Abstract: A solar collector apparatus includes a parabolic mirror configured to direct solar energy through a double convex lens and towards a linear set of secondary mirrors, each of the secondary mirrors positioned to direct the solar energy towards a solar collection target. The subsequent diversion achieved by the solar collector apparatus allows collection of solar energy several times denser than natural sunlight, and can be captured using a substantially compact system.

Abstract: A solar thermal collector is provided. The collector comprises a housing defining an inlet, and an outlet for a heat transfer fluid, said housing comprising a window to allow sunlight to pass there through; a heat transfer core disposed within the interior of the housing said housing designed to be heated by exposure to said sunlight; and a heat absorbing component in proximity to the heat transfer core, said heat absorbing component designed to at least partially absorb heat losses from the heat transfer core; wherein a positioning the components within the housing defines at least one path for the heat transfer fluid for preheating of the heat transfer fluid prior to said heat transfer fluid passing through the heat transfer core.

Abstract: The present invention is a method and apparatus for periodic orientation of arrays of mechanically linked heliostats positioned on rotatable shafts such that incident sunlight is focused on a stationary object. In each altitudinal orientation a minuscule predefined push is given by an actuator and the time interval between each altitudinal orientation is 2×(T2?T1)/n. For azimuthal reorientation, the magnitude of rotation of rotatable shafts is determined by (Y×Sin ?)/2 degrees, and as per the position of the sun in the sky, the determined magnitude in degrees is added/subtracted to form angle ??. The length ‘C’ of the linear actuator with its arm at angle ? can be extended/retracted to length ‘C1’ such that angle ?? is achieved, wherein an arm affixed with each rotatable shaft and coupled with a linear actuator provides the ability to rotate the rotatable shaft in clockwise or anticlockwise direction.

Abstract: A positioning system is attached to radiation collection device such as a solar oven. The positioning system is attached to an outside of a building structure, allowing the collection device to be positioned in a plurality of locations. At least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

Abstract: Adherence to flux or resultant measurable parameter limits, ranges, or patterns can be achieved by directing heliostat mounted mirrors to focus on aiming points designated on the surface of a solar receiver. Different heliostats can be directed to different aiming points, and a heliostat can be directed to different aiming points at different times. The cumulative flux distribution resulting from directing a plurality of heliostats to any aiming point on a receiver surface can be predicted by using statistical methods to calculate the expected beam projection for each individual heliostat or alternatively for a group of heliostats. Control of the heliostats in a solar power system can include designating aiming points on a receiver from time to time and assigning heliostats to aiming points from time to time in accordance with an optimization goal.

Abstract: A solar energy collector system includes a base, and a parabolic trough collector carried by the base for reflecting sunlight to a longitudinal focal line. The parabolic trough collector includes a center section horizontally positioned with respect to ground, and opposing end sections adjacent the center section. Each end section is angled towards the ground. A conduit is positioned along the longitudinal focal line to receive the reflected sunlight. The conduit circulates a heat transfer liquid therethrough to be heated by the reflected sunlight.

Abstract: Solar receiver having a receiver funnel, a solar absorber, and an absorber rotation drive mechanism. The receiver funnel has a funnel entrance and a funnel exit. The solar absorber may have a spherical shape and has an absorber rotation axis. The solar absorber is rotatably positioned in the funnel exit. The solar absorber has an internal absorber fluid chamber, an absorber fluid intake and an absorber fluid outlet. The absorber rotation drive mechanism provides for rotating the solar absorber about the absorber rotation axis.

Abstract: A solar furnace for heating a target having a heliostat with a reflective surface having a reflective portion, a surface altering mechanism capable of altering the shape of the reflective portion, and a target having a target area, the reflective surface capable of reflecting radiant energy toward a target.

Abstract: A method and a control system for a hot water supply system, wherein the hot water supply system includes at least one boiler having a heating fluid input pipe line, the control system comprising: a motorized valve; installed upon the heating fluid input pipe line; a first thermistor installed upon the heating fluid input pipe line; a second thermistor installed within the boiler; a motor mechanically connected to the motorized valve; and a controller, wherein the controller is adapted for opening and closing the motorized valve according to temperature difference between a temperature measurement by the first thermistor and a temperature measurement by the second thermistor, wherein the controller is electrically connected to the motor, to the first thermistor, and to the second thermistor.

Abstract: A solar array is provided with a first heat-transfer fluid transporting line (parabolic trough loop) for transporting a first heat transfer fluid, and at least one further heat-transfer fluid transporting line for transporting a further heat transfer fluid arranged to receive solar energy from, for example, a parabolic-trough solar array. The first heat-transfer fluid transporting line and the further heat-transfer fluid transporting line are coupled to form an overall heat-transfer fluid transporting line (for example, as a parabolic trough loop). The first heat-transfer fluid transporting line is connected to at least one main line pump for pumping the first heat transfer fluid through the heat-transfer-fluid transporting line and the further heat-transfer fluid transporting line is connected to at least one further main line pump for pumping the further heat transfer fluid through the further heat-transfer-fluid transporting line. The first and further heat-transfer fluids may be the same fluid.

Abstract: Method and air conditioning system for the conversion of energy, particularly solar energy; the method featuring the steps of heating a first end (E1) of a base body (2) made of a porous material by way of electromagnetic radiation that impacts on an element of absorption (3), which is thermally coupled to the base body (2) at a first end (E1); supplying an evaporative fluid to the body base (2) at a second end (E2) as opposed to the first end (E1) so that the evaporative fluid penetrates inside the base body (2) and spreads inside the body base (2) by way of capillary action; and circulating a heat exchange fluid in contact with the base body (2) at the second end (E2).

Abstract: A multiplatform heating ventilation and air conditioning control system configured to maximize energy efficiency in maintaining desired conditions within an area through beneficial use of natural energy sources. In some embodiments, the multiplatform heating ventilation and air conditioning control system can include sensors and a control system. In some embodiments, the sensors can detect conditions inside and outside of the controlled area to determine the most efficient method of maintaining desired conditions.

Abstract: Systems and methods for selectively producing steam from solar collectors and heaters are disclosed. A method in accordance with a particular embodiment includes directing a flow of water to a solar collector, directing the flow of water to a gas-fired heater, and, as a result of heating the flow of water at the solar collector and the gas-fired heater, forming steam from the flow of water. The method further includes changing a sequence by which at least a portion of the flow passes through the solar collector and the gas-fired heater.

Abstract: A solar energy receiver includes a plurality of solar receiver elements. Each solar receiver element includes a substantially solid core configured to absorb solar radiation and to store the solar radiation as heat. The core includes a base surface and a plurality of absorption surfaces. The receiver further includes at least one fluid passageway defined within the core adjacent at least one absorption surface of the plurality of absorption surfaces, wherein the at least one fluid passageway is configured to channel a working fluid therethrough for absorbing heat stored in the core.

Abstract: The present invention relates to a process for solar thermal energy production in which switching between daytime and nighttime operation is possible, and also to a device for solar thermal energy production. The present invention relates, in particular, to the use of the process and of the device for producing drinking water or service water.

Abstract: A solar concentrating system includes a heliostat having an actuator that adjusts a reflecting direction of a mirror reflector. An anemometer measures wind direction and wind speed. A controller generates and outputs a target angle command to the actuator in order to control the actuator. The controller generates the target angle command based on the current position of the sun and on the wind direction and the wind speed measured by the anemometer.

Abstract: A concentrator having a reflective surface (1) and a pair of flexible members (2) supporting the deformable reflective surface so as to define its shape. A mechanism (3) is movably mounted to a vertical support and has one end of each of the flexible members (2) attached thereto. A controller drives rotation-changing linkage and tension-varying linkage so as to move the mechanism (3) to impart a toric shaped curvature on the reflective surface (1). This toric shaped curvature minimizes astigmatic aberration due to obliquely incident radiation and changes as the solar point moves throughout the day.

Abstract: Metallic composite phase-change materials and methods of using are disclosed. In some embodiments, a thermal energy storage module is provide that included one or more phase change alloys having a variable phase transition temperature between about 400° C. and about 1200° C. and having a latent heat of more than about 200 kJ/kg.

Abstract: An energy supplying device for energy collection, energy transfer, energy release, cooling, and storing energy, is described. The device has an elongated cavity is produced by extrusion of a profile. The cavity provides space for a medium to circulate and is enclosed by a wall, floor or roof formation. This formation constitutes at least part of an actively supporting structure for direct or indirect mechanical support of loads, while at the same time forming at least one part of a structural element, for example, a house roof, a wall, a board, a bridge, a pier, a road, a pavement, a terrace or balcony and may be an I-, L-, O-, T-, U-, V-, X-, Y- or Z-beam.

Abstract: A modular thermal panel can include a heat exchanger having connected top and bottom plates with channels formed there between for receiving a heat exchange fluid. An architectural tile (e.g., a paver, stone, acoustic tile, or any other architectural element) can rest on the top of the modular thermal panel, while an insulator panel is positioned below the modular thermal panel. The heat exchanger can transfer heat between the architectural tile and the heat exchange fluid to either cool or heat the architectural panel. Additional implementations include heat transfer systems including such modular thermal panels, and methods of collecting and utilizing thermal energy using such modular thermal panels.

Abstract: The present invention relates to a solar system for providing volumetric energy reproducing the effect of a combustion flame for a high-temperature industrial process, characterised in that it comprises: a solar receiver exposed to concentrated solar radiation, in which heat transfer fluid (liquid or gas) is brought to high temperature; at least one high-temperature chamber in which said high-temperature industrial process is performed; injection means of the heat transfer fluid in the form of a gas jet reproducing a combustion flame in the at least one high-temperature chamber. The present invention also relates to a process for providing volumetric energy reproducing the effect of a combustion flame for this purpose.

Abstract: In order to provide a method of operating a solar thermal power plant, in which a heat transfer medium is evaporated endothermally by solar radiation in an evaporator section, wherein the evaporator section comprises a plurality of evaporator branches, among which the heat transfer medium is distributed, in which method non-uniform radiation conditions of the evaporator section may be effectively taken into consideration, it is provided that the mass flow distribution at the evaporator section is controlled, wherein the mass flows are adjusted individually at all or a majority of the evaporator branches and a controlled variable is a variable characterizing a spatial energy rise in a respective evaporator branch in a region of the evaporator branch where the heat transfer medium has not yet evaporated.

Abstract: Polymeric sheets suitable for use as solar concentrators in solar thermal devices are provided. Also provided are solar thermal devices incorporating the polymeric sheets. The polymeric sheets have two oppositely facing surfaces. A first pattern is defined in the first surface and a second pattern is defined in the second surface. The first pattern is designed to reduce the reflectance of light incident upon the first surface relative to the first surface in the absence of the first pattern and to channel incident light through the sheet onto the second surface. It does so by redirecting photons incident upon the first surface over a broad range of incident angles into transmittance angles that are more closely aligned with the surface normal of the polymeric sheet. The second pattern is designed to focus the photons transmitted to the second surface of the sheet onto a focal surface, such as a receptacle containing a heat-transfer medium.

Abstract: A method of generating steam for use in an industrial process is disclosed. The industrial process may for example be power generation or desalination. The method comprises: (a) pressurising a working fluid liquid comprising water to a first pressure; (b) heating the working fluid liquid to a temperature substantially equal to the saturation temperature of the working fluid liquid at the first pressure; and (c) flash evaporating the working fluid liquid to generate steam. The pressurised working fluid liquid is heated in step (b) by direct heating in a solar radiation absorption device. Also disclosed is an apparatus for generating steam for use in an industrial process.

Abstract: A solar absorber module is described. The module has a housing with a longitudinal axis with a first tapered housing section with a first, free end, and a second end with a reduced cross-sectional area compared to the first end, and with a second housing section adjoining the second end of the first housing section with a substantially constant cross-section over its length. The module also has a ceramic solar absorber element accommodated in the first end of the first housing section with a first surface that can be oriented toward the solar radiation with an axis of symmetry, and a second surface lying across from the first surface, wherein the solar absorber element has a large number of substantially straight channels connecting the first surface to the second surface. The solar absorber module is accommodated in the first end of the first housing section such that the axis of symmetry of the first surface is inclined relative to the longitudinal axis of the housing.

Abstract: A method for operating a directly heated, solar-thermal steam generator is provided. As per the method, a nominal value Ms for the supply water mass flow M is conducted to an apparatus for adjusting the supply water mass flow M wherein, at the adjustment of the nominal value Ms for the supply water mass flow M, account is taken of a correction value KT, by which the thermal effects of storage or withdrawal of thermal energy in an evaporator are corrected.

Abstract: A startup system for a solar boiler includes a main fluid circuit having a plurality of solar boiler panels for generating power from solar energy. An auxiliary fluid circuit is selectively connected in fluid communication with the main fluid circuit by a plurality of valves. An auxiliary boiler is operatively connected to the auxiliary fluid circuit. The valves connecting the auxiliary fluid circuit to the main fluid circuit are configured to be opened and closed to selectively place the auxiliary boiler in fluid communication with portions of the main fluid circuit to supply heat to the portions of the main fluid circuit in preparation to produce power from solar energy.

Abstract: The present invention discloses a hermitically sealed solar water heater system and operation method for generation of electricity from thermal power plant. Water storage tank (1) is hermitically sealed by diaphragm (13) to prevent feed water contamination. Solar energy based water heater (2) preheats feed water and raises water temperature close to the boiling point. The feed water heater by trapping the waste heat from the exhaust gases further heats the feed water and is pumped to the boiler and where it is converted to steam. The steam impinging on the turbine blades drives it and generates power from the generator. The steam condenses in the condenser and the water coming out of condenser is pumped to the overhead water tank and the process of power generation is continues uninterruptedly.

Abstract: A trough collector for solar energy, with multiple parallel troughs preferably being contained within a single unit. The collector does not use conventional azimuth tracking in order to keep the sun's rays directed toward the parabola's focus as the sun moves across the sky. Instead, the relative position between the collecting device (preferably a conductive tube containing a circulating working fluid) and the plane of symmetry for each collector is adjusted so that the collecting device remains within the focal zone of the collector as the sun traverses the sky.

Abstract: Disclosed is a method to create a stationary solar collector system composed of linked converging lenses, structured in a dome or cone shape. The solar energy is refracted and concentrated through the converging lenses, in which then, heat specific points on the conical helix receiver pipe to heat the flowing liquid.

Abstract: A receiver module for a solar power station receiver, including a metal structure and an absorber module, the metal structure defining a cavity extending along a longitudinal axis in a base of which the absorber module is housed. The cavity includes an aperture configured to be aligned towards at least one mirror of the solar power station, the aperture is edged by two side portions of the metal structure extending longitudinally on either side of the cavity. The receiver module also includes thermocouples positioned on each of the side portions relative to the longitudinal axis to detect a temperature difference between a reference temperature and two points of the metal structure that are opposite relative to the longitudinal axis.

Abstract: An apparatus includes a sample chamber constructed according to a design certified by the Department of Transportation for transporting fluids at a first pressure P1. A cylindrical sample compartment exists within the sample chamber. The sample compartment is designed to withstand the pressure P1. The cylindrical sample compartment has a cylindrical inner surface with a radius r and a height h. A hollow cylindrical sleeve is secured to the cylindrical inner surface of the sample compartment and has a wall of thickness t. The sample chamber is capable of transporting fluids at a second pressure P2. P2 is higher than P1.

Abstract: A dual hybrid heating apparatus, method of assembly and operation to pre-heat vaporizable fluid by free heat sources—waste heat from heat recovery units and insolation. The pre-heated vaporizable fluid is routed to where a parabolic dish solar concentrator vaporizes it to turn a blade of a turbine generator to generate electricity. Heat is extracted from the vapor to form condensate, but the vapor also heats the condensate before being cooled by heat exchange with fluid cooled by a cooling tower.

Abstract: The solar-powered distillation system is particularly adapted for small scale seawater distillation to produce fresh water. The system includes a single heat-absorbent evaporation panel having mutually opposed evaporation surfaces, the panel being contained within a single housing. Each side of the housing includes a lens panel. The lenses of each panel focus solar energy onto the respective surfaces of the evaporation panel. A mirror is positioned to each side of the housing to reflect solar energy onto the respective lens panels. Contaminated water enters the top of the housing to run down the surfaces of the evaporation panel. A fresh water collection pipe extends from the top of the housing to a collection tank. A scraper mechanism removes salt and/or other residue from the surfaces of the evaporation panel to allow the residue to be removed periodically from the bottom of the housing.

Abstract: A solar energy collection system comprises hollow radiation absorber(s) in an enclosure, each absorber for filling with working fluid, to absorb radiation impinging thereon and transform its energy into heat to thereby heat the fluid. The system comprises an inlet non-return valve upstream of each absorber, for allowing a flow of the fluid thereto; and an outlet valve downstream of each absorber for allowing a flow of the fluid out. The system comprises a measuring device for determining parameter(s) of the fluid within each absorber, which depends on the heat absorbed thereby; and a controller that controls operation of at least the outflow valve between its open state in which the fluid can flow freely out of the associated absorber, and its closed state in which the fluid filling the associated absorber is held therein for a period of time depending on a desired change of the parameter.

Abstract: An energy-generating transparent (EGT) structure is provided, in addition to a method for generating energy from light incident to an EGT structure. The EGT structure is made up of a window pane with an interior surface adjacent a reflective structure. The method accepts light incident to an exterior surface of the window pane, and transmits light in the visible spectrum through the window pane and reflective structure. However, light in the near-infrared (NIR) spectrum is reflected back from the reflective structure into the window pane, so that reflected NIR, spectrum light is supplied to an edge of the window pane. For example, reflected NIR spectrum light is supplied to the window pane edge if the light has an angle greater than or equal to an angle TIR occurring between the window pane exterior surface and air. This reflected NIR spectrum light can be converted to electrical or thermal energy.

Abstract: The disclosed invention relates to solar-thermal receiver tubes for heating high-temperature fluids such as molten salts and oils, such as those used in conjunction with trough reflectors or concentric concentrators. The disclosed invention utilizes fused silica receiver tube assemblies that provide optical absorption by way of optically-absorbing media that is imbedded within the thermal transfer fluid, preferably comprising inorganic “dyes” that comprise pulverized thin film coatings or dissolved materials that are specifically designed for maximizing optical absorption. Alternatively, the chemistry of the transfer fluid can be modified to increase optical absorption, or the optically absorbing media may comprise fine powders with density preferably similar to the thermal transfer fluid, such as fine graphite powder; or, in another preferred embodiment, absorbing means within the heat transfer fluid comprise a solid absorbing element disposed along the central axis of the receiver tube's interior.

Abstract: A method for operating an indirectly heated, solar-thermal steam generator and to an indirectly heated, solar-thermal steam generator are provided. A heat transfer medium is used in the solar-thermal steam generator. The supply water mass flow M is predictively controlled by a device for adjusting the supply water mass flow M. To this end, a nominal value Ms is fed to the device. A correction value KT, by which thermal storage effects of stored or withdrawn thermal energy are corrected is taken into account by the nominal value Ms.

Abstract: An overheat protection device (OPD) is implemented independently of the circulating system of a solar thermal collector and isolated from the environment. The system facilitates operation of a solar thermal collector at elevated internal temperatures (versus reducing or ceasing operation above a critical temperature). OPD includes a heat pipe filled with at least two fluids. In a non-heat conducting state, a temperature at an evaporator portion of the heat pipe is below a transition temperature and the dual-fluid includes at least one fluid in a liquid state and at least one fluid in a gaseous state. When the temperature at the evaporator is above the pre-defined transition temperature the OPD undergoes an abrupt transition to a heat conducting state, whereby the dual-fluid transfers heat from the evaporator area to the condenser area, thus transitioning from a state of thermal isolation from an environment to one of strong thermal coupling.

Abstract: A method and system is provided whereby heliostats in a solar power plant may be calibrated without being aimed away from the receiver. The heliostats may be moved through a calibration path different from their operational path. The calibration path may start from any point along the operational path of the heliostat and may move the reflected sunlight from the heliostat across a portion of the solar receiver. Individual power generation receiver modules may be monitored to detect changes in output as the calibration path takes the heliostat reflection across various receiver modules.

Abstract: A volumetric absorption solar collector in combination with a conventional flat panel collector. Addition of the volumetric absorption solar collector to the conventional flat panel collector allows the overall solar collection system to reach higher collection temperatures, increase collection efficiency, and reduce ecological footprint.

Abstract: A solar energy collector including a solar energy receiver defining a primary target; and a field of heliostats mounted for angular adjustment to receive and direct sunlight to the primary target and an actuator to effect the angular adjustment of each heliostat. A secondary target at or spaced from the primary target. A controller coupled to the actuator configured to sequentially cause, a temporary angular adjustment of the respective the heliostats so as to divert the beam of sunlight received at each heliostat to the secondary target for a predetermined period of time. A recorder to record a representation of each diverted beam at the secondary target. The controller is coupled to the recorder and further configured to respond to the representation of the diverted beam for the respective heliostats when a parameter deviates from norm, by activating the actuator to angularly adjust the corresponding heliostat.

Abstract: Insolation can be used to heat a solar fluid for use in generating electricity. During periods of relatively higher insolation, excess enthalpy in a superheated solar fluid can be stored in a thermal storage system for subsequent use during periods of relatively lower insolation or at times when supplemental electricity generation is necessary. Enthalpy from superheated solar fluid can be transferred to the thermal storage system so as to heat a storage medium therein, but the enthalpy transfer can be limited such that the superheated solar fluid does not condense or only partially condenses. The remaining enthalpy in the de-superheated solar fluid can be used for other applications, such as, but not limited to, preheating the solar fluid for an evaporating solar receiver, supplementing the input to a superheating solar receiver, industrial applications, resource extraction, and/or fuel production.

Abstract: The invention relates to a device for collecting solar energy (1), characterized in that it includes at least one solar receiver (2) including at least one suspension of solid particles fluidized by a gas, each suspension circulating between an inlet and an outlet of the receiver (2), wherein the volume of particles is between 40% and 55% of the volume of the suspension, and the average size of the particles is between 20 and 150 ?m.

Abstract: A solar power system, comprising a solar receiver that absorbs solar radiation, at least first and second fluid flow paths passing through the receiver, a first working fluid flowable through the first fluid flow path to absorb thermal energy from the receiver up to a first maximum temperature and a second working fluid flowable through the second fluid path to absorb thermal energy from the receiver up to a second maximum temperature.

Abstract: The invention relates to a solar collector (1) comprising a collector housing (2), an absorber (3) arranged therein and having a heating medium fluid (13) flowing through it, to absorb solar radiation (28), a return line (6) leading to the absorber (3) and a flow line (7) leading away from the absorber (3). Thereby a pump (14) is arranged on or at least partially inside the collector housing (2) for circulating a heating medium fluid (13) through the absorber (3).

Abstract: The invention relates to a solar collector having a multi-tube receiver, to thermosolar plants that use said collector and to a method for operating said plants, where the multi-tube receivers have a primary reflector (5) formed by two continuous symmetrical parametric curves, a secondary reconcentrator (6) and a receiver (1) that includes several connected tubes (7) with a circular cross-section, the center of gravity of the collector being located very close to the axis of rotation of the collector itself, and the concentration ratio C/Cmax being greater than 0.63, having 100% collection efficiency and having a maximum of two reflections of solar rays (8). The thermosolar plants that use said multi-tube receivers combine same with cylindrical or trough collectors with a tubular receiver and can be used for the direct generation of steam (with a saturation and overheating zone) or the indirect generation of steam (with the collectors connected in series).

Abstract: A process and an apparatus (100) for producing a superheated working fluid from a concentrating solar plant. More specifically, the process and apparatus produce superheated steam. The apparatus is designed such that it can use more than one heat transfer medium to produce the superheated working fluid. A first heat exchanger system (101) is designed to use the heat of a first heat transfer medium in order to preheat, evaporate and superheat a working fluid in a power generating working cycle (103). A second heat exchanger system (102) is designed to use the heat of a second heat transfer medium to superheat the working fluid in cycle (103).

Abstract: A solar receiver (100), for capturing solar radiation, comprising a radiation capturing element (3) and a channel (8) around that element, through which channel (8) a pressurised working fluid is passed to absorb thermal energy from the radiation capturing element.

Abstract: A solar concentrator for heating a fluid has an extended solar reflector with a plurality of reflective concave steps, each step having an apex offset vertically and horizontally from a reflector apex of the reflector. A conduit through which the fluid flows is positioned along a common focal line of each step, preferably on an underside of the conduit. A framework is fixed with the reflector and conduit and is adapted for holding the reflector and conduit in a fixed mutual relationship. In use, with the reflector positioned towards the sun, rays from the sun reflect from each step to concentrate along the focal line on the conduit to heat the fluid.