A growth chamber for improving growing conditions of a growing plant which include a growing grape vine, grape vine replant or other agricultural crop plant. The growth chamber includes a solar concentrator for collecting and concentrating solar energy, a light transmitter in optical communication with the solar concentrator, for directing the collected solar energy toward the growing plant, an inner wall comprising a perimeter positioned between the solar concentrator and the growing grape vine or grape vine replant, the inner wall further comprising a reflective inner surface for directing collected solar energy toward the growing plant, and a protective inner surface configured for placement around the growing plant, the protective inner surface defining a protected zone surrounding the growing plant, the protective inner surface extending downward from the light transmitter and comprising a rigid outer wall for protecting the protected zone from one or more growth limiting factors selected from the group consisting of: wind damage; heat damage; cold damage; frost damage; herbicide damage; and animal damage; and/or for reducing evapo-transpiration by growing plant positioned in the protected zone.

A growth chamber for improving growing conditions of a growing plant which include a growing grape vine, grape vine replant or other agricultural crop plant. The growth chamber includes a solar concentrator for collecting and concentrating solar energy, a light transmitter in optical communication with the solar concentrator, for directing the collected solar energy toward the growing plant, an inner wall comprising a perimeter positioned between the solar concentrator and the growing grape vine or grape vine replant, the inner wall further comprising a reflective inner surface for directing collected solar energy toward the growing plant, and a protective inner surface configured for placement around the growing plant, the protective inner surface defining a protected zone surrounding the growing plant, the protective inner surface extending downward from the light transmitter and comprising a rigid outer wall for protecting the protected zone from one or more growth limiting factors selected from the group consisting of: wind damage; heat damage; cold damage; frost damage; herbicide damage; and animal damage; and/or for reducing evapo-transpiration by growing plant positioned in the protected zone.

The disclosed invention relates to an optical element preferably utilized for concentrating solar heat radiation, and more particularly, high-concentration, reflective concentrators that are constructed from discrete conical concentrators utilizing flexible high-reflectance layers that are produced by roll-to-roll manufacturing. In its first preferred embodiment, the disclosed optical element preferably comprises a quasi-parabolic, multi-frustum, concentration optic.

The invention relates to a solar concentrator comprising a solid body consisting of a transparent material that has a light coupling surface and a light decoupling surface, the solid body having a light guide part that tapers towards the light decoupling surface, being located between the light coupling surface and the light decoupling surface and being delimited by a light guide surface between the light coupling surface and the light decoupling surface, the light guide surface merging into the light decoupling surface with a constant first derivation. The invention also relates to a method for the production of a solar concentrator, wherein the transparent material is precision-molded between the molds.

A light guide apparatus that can redirect light impinging on the apparatus over a wide range of incident angles and can concentrate light without using a tracking system and methods for fabrication.

A heat receiver, a reactor, and a heater utilize the heat of concentrated solar light for thermal decomposition and/or chemical reaction of coals, etc. The heat receiver includes: a side portion forming a substantially cylindrical side surface; a substantially circular bottom portion connected to the lower edge of the side portion; and a ceiling connected to the upper edge of the side portion. A substantially circular aperture is formed in the center of the ceiling. The heat receiver has a substantially cylindrical cavity and the opening portion is open. When the cavity has a diameter of D and a length of L, and the aperture has a diameter of d, d=D/2 or less and L=2D or more. Concentrated solar light entering the heat receiver is to be contained in the heat receiver to effectively utilize the solar light.

A disc-type concentrator comprises a disc rack vertical post, a disc rack, a rotating shaft, a rotating reflection mirror, a power driving device, and a control system. The rotating shaft is arranged on the disc rack and rotatably connected with the disc rack. The rotating reflection mirror is arranged on a side of the rotating shaft and fixedly connected with the rotating shaft. The power driving device is arranged on the disc rack or on the back surface of the rotating reflection mirror and driving the rotating reflection mirror to rotate. The control system is connected with the power driving device and controlling the working state of the power driving device.

A light guide apparatus that can redirect light impinging on the apparatus over a wide range of incident angles and can concentrate light without using a tracking system and methods for fabrication.

The invention relates to apparatus utilized for concentrating and converting solar energy. In a first preferred embodiment, the disclosed solar concentrator is utilized in conjunction with a solar-energy conversion device located within the volume of the concentrator, and, in the first preferred embodiment, is a solar-thermal receiver module utilizing absorbing media wherein absorption occurs both in a liquid media and by means of a photovoltaic array.

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.