A solar thermal lamp used for heating water inside a tank. The thermal lamp includes a transparent glass bulb with a threaded male coupling for attaching to a female coupling in the tank. The lamp also includes a heat tube with an enlarged water heating condenser. The condenser is received inside the tank. The heat tube can include a copper coil, copper fins, a glass coil, a copper lamp, a glass lamp, and the like for receiving solar energy and conducting the heat to the heating condenser for heating the water inside the tank. Also, the invention can be in the form of a solar thermal globe. The solar globe is self-contained and includes a water tank. Another embodiment of the globe tracks with the daily movement of the sun and change with seasons.

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.

The solar evaporator is comprised of a parabolic dish structure and the evaporator located just outside of the focal point. The refrigerant, coming from the heat pump, circulates through the evaporator. After having been heated up by the concentrated solar heat, the refrigerant is routed to the heat pump which compresses the refrigerant so as to extract the maximum amount of heat collected. The goal is to continuously maximize the temperature differential at the receiving coil by keeping the refrigerant at the lowest temperature possible in order to maximize heat gains at the evaporator. Multiple parabolic dishes can work together wherein they are connected in parallel to the header. A sun tracking mechanism ensures that the dishes are always pointing towards the sun. The extract heat can be used for multiple purposes.

The invention provides a solar collector arrangement which includes a reflector (12), a collector (14) and a support arrangement (16). The support arrangement is configured to permit relative displacement of the reflector and the collector between an operative condition, in which the collector is positioned to receive reflected radiation from the reflector, and a stowed condition. In the stowed condition, the spacing between the reflector and the collector is less than in the operative condition and the wind loading on the solar collector arrangement is less than in the operative condition. The invention extends to a solar assembly which includes a mobile platform on which the solar collector arrangement is mounted.

The present invention discloses a receiver for a concentrated thermal system. The thermal system includes a first heat exchange element helically coiled to receive a solar radiation from a first reflector and the second heat exchange element. Further, the first heat exchange element includes a first end and a second end to enable circulation of a heat exchange fluid in the first heat exchange element. The second heat exchange element being a helically coiled element is extending from and fluidically connected to the first end of the first heat exchange element. Further, the second heat exchange element is configured to receive absorb a part of solar radiation to preheat the heat exchange fluid flowing therein.