An external solar receiver for a tower solar concentration thermodynamic plant and a field of heliostats includes a plurality of panels wherein each panel with heat exchanger tubes is connected to an interior support element, with an axis substantially perpendicular to the panel, the interior support element being furthermore connected in a rotary manner to a support element belonging to the internal structure by means of at least two parallel, substantially horizontal connecting rods. The connecting rods are each articulated at a first end on the interior support element and at a second end on the support element, respectively, so that under the effect of thermal expansion or contraction of the panels with heat exchangers, each of the panels moves substantially parallel to itself and without deformation of the surface thereof, and in such a way that the polygonal or circular cross-section of the receiver undergoes a homothetic transformation.

A solar receiver system includes a panel mounted to a multiple of standoffs such that the panel is spaced away from the support structure to provide convective cooling.

A solar concentrator assembly includes a tripod, a base, a reflective dish, a receptacle, and a thermoelectric module or a heat transfer module. The tripod includes legs and a top tripod connector coupled to top portions thereof. The base includes a rod coupled to the tripod; a bottom support structure coupled to the rod; a top support structure coupled to the bottom support structure; an extension coupled to the bottom support structure and the top support structure; and a cap with recesses mounted to the top support structure. The reflective dish includes support rods received within the recesses; a pliable material forms panels, wherein the support rods are inserted into seams between the panels; and a reflective material disposed on the pliable material. The receptacle is connected to the base and disposed within the reflective dish. The thermoelectric module or the heat transfer module is partially disposed within the receptacle.

A converter of kinetic energy from a jet formed by a heat transfer fluid and a gas at high temperature, includes: at least one injector of the jet from at least one source of heat transfer fluid and of high-temperature gas, an impulse wheel mounted rotating secured to a shaft extending along an axis substantially perpendicularly to the injector and including a plurality of asymmetric blades, a tank surrounding said impulse wheel and at least one deflector extending underneath the blades.

A solar boiler 300 includes first and second primary receiver panels 500, 600 spaced apart by a gap 700. Each panel 500, 600 include a plurality of primary boiler tubes 510, 610 for receiving solar flux. The boiler 300 includes at least one secondary receiver arrangement 800 disposed across the gap 700 for receiving solar flux incident thereacross. The arrangement 800 includes at least one secondary boiler tube 810, and at least one support member 820 supported thereto. The arrangement 800 is configured relative to the primary panels 500, 600 such that endmost primary boiler tubes 510a, 610a are supported over the support member 820 in spaced relation S to the secondary boiler tube 810 for enabling transverse and lateral thermal expansion of the tubes 510, 610, 810 without bending out. Further, a panel joining attachment 900 is provided for attaching the panels 500, 600 and the arrangement 800.

A hybrid receiver-combustor (100) for capturing heat energy from a solar source and a fuel source. The hybrid receiver-combustor (100) includes a vessel (110) for acting both as a combustion furnace and as a solar receiver, and a plurality of burners (180) for combusting an oxidant stream, such as an air stream, and a fuel stream. The vessel (110) includes a casing (120) defining a cavity (125) having an aperture (130) for receiving the concentrated solar radiation from the solar source. The cavity (125) provides a chamber defining a zone (126) which can function as a combustion zone for production of heat energy through a combustion process using the fuel and into which concentrated solar radiation can be received from the solar source through the aperture (130). A heat energy absorber (190) configured as a heat exchanger is provided to receive heat energy from concentrated solar radiation entering the cavity (125) through the aperture (130) and from combustion within the cavity. A fluidic seal system (135) is associated with the aperture (130) and is operable to establish a fluidic seal to restrict fluid flow through the aperture (130) during the combustion process. The fluidic seal comprises exhaust gas from the combustion process within the cavity (125).

Broadband reflectors include a UV-reflective multilayer optical film and a VIS/IR-reflective layer. In various embodiments, the VIS/IR reflective layer may be a reflective metal layer or a multilayer optical film. Concentrated solar power systems and methods of harnessing solar energy using the broadband reflectors and optionally comprising a celestial tracking mechanism are also disclosed.

The invention relates to a solar power concentrator (CSP) formed by a series of long flat (Fresnel-type) mirrors oriented in a north-south direction, each mirror having a single east-west axis of rotation, tracking the height of the sun. Together the mirrors reflect the light throughout the day towards a single cylindrical-parabolic mirror which concentrates the solar radiation onto a small area close to the focal line of the parabola on which an absorber is located that heats fluids and/or generates electricity.

A solar heat boiler is provided which is capable of avoiding damage to heat transfer tubes without increasing facility cost and construction cost. The solar heat boiler includes: a low-temperature heating device by which water supplied from a water supply pump is heated by heat of sunlight; a steam-water separation device by which two-phase fluid of water and steam generated in the low-temperature heating device is separated into water and steam; a high-temperature heating device by which the steam separated by the steam-water separation device is heated by the heat of sunlight; and a circulation pump by which the water separated by the steam-water separation device is supplied to the low-temperature heating device.

The molten salt solar tower system 100 is provided for controlling molten salt temperature in a solar receiver 130 for effective operation of the system 100 while without degrading physical properties of molten salt. The system 100 includes two circuits, first 140 and second 150. The first circuit 140 is configured to supply relatively cold molten salt in the solar receiver 130 for heating, and the second circuit 150 is configured to supply a predetermined amount of the relatively cold molten salt in the first circuit 140, as and when the temperature of the relatively hot molten salt circulating through the solar receiver 130 exceeds a predetermined set temperature value thereof.