An apparatus and method for simultaneous water disinfection and electricity generation includes a disinfection section and an electricity generating section. In some cases, the disinfection section includes a storage tank and a plurality of transparent vacuum tubes. In addition, the electricity generating section includes a base plate and a plurality of photovoltaic cells. Water disinfection is performed by exposing the disinfection section to sunlight radiation. Electricity generation is carried out by exposing the electricity generating section to the sunlight passing through the plurality of transparent vacuum tubes of the disinfection section.

A heat concentrator device for a solar power system includes an evacuated hollow body with a bottom, side walls, a top and an airtight cap. Portions of the side walls have inwardly reflective surfaces for concentrating solar radiation into the chamber toward a heat sink, which is positioned in the bottom of the chamber. The heat sink also is hollow and has an inlet port formed in one of its opposite side walls and an outlet port formed in the other for heat transfer fluid to flow into and out of the heat sink. Circuitous passageways form a maze that connects the inlet and outlet ports thus maximizing heat transfer to/from system fluid(s) within the heat sink. The sidewalls of the chamber of the device extend below the heat sink to form a partial vacuum chamber between its bottom and the heat sink. The device is mounted to a reflective dish of a solar power system in a unique way adding additional solar energy collection efficiencies.

An improvised Solar Concentrator and Absorber/Receiver Subsystem using a Dual-Stage Parabolic Concentrator for Concentrating Solar Power (CSP) (Thermal) system comprises of two parabolic mirrored reflectors wherein their apertures face each other with their focal point/line and axes coincides with each other, a plurality of absorber tubes/cavities placed on the non-reflecting side of the primary and/or secondary reflectors to carry heat transfer fluid, combined with relevant mechanisms to prevent/minimize thermal loss, mounted on a Sun tracking mechanism. For Concentrating Photovoltaic (CPV) and Concentrating Hybrid Thermo-Photovoltaic (CHTPV) Systems, all or a portion of the reflectors' reflecting and/or exterior surfaces would be covered or substituted with suitable photovoltaic panels.

Disclosed is an apparatus for generating power by amplifying sunlight, including a sunlight amplifying means; and an energy storing means configured to support the sunlight amplifying means and to store an electric energy and a thermal energy generated from the sunlight amplifying means, wherein the sunlight amplifying means includes a first pipe formed of metallic material; a second pipe configured to enclose the first pipe; a solar photovoltaic module installed between the first pipe and the second pipe; and a sunlight amplifying sheet configured with concave mirrors or convex lenses having predetermined shapes and attached to the outer circumference of the second pipe so as to amplify sunlight.

There is herein described energy storage systems. More particularly, there is herein described thermal energy storage systems and use of energy storable material such as phase change material in the provision of heating and/or cooling systems in, for example, domestic dwellings.

A solar heat collection tube with improved optical transmittance and durability to the external environment includes an inner tube through the interior of which a heat medium can flow, an outer tube that covers an outer periphery of the inner tube such that an annular heat insulating space is formed between the outer tube and the inner tube, and thermal expansion difference absorbing means or absorbing a thermal expansion difference between the inner tube and the outer tube. The outer tube is a glass tube, a first anti-reflection film is formed on an inner surface of the glass tube, a second anti-reflection film is formed on an outer surface of the glass tube, the second anti-reflection film is more durable to the external environment than the first anti-reflection film, and the first anti-reflection film has a higher optical transmittance than the second anti-reflection film.

An integrated solar energy drying system, including: a solar greenhouse, a solar energy storage bed, an air condenser, a wet dust collector, pipes, valves, and blowers. The solar greenhouse includes: a top side, three sunny sides, a shady side, floorboards, a gas inlet, and two gas outlets. The solar energy storage bed includes: an upper air box, a lower air box, a plurality of solar heat collecting-storing pipes, and a sealing chamber. Each solar heat collecting-storing pipe includes an air pipe. The air condenser includes: an air inlet, an air outlet, two gas chambers, and a bundle of gas pipes. The solar greenhouse, the solar energy storage bed, the air condenser, the wet dust collectors are connected via pipes. The valves and the blowers are disposed on the pipes.

An absorber tube is provided that includes a metal tube, a glass sleeve tube surrounding the metal tube, and a glass-metal transition element is disposed on at least one end. The metal tube and the transition element can be moved relative to one another in the longitudinal direction and connected to one another by an expansion compensating device. An inner end of the expansion compensating device is fastened to an attachment element, which is connected to the transition element. An outer end of the expansion compensating device is fastened to the metal tube. An annular space section of the annular space is constructed between the transition and attachment elements. The attachment element has an annular disc on which the expansion compensating device is fastened. The absorber tube has at least one shielding device that has a first annular disc-shaped section disposed on at least one end in the annular space.

The invention relates to a device for the concentration of solar radiation in an absorber, comprising an inflatable concentrator cushion, which comprises a cover film element comprising a light-permeable entry window for coupling in solar radiation and a reflector film, which sub-divides the concentrator cushion into at least two hollow spaces, for the concentration of solar radiation in an absorber, comprising a pivoting apparatus, by means of which the concentrator cushion can be pivoted, in particular about its longitudinal axis, and comprising a retaining apparatus secured (mounted) to the pivoting apparatus for retaining the concentrator cushion, which retaining apparatus comprising an upper longitudinal member extending in the longitudinal direction of the concentrator cushion, suspending the absorber, wherein the upper longitudinal member is arranged on a substantially air-tight closed upper passage opening of the concentrator cushion.

A central solar receiver (1) is provided having a heat exchanger assembly with walls that form an inlet chamber (2) and a generally juxtaposed outlet chamber (3) connected to each other by way of a multitude of tube assemblies (4). Each tube assembly (4) has an inner tube (6) and an outer tube (7) with the tube assemblies (4) extending away from the inlet and outlet chambers (2, 3). A remote end (8) of the outer tube (7) is closed and the inner tube (6) terminates short of that closed end (8). The interior of each inner tube (6) communicates with one of the inlet and outlet chambers (2, 3) and a space between each of the inner and outer tubes (6, 7) communicates with the other of the inlet and outlet chambers (2, 3) to form a passageway connecting the inlet and outlet chambers (2, 3) by way of the inner tube (6) and the space between the inner and outer tubes (6, 7) with a change in direction of flow of about 180.