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 hybrid solar system including a hybrid solar collector using non-imaging optics and photovoltaic components and a heat transfer and storage system in thermal communication with the hybrid solar collector, the heat transfer and storage system using particle laden gas as thermal media to simultaneously generate and store electricity and high temperature dispatchable heat.

A light-concentrating lens assembly for a solar energy system, the assembly comprising a primary off-axis quarter-section parabolic reflector for reflecting incident light, a secondary off-axis quarter-section parabolic reflector for receiving light reflected from the primary off-axis quarter-section parabolic reflector, a compound paraboloid concentrator (CPC) for receiving light reflected from the secondary off-axis quarter-section parabolic reflector and a housing for holding the primary and secondary off-axis parabolic reflectors as well as the CPC.

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 linear Fresnel light concentrating device with high multiplying power, including a reflector field and a receiving unit, where the reflector field includes a plurality of arrays of one-dimensional linear convergence reflector strips; the linear receiving unit is arranged parallel to the reflector strips, and is provided with a secondary optical light concentrating unit inside, the height value of the receiving unit exceeds half of the width value of the reflector field, so as to obtain a relatively high primary convergence light concentrating multiplying power and secondary convergence light concentrating multiplying power, thereby realizing a high total convergence light concentrating multiplying power. High multiplying power light concentration in low cost can be achieved, while the severe problem of low light concentration efficiency caused by extinction, tolerance rate and shading rate and the problem of inconvenience in repair and maintenance of the device are solved.

The present invention is a solar concentrator composed of a generally V-shaped trough of reflective Fresnel steps. The Fresnel reflective steps concentrate the sunlight entering the mouth of the V-shaped trough and parallel to its central axis into a central focal area. By disposing a solar energy receiving element at the central focal area of sunlight concentration a preferred embodiment as a concentrating solar energy collector is realized. Various types of solar energy receiving structures are shown that serve to convert the concentrated sunlight into other forms of useful energy to realize the preferred embodiment as a concentrating solar energy collector.

A solar thermal collecting system, including at least one solar thermal collector and a pressure-adjusting module, is provided. The solar thermal collector includes a container, a light-transmissive cover that seals the container, and a plurality of solar thermal collecting pipes. The solar thermal collecting pipes are installed in the container, so as to allow a heat transfer material to flow therein. The outer surfaces of the solar thermal collecting pipes are correspondingly deposited with solar selective coatings for absorbing solar radiation energy, transforming the radiation energy into thermal energy, and transmitting thermal energy to the heat transfer material flowing in the solar thermal collecting pipes. The pressure-adjusting module controls the heat loss rate of the solar thermal collector by adjusting the air pressure inside the solar thermal collector and controlling the direction of air circulation to flow in or out of the solar thermal collector.

A portable solar concentrator includes a stand, a plurality of inner panels supported by the stand, and a plurality of outer panels attached to the inner panels. The inner panels have a reflective surface, and are configured to direct solar energy at a target. The outer panels have a reflective surface and can be configured in an active position to direct solar energy at the target, and can be configured in an inactive position to direct solar energy away from the target.

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.

Methods and apparatuses to increase a speed of airflow through a heat exchanger are described. An optoelectronic device comprising a heat exchanger is coupled to an airflow accelerator. The airflow accelerator comprises a surface to guide the airflow towards the heat exchanger. An optical element is coupled to concentrate light onto the optoelectronic device. The size of the surface, position of the airflow accelerator relative to the heat exchanger, or both can determine increase in speed of the airflow. A photovoltaic (PV) system comprises rows of receivers; rows of optical elements to concentrate light onto the receivers, and rows of airflow accelerators coupled to the receivers to increase the speed of airflow through heat exchangers. The airflow can be deflected by an airflow accelerator towards a heat exchanger. A wind load can be reduced by the airflow accelerator.