A protective transparent enclosure (such as a glasshouse or a greenhouse) encloses a concentrated solar power system. The concentrated solar power system includes one or more solar concentrators and one or more solar receivers. Thermal power is provided to an industrial process, electrical power is provided to an electrical distribution grid, or both. In some embodiments, the solar concentrators are parabolic trough concentrators with one or more lateral extensions. In some embodiments, the lateral extension is a unilateral extension of the primary parabolic trough shape. In some embodiments, the lateral extensions are movably connected to the primary portion. In some embodiments, the lateral extensions have a focal line separate from the focal line of the base portion. In some embodiments, the greenhouse is a Dutch Venlo style greenhouse.

A protective transparent enclosure (such as a glasshouse or a greenhouse) encloses a concentrated solar power system. The concentrated solar power system includes one or more solar concentrators and one or more solar receivers. Thermal power is provided to an industrial process, electrical power is provided to an electrical distribution grid, or both. In some embodiments, the solar concentrators are parabolic trough concentrators with one or more lateral extensions. In some embodiments, the lateral extension is a unilateral extension of the primary parabolic trough shape. In some embodiments, the lateral extensions are movably connected to the primary portion. In some embodiments, the lateral extensions have a focal line separate from the focal line of the base portion. In some embodiments, the greenhouse is a Dutch Venlo style greenhouse.

A thermoelectric device includes a flexible first substrate, and a number of sets of N and P thermoelectric legs coupled to the first substrate. Each set includes an N and a P thermoelectric leg electrically contacting each other through a conductive material on the first substrate. The thermoelectric device also includes a rigid second substrate, a conductive thin film formed on the second substrate, and a number of pins corresponding to the number of sets of N and P thermoelectric legs. Each pin couples the each set on an end thereof away from the first substrate to the conductive thin film formed on the second substrate, and is several times longer than a height of the N and P thermoelectric legs.

A solar collector with reflecting surfaces according to the present invention prevents overheating of the solar collector by reflecting the radiation in a way that the light beams, by means of a first transparent surface, are corrected to the preferred angle and further directed towards channels. On a second transparent surface the beams are directed again and on a third transparent surface the light beams are reflected if in the channels is air. If the working fluid flows through the channels, on the third surface there is no reflection, so the light beams pass through the opaque part of an absorber where the solar radiation is converted into the thermal energy that is then removed by the working fluid.

A solar collector with reflecting surfaces according to the present invention prevents overheating of the solar collector by reflecting the radiation in a way that the light beams, by means of a first transparent surface, are corrected to the preferred angle and further directed towards channels. On a second transparent surface the beams are directed again and on a third transparent surface the light beams are reflected if in the channels is air. If the working fluid flows through the channels, on the third surface there is no reflection, so the light beams pass through the opaque part of an absorber where the solar radiation is converted into the thermal energy that is then removed by the working fluid.

The disclosed invention relates to solar-thermal receiver tubes for heating high-temperature fluids such as molten salts and oils, such as those used in conjunction with trough reflectors or concentric concentrators. The disclosed invention utilizes fused silica receiver tube assemblies that provide optical absorption by way of optically-absorbing media that is imbedded within the thermal transfer fluid, preferably comprising inorganic dyes that comprise pulverized thin film coatings or dissolved materials that are specifically designed for maximizing optical absorption. Alternatively, the chemistry of the transfer fluid can be modified to increase optical absorption, or the optically absorbing media may comprise fine powders with density preferably similar to the thermal transfer fluid, such as fine graphite powder; or, in another preferred embodiment, absorbing means within the heat transfer fluid comprise a solid absorbing element disposed along the central axis of the receiver tube's interior.

To reduce the overall environmental impact of a residence or commercial facility, a system is provided for integrating energy usage. In such a system, there is a system for capturing solar energy; a system for fermenting biomass and concentrating the fermentate, generating carbon dioxide and ethanol; a system for storing excess energy for subsequent release; and a system for growing biomass. In integrating the systems, the captured solar energy is used as heat and electrical power. Excess energy beyond an instantaneous energy requirement is stored in the system for storing excess energy. Ethanol produced is used as a fuel. Carbon dioxide that is produced is provided to the system for growing biomass. Instantaneous energy deficiencies are reduced by releasing stored excess energy.

A hybrid solar-thermoelectric device includes a solar device and a thermoelectric device coupled thereto. The thermoelectric device includes a flexible first substrate, and a number of sets of N and P thermoelectric legs coupled to the first substrate. Each set includes an N and a P thermoelectric leg electrically contacting each other through a conductive material on the first substrate. The thermoelectric device also includes a rigid second substrate, a conductive thin film formed on the second substrate, and a number of pins corresponding to the number of sets of N and P thermoelectric legs. Each pin couples the each set on an end thereof away from the first substrate to the conductive thin film formed on the second substrate, and is several times longer than a height of the N and P thermoelectric legs.

A system and method of extracting frozen water from soil or a regolith and capturing the water is provided. More specifically, the present disclosure relates to a water collection system to extract and collect water from regolith. The system is configured to heat the regolith in situ to a temperature at which frozen water in the regolith will vaporize. The water vapor is then captured and collected. In one embodiment, the system includes a power system to provide energy to the regolith to heat the regolith, an enclosure to trap the water vapor released from the heated regolith, and a container operably interconnected to the enclosure to collect the water vapor. In one embodiment, the system can be positioned at a production facility on the Earth, the Moon, Mars, or an asteroid.

A swimming pool cover with lenses is disclosed. The swimming pool cover uses lenses to focus ambient solar energy into the water of a swimming pool. In one embodiment, a plurality of rectangular lenses is connected at their edges by a minimal amount of connecting or gusset material, in order to create an impermeable sheet, while maximizing the amount of incident solar energy absorbed by the swimming pool water. The swimming pool cover also protects detritus from falling into the swimming pool, while at the same time, reduces the amount of heat loss through evaporation. In another embodiment, the gusset material connects a plurality of lenses, varying in both size and shape.