A deformable mirror with variable curvature including: a plate having a reflective face and opposite hidden face and whose shape has a center (C) and radiuses (r), and at least one actuator intended to exert a force on the hidden face in order to deform the plate. The plate comprises a plurality of primary and secondary portions. The secondary portions being interposed between the primary portions, each of the primary portions extending locally substantially along and on either side of a respective radius (r) among said radiuses (r), and having a stiffness different from the adjacent secondary portions. The deformable mirror is intended to the introduction or the correction of an optical aberration in a light beam.

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 solar thermal collector comprises a solar heat collector tube and a Fresnel reflector film configured to focus incident solar light on the solar heat collector tube. A solar thermal collector assembly, a solar thermal collector module, a cooling apparatus, and a solar cooker comprising the solar thermal collector are also provided. Also provided is a use of a Fresnel reflector film for collecting solar thermal energy.

A deformable mirror with variable curvature including: a plate having a reflective face and opposite hidden face and whose shape has a center (C) and radiuses (r), and at least one actuator intended to exert a force on the hidden face in order to deform the plate. The plate comprises a plurality of primary and secondary portions. The secondary portions being interposed between the primary portions, each of the primary portions extending locally substantially along and on either side of a respective radius (r) among said radiuses (r), and having a stiffness different from the adjacent secondary portions. The deformable mirror is intended to the introduction or the correction of an optical aberration in a light beam.

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 solar collector unit is adapted for reflecting light onto a receiver, and comprises a reflector element, and a support structure supporting the reflector element. The reflector element is flexible and comprises a reflective surface and a substrate having a predefined length and width. The support structure comprises a predefined number of profiles per length unit connected to the reflector element at a distance from each other to provide a predefined shape of the solar collector unit. The number of profiles per length of substrate may be varied and lies in the interval 3 to 12, preferably 4 to 10, most preferred 5 to 8 per 2000 mm of length of the substrate.

An extremely low cost solar concentrator made of membranes or films is inflated into a Compound Parabolic Concentrator (CPC) a non-image concentrator. The portion of the inflatable concentrator, which is shaped into a CPC concentrator, is formed with reflective membranes or films, and the portions of the inflatable concentrator on the top of CPC and on the bottom of the concentrator are made of clear membranes or films. The incident light including parallel rays of light and diffuse light, as long as falling into the half acceptance angle of the CPC, will be concentrated to the bottom exit aperture of the CPC. Therefore, this type concentrator reduces the requirement to the accuracy of tracking for concentration. In addition, this type of concentrator demonstrates more tolerance to shape distortion for concentration than imaging system.

A method of utilizing solar radiation as a solar radiation source moves throughout the day includes providing a deformable surface having a pair of opposing edges and supporting the opposing edges of the deformable surface with a pair of flexible members. The method also includes imparting a curvature on the deformable surface to cause incident rays to be coincident with the normal axis of the deformable surface. The method further includes changing the curvature of the deformable surface as the solar radiation source moves throughout the day, such that the curvature corresponds to a location of the solar radiation source.

Solar energy concentration systems and methods that includes a curved lower solar reflective dish, and a smaller curved solar concentrator located on a focal line above the dish. The dish reflects input light rays onto the smaller curved solar concentrator. Moveable supports adjusts the shape of the deformable solar concentrator mounted directly below the concentrator to receive concentrated light rays reflected from the concentrator. A controller for storing and executing a set of instruction controls the shape of the concentrator to focus the reflected concentrated light rays onto a focal collector. A mirror point list adjusts the shape of the concentrator based on a sun angle.

A rigid deformable reflector for heating a target, the rigid deformable reflector having a reflective surface capable of being rigidly deformed, a backing surface capable of supporting the reflective surface, and a concave shape. A method of deforming a rigid deformable reflector utilizing a deforming mechanism, wherein the rigid deformable reflector has a reflective surface and the deforming mechanism has a base and an actuator, the method having the steps of: placing a rigid deformable reflector onto the deforming mechanism, and activating the actuator thereby causing a first force to be applied to the rigid deformable reflector and deforming the shape of the rigid deformable reflector beyond its elastic limit.