooling system reduced the average temperature of the panel by as much as 19° C. or 25%. Further, the output power of the photovoltaic panel increased by 44% when the photovoltaic panel was used in a very hot climate (30-40° C.). An additional two watts of power was generated by the TEGs.

A cooling system for a photovoltaic panel including micro flat heat pipes (HP) integrated with thermoelectric generators (TEG) and a cooled water reservoir for cooling the working fluid in heat pipes. The cooled water in the reservoir is pumped from the condensate pan of an air conditioner. Experimental results show that cooling system reduced the average temperature of the panel by as much as 19° C. or 25%. Further, the output power of the photovoltaic panel increased by 44% when the photovoltaic panel was used in a very hot climate (30-40° C.). An additional two watts of power was generated by the TEGs.

A solar energy particle receiver system and method of use for precise and controlled heating, sintering, and/or phase change of particles. In one embodiment, the solar energy particle receiver system directs sunlight from a primary concentrator into supplemental concentrating reflective optic where the emitted sunlight is used to heat and sinter, melt, or induce a phase change of the particles such as regolith at a controlled temperature, the supplemental concentrating reflective optics cooled to prevent overheating and a sweeping gas directed at the reflective surface to prevent optical fouling. In one aspect, the supplemental concentrating reflective optic is a compound reflective concentrator. In one application, the particles are a regolith, such as a lunar regolith.

A solar energy particle receiver system and method of use for precise and controlled heating, sintering, and/or phase change of particles. In one embodiment, the solar energy particle receiver system directs sunlight from a primary concentrator into supplemental concentrating reflective optic where the emitted sunlight is used to heat and sinter, melt, or induce a phase change of the particles such as regolith at a controlled temperature, the supplemental concentrating reflective optics cooled to prevent overheating and a sweeping gas directed at the reflective surface to prevent optical fouling. In one aspect, the supplemental concentrating reflective optic is a compound reflective concentrator. In one application, the particles are a regolith, such as a lunar regolith.

The present invention limits fluid temperature at a point in a fluidic system to below a predetermined temperature by cooling the fluid when needed and without requiring a separate cold fluid source. The present invention “clips” the temperature of the fluid at a point in the system to within a temperature range and prevents overcooling the fluid. When the fluid temperature is below the temperature range, the temperature of the fluid is unchanged as it passes through the apparatus of the present invention. The present invention may operate without external power, can function in any orientation, and works for unpressurized and pressurized systems. The present invention has application in the areas of solar thermal energy systems, fluid tanks, engine oil and coolant systems, transmission fluid systems, hydraulic systems, machining fluid systems, cutting fluid systems, nuclear reactors and chemical reactors, among others.

A hybrid power and heat generating device (100) comprising: a photovoltaic solar power collector (102) configured to collect solar power from solar radiation received on an active side (103) of the photovoltaic solar power collector; and a heat exchanging unit (104) configured to cool the photovoltaic solar power collector, which heat exchanging unit includes a cooling plate (106;404;504704) arranged to transfer heat from the photovoltaic solar power collector (102) to a cooling medium. The heat exchanging unit (104) is adapted to transport the cooling medium away from the cooling plate (106;404;504;704) for heat extraction from the cooling medium. The cooling plate (106;404;504;704) is arranged with a gap (110) from a rear side (111) of the photovoltaic solar power collector (102) and the cooling medium is arranged to cool the cooling plate (106;404;504;704) to a temperature which allows water vapor of the ambient air in the gap (110) to condensate into water on the cooling plate (106;404;504;704) in the gap (110). The hybrid power and heat generating device (100) being operable in at least two operation modes; a normal operation mode in which the gap (110) is at least partly filled with condensed water, which condensed water transfers heat from the photovoltaic solar power collector (102) to the cooling plate (106;404;504;704); and a security operation mode in which the gap (110) is filled with air to thereby reduce the heat transfer from the photovoltaic solar collector (102) to the cooling plate (106;404;504;704).

A hybrid power and heat generating device (100) comprising: a photovoltaic solar power collector (102) configured to collect solar power from solar radiation received on an active side (103) of the photovoltaic solar power collector; and a heat exchanging unit (104) configured to cool the photovoltaic solar power collector, which heat exchanging unit includes a cooling plate (106;404;504704) arranged to transfer heat from the photovoltaic solar power collector (102) to a cooling medium. The heat exchanging unit (104) is adapted to transport the cooling medium away from the cooling plate (106;404;504;704) for heat extraction from the cooling medium. The cooling plate (106;404;504;704) is arranged with a gap (110) from a rear side (111) of the photovoltaic solar power collector (102) and the cooling medium is arranged to cool the cooling plate (106;404;504;704) to a temperature which allows water vapor of the ambient air in the gap (110) to condensate into water on the cooling plate (106;404;504;704) in the gap (110). The hybrid power and heat generating device (100) being operable in at least two operation modes; a normal operation mode in which the gap (110) is at least partly filled with condensed water, which condensed water transfers heat from the photovoltaic solar power collector (102) to the cooling plate (106;404;504;704); and a security operation mode in which the gap (110) is filled with air to thereby reduce the heat transfer from the photovoltaic solar collector (102) to the cooling plate (106;404;504;704).

Devices and methods for concentrated radiative cooling using radiative cooling coatings in combination with mid-infrared reflectors. Concentrated radiative cooling (CRC) devices include an object to be cooled that is coated with a radiative cooling material and a mid-infrared (mid-IR) reflector configured to reflect thermal energy radiated from a surface of the object to deep space. The object may be nested in a mid-IR reflective trough such that substantially an entirety of the object's surface area contributes to radiative cooling. The radiative cooling material may be a coating such as a paint or film that is applied directly to the object's exterior surfaces to reduce thermal resistances. The radiative cooling coating is configured to lose thermal energy from the object by means of exhibiting high emissivity for wavelengths of 8 to 13 micrometers, and in some arrangements of 5 to 30 micrometers.

Devices and methods for concentrated radiative cooling using radiative cooling coatings in combination with mid-infrared reflectors. Concentrated radiative cooling (CRC) devices include an object to be cooled that is coated with a radiative cooling material and a mid-infrared (mid-IR) reflector configured to reflect thermal energy radiated from a surface of the object to deep space. The object may be nested in a mid-IR reflective trough such that substantially an entirety of the object's surface area contributes to radiative cooling. The radiative cooling material may be a coating such as a paint or film that is applied directly to the object's exterior surfaces to reduce thermal resistances. The radiative cooling coating is configured to lose thermal energy from the object by means of exhibiting high emissivity for wavelengths of 8 to 13 micrometers, and in some arrangements of 5 to 30 micrometers.

A heat rejection system that employs temperature sensitive shape memory materials to control the heat rejection capacity of a vehicle to maintain a safe vehicle temperature. The technology provides for a wide range of heat rejection rates by actuation of the orientation or position of a heat rejection panel which impacts effective properties of the heat rejection system in response to temperature. When employed as a radiator for crewed spacecraft thermal control this permits the use of higher freezing point, non-toxic thermal working fluids in single-loop thermal control systems for crewed vehicles in space and other extraterrestrial environments.