A solar desalinator that converts contaminated water to potable water includes a cylindrical solar collector, a trough-shaped parabolic mirror, and a condenser. The solar collector is positioned within the trough-shaped parabolic mirror, and the parabolic mirror focuses the Sun's rays onto the solar collector, heats the water, and converts the water to steam. The steam is fed to the condenser where the steam is condensed to recover potable water. The solar collector includes an inner conduit surrounded by an outer shell with a vacuum in the anger space between. Energy absorbing material in the form of dark metal is positioned in the inner conduit. A residue bulb is attached at the contaminated water inlet to collect residue left by the creation of the steam.

The present disclosure describes a method for discharging a hydrogen storage system that is found in the annular space of a receiver tube, in particular for solar collectors, wherein the annular space is formed at least by an outer-lying tubular jacket and an inner-lying absorber tube of the receiver tube, and the outer-lying tubular jacket is joined by means of a wall to the absorber tube. The method is hereby characterized in that a first opening penetrating the tubular jacket or the wall is produced under a protective gas atmosphere, wherein protective gas enters through the first opening into the annular space, after which a process chamber with a connection for a vacuum pump is arranged in a gas-tight manner above the first opening, the receiver tube is evacuated through the first opening, and the first opening is subsequently sealed in a gas-tight manner.

A solar heat collector includes a plurality of heat collecting tubes connected in series. The heat collecting tubes each include: a heating-medium circulating tube through which a heating medium circulates; a glass tube that covers an outer peripheral surface of the heating-medium circulating tube and forms an annular space between the glass tube and the heating-medium circulating tube; and a getter member that adsorbs a gas that exists within the annular space. The heat collecting tube on a downstream side of the heating medium includes a larger number of the getter members than the heat collecting tube on an upstream side of the heating medium.

Provided is a solar collector that captures and utilizes solar energy and includes a plurality of vacuum tubes which are disposed by extending horizontally and are disposed parallel to each other with a predetermined distance; and a reflection plate having a substantially planar shape, which reflects solar light on an opposite side of the sun with respect to the plurality of vacuum tubes, in which the reflection plate includes a reflection surface having a serrated section at a corresponding position between vacuum tubes adjacent to each other, and in the reflection surface, one face of a serration forms a first reflection surface that reflects the solar light to the vacuum tube on a lower side among the vacuum tubes adjacent to each other.

The described embodiments provide thermal energy via solar powered heat exchangers. This energy can be implemented to heat hot water or heat residential/commercial structures. Parallel mounted vacuum insulated tubes heat water within a geometric heat transfer piping system. This thermal energy is transferred via a piping system to an insulated tank. A digital controller monitors and controls the temperature of the water within the system as well as provides frost/freezing protection. An electrical active pumping system is connected to the digital controller to circulate water within the solar heat exchanger. The electric active pump can be connected to a solar photovoltaic (electric) panel for reliable and uninterrupted heat/hot water delivery.

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.

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.

An external concentrator is disclosed for use in concentrating reflected solar radiation (e.g., beams or rays) onto a heat collection element (HCE) located at a focal point of a parabolic mirror. The external concentrator includes at least first and second elongated ribs that are adapted to extend radially outward from the outside surface of an HCE and along a linear length (e.g., a portion or all) of the HCE to redirect stray/spilled light into the absorber tube of the HCE. The radial extension of the ribs above the outside surface of the HCE allows a reflective surface of the rib to redirect stray reflected beams/rays that would otherwise bypass the HCE back onto the HCE.

The present invention discloses a pump-type autoclave system and a providing method for steam and pressure thereof, wherein the pump-type autoclave system comprises an autoclave, a steam providing device and a compressor, said steam providing device comprises a water storage container and a heating device used for heating said water storage container, said water storage container, the compressor and the autoclave are connected through a pipeline to form a closed loop, an inlet of the compressor is connected with a steam output port of the water storage container, an outlet of the compressor is connected to a steam input port of the autoclave, and a condensate water drain outlet of the autoclave is connected to the water storage container. The present invention uses the compressor to depressurize an intermediate-low temperature water source to obtain steam, and the steam is pumped into the autoclave and condensed to release heat to obtain corresponding temperature and pressure. Since the present invention fully utilizes a great amount of low-cost intermediate-low temperature heat sources obtained from natural, industrial or living waste heat to provide needed high temperature, steam and pressure to the autoclave system, the energy is saved.

A multi-fuel microgrid class generator system includes a heat regenerative steam engine that provides a versatile power source having a clean burn using liquid fuel or biomass for generating electricity. The generator system is also capable of using wind energy and/or solar energy that is converted to heat and stored in a thermal storage unit using a heat exchange medium, such as carbon/graphite. The heat regenerative steam engine uses these various power sources to generate up to 1 megawatt of clean and cost-effective electricity.