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.

Embodiments disclosed herein are directed to a rapidly deploying transportable power system for generating power. The rapidly deploying transportable power system embodiment disclosed herein can have a plurality of frame members containing a plurality of solar panels. Any embodiments of the rapidly deploying transportable power system can also have a transport enclosure configured to support the plurality of frame members and a rail system coupleable with the transport enclosure, the rail system being configured to support the plurality of frame members outside of the transport enclosure. In any embodiments, the plurality of frame members can be positionable within the transport enclosure with one frame member positionable above another frame member. Furthermore, the plurality of frame members can be movable along the rail system to positions outside of the transport enclosure along the track system.

An optical mining apparatus comprising: a light weight solar reflector; optics for controlling the delivery of concentrated sun light onto the surface of a target; and a temperature controlled gas enclosure that contains the target; wherein said solar reflector is oriented to reflect sun light onto said optics.

A foldable parabolic solar collector includes a first panel having a semi-parabolic reflective inner surface, a central tube to which the first panel is fixed, and a second panel having a semi-parabolic reflective inner surface. The second panel is pivotably mounted to the central tube with the reflective inner surface of the second panel facing the reflective inner surface of the first panel. A receiver tube carries a heat transfer fluid. A tracking motor rotates the central tube. A torque sensor lies in between the tracking motor and the central tube and is configured to measure torque between the tracking motor and the central tube. A servomotor pivots the second panel about the central tube between an open position and a closed position when it is determined by a controller that the torque between the tracking motor and the central tube exceeds a predetermined torque threshold.

A collapsible reflector includes a plurality of reflective blades which are rotatably arranged around a common axis. Each blade has a leading edge and a trailing edge. The blades are substantially flat and stacked above one another between a top blade and a bottom blade when the reflector is in a retracted position. The blades rotate and elastically bend to form an approximately dish-shaped arrangement when in an extended position. The leading edge of each blade is arranged below the trailing edge of the adjacent blade when the reflector is in the extended position. This includes the leading edge of the top blade, which is below the trailing edge of the bottom blade when the reflector is in the extended position. One blade may be fixedly connected to a central hub, enabling quick setup and disassembly of the reflector.

An optimally-angleable solar powered air system is a portable indoor solar heating unit that may stand upright or may be mounted to a door or window. The optimally-angleable solar powered air system has a frame having a solar panel mounted to a first side and a fan mounted to a second side of the frame. In use, the frame may stand inside a room at an angle facing the sun via a removable handle such that the solar panel is able to capture solar energy. The system may then convert solar energy into usable power to power the fan. The second side of the frame includes an air deflector which may direct airflow outwardly from the second side of the frame into the room.

This invention relates to a portable or fixed solar powered heating ventilation air conditioner (HVAC) system. The disclosed invention consists of the following major components. 1) Solar Hot Water Tank/Storage Tank, 2) Solar Generator, 3) Solar HVAC Heat Exchanger Unit, 4) Solar Grill, 5) Wireless Network Energy Monitoring System and 6) Supervisor Control and Data Acquisition (SCADA) system. Also included is a list of appliances that the HVAC system can be configured to function as: a) refrigerator, b) air purifier/fan, c) pressure cooker, d) drink dispenser, and e) pressurized hot water supply. The HVAC system and above listed appliances is designed to be used in homes, businesses, camping, military, hospitals, FEMA and in developing countries with very little electrical or plumbing infrastructure. The HVAC is capable of supplying all the above mention functions while being powered solely on solar power, solar hot water/fluid or geothermal and a chilled water source, therefore creating a NetZero Energy Machine that required no power from a utility grid when properly sized.

A solar module comprising at least a plurality of lamellar solar panels, which are mounted pivotably, about a common axis, on an elongate support and can be and which can be moved between a first position, in which they are disposed on top of each other substantially congruently and parallel to the support, and a second position, in which they lie substantially next to each other in a fanned out manner about the aforementioned axis, wherein the support can be pivoted out of a housing, which accommodates the support together with the solar panels in the first position of the panels, characterized in that the solar module comprises two supports of the aforementioned type equipped with solar panels in the manner described, wherein the two supports are pivotably hinged at the diametrical longitudinal ends of an elongate base support, which is mounted rotatably, about an approximately vertical axis, in the housing.

A support basement adapted to support fixedly mounted or extensible and collapsible photovoltaic panels that comprises a plurality of triangular arrays (53) interconnected by tubular members (21) and constructed with links (54, 55) and radially extending tubular members (1). Profile members (24, 30, 84) extending longitudinally along each photovoltaic panel connect the profile frames (37, 39, 69) of the photovoltaic panels to underlying triangular arrays (53) by means of connector assemblies comprising bolts (10) and nuts (12). Adjustable connector assemblies comprising bolts (27) and nuts (29a, 29b) are used to connect bottom links (55) of triangular arrays (53) with profile members (41) based onto ground pillars (51). A retraction mechanism of the photovoltaic panels offering protection from adverse weather conditions and during night periods comprises sequentially connected X-configured assemblies with an elongate screw (72) rotatable within nuts (71) at the ends of a terminal X-configured assembly proximally to the protective housing (86).

A solar thermal collector adapted to be assembled from a flat pack configuration, comprising a conduit (6) configured to carry fluid and to absorb radiation, a base (1) above which the conduit (6) is mounted and a plurality of panels configured to interconnect with the base (1) to produce a housing (8) for the conduit (6).