Abstract: A solar thermal system is provided. The system comprises at least one solar thermal collector for heating a heat transfer fluid (HTF); and at least one conduit for transporting the HTF into and out of the at least one solar thermal collector; wherein said at least one conduit is of a foam or plastics material.

Abstract: A greenhouse, for cold weather climates, is configured with a gable that is offset toward the north wall and therefore the south extension of the roof, from the gable to the south wall is longer than the north extension. A greater amount of light can enter through this south extension and the inside surface of the north wall is configured with a reflective surface to allow light to be more uniformly distributed around the plants. The north wall may have no widows and may be thermally insulated to prevent the greenhouse from getting too cold during the night. A ground to air heat transfer (GAHT) system may be configured to produce a flow of greenhouse air under the greenhouse for heat transfer, to moderate the temperature of the greenhouse. A thermal medium may flow to a thermal reservoir for heat exchange with the conduits of the GAHT system.

Abstract: The invention relates to a construction foil (16), especially roof film, roofing foil, flat roof sheeting, fa-cade sheeting and/or vapor barrier and/or sub-roofing sheeting, especially underlayment and/or sarking sheeting, with a single- or multilayer layer structure (17). It is provided according to the invention that at least one moisture sensor (1) for detecting moisture is associated to the construction foil (16), that the moisture sensor (1) is designed as an active pick-up, and that the moisture sensor (1) comprises at least one electrode (18) and/or a humidity sensing element, and the electrode (18) and/or the humidity sensing element is in direct contact with a nonwoven layer (19).

Abstract: The solar-powered LiBr-water absorption air conditioning system using hybrid storage includes one or more solar collectors generating heat energy to drive the system. The solar collector communicates with a generator to heat an aqueous LiBr solution and release refrigerant through vaporization. The refrigerant feeds into a condenser to form a refrigerant condensate. The condensate feeds into an evaporator, which throttles the refrigerant and causes flash vaporization, resulting in cooling discharged into a load. The refrigerant from the evaporator feeds into an absorber containing a weak LiBr-water mixture from the generator to facilitate absorption of the refrigerant. A pump feeds the resultant aqueous LiBr solution back to the generator for another cycle.

Abstract: A heat buffering system that has a hydrant boiler for storing energy and a hut for housing the hydrant boiler outside a building being heated using the energy stored in the hydrant boiler. The hut is insulated. The system has a heat source coupling for connecting a local solar energy collector to the hydrant boiler. Heat is stored in the hydrant boiler in separately controllable layers. Heat is transferred from one of the layers to at least one other layer. A controller is configured to control charging and discharging of the hydrant boiler based on the weather forecast. Buffered energy can be used for heating the building or for selling to others via district heating.

Abstract: A device for storage and conveyance of thermal energy for an energy production system apt to receive solar radiation and based on the use of a modular fluidizable granular bed and a heat exchanger associated thereto is described.

Abstract: A heating system for heating a fluid pipe in an industrial process system includes at least one gas tank fluidically connected to a first catalyst via a gas supply pipe. A first pipe heating zone is fluidically connected to the first catalyst via a first hot gas pipe. The first pipe heating zone has at least one passage extending along a first portion of the fluid pipe, in thermal contact with the fluid pipe.

Abstract: Solar energy is collected and used for various industrial processes, such as oilfield applications, e.g. generating steam that is injected downhole, enabling enhanced oil recovery. Solar energy is indirectly collected using a heat transfer fluid in a solar collector, delivering heat to a heat exchanger that in turn delivers heat into oilfield feedwater, producing hotter water or steam. Solar energy is directly collected by directly generating steam with solar collectors, and then injecting the steam downhole. Solar energy is collected to preheat water that is then fed into fuel-fired steam generators that in turn produce steam for downhole injection. Solar energy is collected to produce electricity via a Rankine cycle turbine generator, and rejected heat warms feedwater for fuel-fired steam generators. Solar energy is collected (directly or indirectly) to deliver heat to a heater-treater, with optional fuel-fired additional heat generation.

Abstract: In the heat utilization installation (1) according to the invention several heat sources (2) are included which are provided each with a jet pump (16), (17), (18), (19). The heat sources (2) are connected to a heat carrier circuit system (7) which includes a single, central circulating pump or circulating pump unit (20). The individual jet pumps (16) to (19) are so controlled for the respective heat sources (2), the required operating temperatures with respect to temperature difference between the outlet and inlet and the flow volume are maintained or achieved. With the possibility of independent control of the flow volumes at the various heat sources (2), uniform fluid temperatures as required for a buffer store (22) or heat consumers can be maintained.

Abstract: Heating system utilizing solar stored energy as a power source.

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: In a hot water supply system having a solar heater that heats a heating medium with absorbed solar heat, a cogeneration unit that heats the medium by heat exhausted from an engine, a hot water supply unit with a heat exchanger for heat-exchanging between the medium and water supplied from a water supply source to generate the hot water, a medium circulator that circulates the medium among the solar heater, cogeneration unit and heat exchanger, an electric heater that heats the hot water with the power generated by the generator, a heat absorption amount to be adsorbed by the solar heater is estimated and operations of the cogeneration unit and the electric heater are controlled based on the estimated heat absorption amount, thereby enabling to improve energy efficiency of the entire system.

Abstract: The solar-based power generator is a system for producing usable electricity from water, which is heated through concentration of ambient, environmental light. The generator includes a reservoir having an open upper end. The reservoir receives a volume of water therein. A convex lens is mounted on an upper edge of the reservoir. The convex lens covers the open upper end. A steam output port is in fluid communication with a steam-based electrical generator. The convex lens concentrates ambient light on the water stored within the reservoir, thus heating the water and to converting the liquid water to steam. Additionally, a methane-burning electrical generator is in communication with the reservoir. Pollutants in the water produce methane during heating and decomposition, which is burned by the methane-burning electrical generator.

Abstract: Provided is a solar light concentrating system which realizes suppression of power generation costs by applying a receiver 2 that is capable of suppressing a manufacturing cost to a low level, facilitating recovery work when a failure occurs, and quickly recovering a heating medium circulating inside in case of an emergency. The receiver 2 is formed by three-dimensionally combining multiple modules 20. At least a part of the modules is a trapezoid-shaped module 20B. The trapezoid-shaped module includes an upper header 21B, a lower header 22B being shorter than the upper header, and multiple heat receiving tubes 23 which connect the two headers. The heat receiving tubes are formed by successively altering their cross-sectional shapes in away that makes each heat receiving tube shaped like a wedge that becomes narrower from its top toward its bottom in a front view, and like a wedge that becomes wider from its top toward its bottom in a side view.

Abstract: An apparatus for heating a working fluid of a gas turbine-solar power generation system, comprising, sequentially connected, a cold air flow channel, a heat collecting cavity, and a hot air passage. The hot air passage is formed by connecting an inner housing on the front side to a supplemental heating section on the rear side. Also comprised is a burner for heating a primary heating air within the supplemental heating section when having insufficient solar power, and the burner is arranged at the supplemental heating section.

Abstract: A superheated steam generator for generating superheated steam is disclosed that can be converted into electric energy by adsorbing water into zeolite and desorbing water from zeolite by use of solar heat source energy and seawater source energy. The superheated steam generator using zeolite is provided with a water supply device for causing the zeolite to adsorb mist-state moisture and heat the zeolite, a zeolite boiler system including a desorption heater for desorbing water molecules adsorbed onto the zeolite and heating the zeolite to produce the superheated steam, a low-temperature purified water tank for storing purified water that can be subjected to heat exchange with at least one of seawater and surface water, and for supplying purified water energy subsequent to the heat exchange to the water supply device, and an atomization device for generating the purified water supplied to the water supply device as the mist-state moisture.

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: A solar energy system comprising: solar collector having thermo-oil piping and three thermo-oil valves; three tanks each having steam inlet and outlet valves; an electric generator device downstream of the three tanks; and a controller, wherein a flow of thermo-oil is alternatively controllable to flow into each of the three tanks wherein fluid in the three tanks is alternatively heatable to a gaseous phase and providable to the electric generator device for producing electrical energy.

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: 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: Solar heating systems are provided which utilize an integrated fixture for transferring heat from a solar collector to a lower-temperature loop, e.g. a domestic hot water system or radiant heating system. The fixture provides a heat exchanger for transferring heat from the solar collector to the lower temperature loop. The fixture may also include a casting, in which are formed solar collector supply and return ports, lower temperature supply and return ports, a solar collector pump volute, and a lower temperature pump volute. The systems also include two pumps, and a temperature optimization control that varies the speed of at least one of the pumps depending on the temperature of the liquid in the solar collector.

Abstract: The forced recirculation solar water heating system with a backup water heater works through an electronic card that initiates the operation and activation of the water recirculators when there is a setpoint temperature difference between the panel and the storage tank detected by means of a bimetallic cable connected at one of the top ends of the panel and another bimetallic cable at the upper part of the storage tank. This storage tank has a series of safety check valves that prevent temperature loss due to hot water backflow to the hydraulic network or due to natural reverse recirculation, thus avoiding excess pressure in the system.

Abstract: A solar receiver has an arrangement of heat transfer surfaces and a heat transfer fluid phase separator, such as a vertical steam/water separator, fluidly interconnected thereto. The receiver includes a plurality of heat transfer fluid filled components, and at least one alternate heat source. When various temperature measurements indicate freezing or solidification of the fluid is possible, the alternate heat source is activated to maintain a temperature of the fluid greater than the freezing/solidification point of the fluid. The application of the alternate heat source further induces natural circulation of the fluid within the components, further providing freeze/solidification protection to the receiver. A controller may be configured to receive sensed temperatures of the fluid, components, ambient air, etc., and use these temperatures relative to a threshold temperature to activate, vary output, and deactivate one or more alternate heat sources.

Abstract: A photovoltaic receiver comprising an elongated structure bearing a plurality of photovoltaic cells. Said structure carries a plurality of finned dissipators, mounted on which are said photovoltaic cells, and ventilating means, designed to convey a flow of cooling air towards said dissipators.

Abstract: An air drying system for use in a concentrated solar power generation system using a fluid heat transfer medium includes a first vent pipe and a first desiccant pack. The first vent pipe extends from the concentrated solar power generation system and includes a first inlet open to ambient air, and a first outlet open to an interior of the solar power generation system in fluid communication with the fluid heat transfer medium. The first desiccant pack is positioned within the first vent pipe between the first inlet and first outlet and is positioned to reduce moisture content of ambient air flowing into the first vent pipe.

Abstract: A working fluid heating system that utilizes solar energy and fuel-fired heaters to heat the working fluid is provided. The system may have a fuel heating plant that has a first fuel-fired heater to heat a first portion of working fluid, a solar heating plant that has both a solar thermal-energy heater and a second fuel-fired heater to heat a second portion of working fluid. The first and second portions may join in a pipeline to supply heated working fluid to a facility such as an electrical generation facility, desalination facility, petrochemical facility, enhanced oil recovery facility, or air conditioning facility.

Abstract: A water heater system is provided with a solar water heater and an electric water heater having one or more electric heating elements. The solar and electric water heaters are configured to provide a common hot water output. A controller is operatively configured with the water heaters and receives a first signal indicative of a current power demand state of an associated electric utility. In response to the received signal, the controller operates the electric water heater in an energy savings mode during periods of high power demand wherein power consumption of the electric heating elements is restricted. The controller is operatively configured to modulate the degree of power consumption restriction placed on the electric heating elements in the energy savings mode as a function of current hot water supply capacity of the solar water heater.

Abstract: A tankless water heating auxiliary system for a solar water heating system, includes a solar collector; a tankless water heater auxiliary system; an insulated water storage tank storing the potable water; a heat exchange system for heating stored water; and piping for connecting the collector, the storage tank and the heat exchanger in fluid communication. A first sensor is connected to and located adjacent the storage tank for sensing the temperature of the stored water at an outlet of the tank.

Abstract: A system for generating electricity. The system includes a platform having a top surface. The platform floats on a body of water and includes a plurality of energy modules. Each energy module produces electricity from a different source of energy and is affixed to the platform. Each module contributes produced electricity to the system for storage and distribution. Modules may include wind turbines for generating electricity from wind, water-driven generators for generating electricity from water currents, solar panels for generating electricity from solar energy, an apparatus which floats on water and converts kinetic energy of wave movements into electricity, and an apparatus which extends below the water where the platform is located upon and generates electricity from differences in water temperature at various levels of water depth. An apparatus may be mounted on the platform which produces hydrogen and oxygen gases through a process of electrolysis.

Abstract: A hybrid solar heat collector within a translucent dome structure includes a tubular frame, forming a first fluid path, and a transverse hose winding in a spiral inside and outside alternating legs of the frame to form a second fluid path. The first fluid path is connected to a reservoir in which a heater that is turned on to heat a fluid in the first fluid path when its temperature falls below a threshold. The reservoir is located within the dome structure and is configured to readily heat the space within the dome structure, so that the freezing of fluids within the heat collector is prevented. The translucent dome structure is provided with a layer having an opacity that is increased in response to an increase in temperature above a different threshold level, so that the boiling of fluids within the heat collector is prevented.

Abstract: Disclosed is a process for generating and superheating steam.

Abstract: A solar power generation system includes a fluid housing, a solar collector, and a heating system. The fluid housing contains a heat transfer medium. The solar collector concentrates solar energy onto the heat transfer medium. The heating system includes at least one gas tank containing a gas and fluidically connected to a first catalyst. The first catalyst is configured to catalyze gas from the gas tank to create hot gas. The heating system also includes a first hot gas pipe fluidically connected to the first catalyst and positioned with respect to the fluid housing such that hot gas flowing through the first hot gas pipe comes into thermal contact with the heat transfer medium within the fluid housing.

Abstract: A solar water heater system composed of retrofitting an existing conventional gas or electric water heater by adding a solar thermal circulating loop, wherein a heat pipe vacuum tube solar collector, a thermal circulating pump, a computer control system with temperature sensors and relative three-way connections, valves and pipes are installed on the existing water storage tank, is disclosed herein along with the method for building the system.

Abstract: A superheated steam generator for generating superheated steam is disclosed that can be converted into electric energy by adsorbing water into zeolite and desorbing water from zeolite by use of solar heat source energy and seawater source energy. The superheated steam generator using zeolite is provided with a water supply device for causing the zeolite to adsorb mist-state moisture and heat the zeolite, a zeolite boiler system including a desorption heater for desorbing water molecules adsorbed onto the zeolite and heating the zeolite to produce the superheated steam, a low-temperature purified water tank for storing purified water that can be subjected to heat exchange with at least one of seawater and surface water, and for supplying purified water energy subsequent to the heat exchange to the water supply device, and an atomization device for generating the purified water supplied to the water supply device as the mist-state moisture.

Abstract: Disclosed is a solar water heating apparatus comprising a central tank and one or more outer layers wherein at least part of the exterior of the outermost layer is adapted to be exposed to the sun. The outer layers also form water pathways such that, when the tank is substantially filled with water, said water is able to circulate around a path formed by said central tank and the outer layers. A pulsing pump may help circulate the water. An auxiliary heating element may be also provided, such as a small gas burner.

Abstract: A system for operating environmental equipment with improved efficiency including a surface covering having fluid carrying conduits and surface structure heated by solar radiation to heat the fluid with the fluid carrying conduits having non-round cross-sectional shapes to provide increased heat transfer contact surfaces, a heat exchanger communicating with the conduits and energy conversion equipment coupled with the heat exchanger to utilize the heat generated energy for operation.

Abstract: In a hot water supply system having a solar heater that heats a heating medium with absorbed solar heat, a cogeneration unit that heats the medium by heat exhausted from an engine, a hot water supply unit with a heat exchanger for heat-exchanging between the medium and water supplied from a water supply source to generate the hot water, a medium circulator that circulates the medium among the solar heater, cogeneration unit and heat exchanger, an electric heater that heats the hot water with the power generated by the generator, a heat absorption amount to be adsorbed by the solar heater is estimated and operations of the cogeneration unit and the electric heater are controlled based on the estimated heat absorption amount, thereby enabling to improve energy efficiency of the entire system.

Abstract: A thermal device includes a solar collector configured to concentrate solar energy in a heated zone, and a combustion area configured to provide thermal energy to the heated zone simultaneously with the concentrated solar energy from the solar collector. The heated zone may include two or more locations, wherein the solar energy is primarily concentrated at only one of the two or more locations at any particular time.

Abstract: A solar energy module includes a photovoltaic unit including a layer of one or more solar cells. The layer has a front side exposed to incident radiation and an opposite back side. The solar energy module also includes a thermal unit thermally coupled to the back side of the layer of one or more solar cells. The thermal unit includes one or more channels through which a thermal transfer fluid flows, wherein a portion of the incident radiation is converted into electricity by the layer of one or more solar cells and a portion of the incident radiation is simultaneously converted to heat for increasing the temperature of the thermal transfer fluid. The solar energy module also includes a heating system to further increase the temperature of the thermal transfer fluid. The heating system is powered by electricity generated by the one or more solar cells.

Abstract: A method and apparatus for heating service water and providing heat for the heating of buildings, if required, including a first heat source, a storage tank, and a service water heat exchanger for heating service water, where a simple, robust and efficient system is attained by connecting the first channel of the service water heat exchanger in parallel with the storage tank and by providing a control device, which controls the first circulator pump and the second circulator pump in such a way that in a first operational state the mass flow of the heat transport medium through the first heat source is greater than the mass flow of the heat transport medium through the first channel of the service water heat exchanger, and that in a second operational state the mass flow of the heat transport medium through the first heat source is smaller than the mass flow of the heat transport medium through the first channel of the service water heat exchanger

Abstract: A heating system for heating a fluid pipe in an industrial process system includes at least one gas tank fluidically connected to a first catalyst via a gas supply pipe. A first pipe heating zone is fluidically connected to the first catalyst via a first hot gas pipe. The first pipe heating zone has at least one passage extending along a first portion of the fluid pipe, in thermal contact with the fluid pipe.

Abstract: An air drying system for use in a concentrated solar power generation system using a fluid heat transfer medium includes a first vent pipe and a first desiccant pack. The first vent pipe extends from the concentrated solar power generation system and includes a first inlet open to ambient air, and a first outlet open to an interior of the solar power generation system in fluid communication with the fluid heat transfer medium. The first desiccant pack is positioned within the first vent pipe between the first inlet and first outlet and is positioned to reduce moisture content of ambient air flowing into the first vent pipe.

Abstract: A temperature control system (100) includes a heating system (1), a cooling system (2) and a control unit (3). The heating system has a heated fluid. The heated fluid is heated by a solar energy for increasing the mold temperature. The cooling system has a cooled fluid. The cooled fluid cools for decreasing the mold temperature. The control unit controls the heating system and the cooling system to be opened or closed.

Abstract: An embodiment of the present invention may take the form of a system and method that may use at least one solar heating system to heat the fuel consumed by a turbomachine. An embodiment of the present invention may incorporate concentrated solar power (CSP). Generally, CSP systems incorporate a plurality of lenses, mirrors, or combinations thereof and a tracking system to focus a large area of sunlight forming a small concentrated beam of light. The concentrated light may then be used as a heat source. In an embodiment of the present invention, the heat source may be used to partially or completely heat the fuel consumed by a turbomachine. CSP systems may take the form of a solar trough system, a parabolic dish system, a solar power tower system, or the like.

Abstract: A thermal energy system comprises a primary thermal energy system, a solar thermal energy system, a burner, and a heat recovery system. The solar thermal energy system comprises a pipe for absorbing heat from solar rays. The burner is arranged such that the pipe of the solar thermal energy system is capable of absorbing heat from the burner. The heat recovery system uses thermal energy from at least one of the primary and solar thermal energy sources.

Abstract: Solar heating systems are provided which utilize an integrated fixture for transferring heat from a solar collector to a lower-temperature loop, e.g. a domestic hot water system or radiant heating system. The fixture provides a heat exchanger for transferring heat from the solar collector to the lower temperature loop. The fixture may also include a casting, in which are formed solar collector supply and return ports, lower temperature supply and return ports, a solar collector pump volute, and a lower temperature pump volute. The systems also include two pumps, and a temperature optimization control that varies the speed of at least one of the pumps depending on the temperature of the liquid in the solar collector.

Abstract: A system for heating water including a water heater and a solar collector is provided. The water heater includes a water storage tank, a heating element positioned within the bottom end of the water tank and a lower thermostat configured to selectively activate the heating element as a function of the water temperature sensed by the temperature sensor of the thermostat. A tank heat exchanger is also positioned within the bottom end portion of the water storage tank. The tank heat exchanger is configured to contain a fluid medium for heat exchange with water in the bottom end portion of the water storage tank. The solar collector is fluidly coupled to the tank heat exchanger of the water heater for circulating the fluid medium through the tank heat exchanger.

Abstract: A control system suitable for use with a bathing unit system having a water receptacle is provided. The control system comprises a heating module, a power source and a controller in communication with the heating module and the power source. The power source includes an energy storage member for storing energy collected from a solar panel, and is operative for supplying power generated from solar energy to the heating module. The controller is operative for causing the power source to supply power to the heating module at least in part based on first information derived from a temperature of the water within the water receptacle and second information derived from a condition associated with the power source. The controller is further operative for selecting between a first power source and a second power source for supplying power to the heating module.

Abstract: An apparatus is disclosed for brewing coffee, which includes a housing having an inner chamber for receiving and retaining brewed coffee, a water reservoir adjacent to and generally surrounding the inner chamber, for receiving water, and an electrically powered coil for heating the water contained in the water reservoir. A brew valve is positioned above the inner chamber for supporting coffee grounds, the brew valve being rotatable between a first inactive position and a second active position for brewing coffee. Heated water is directed from the water reservoir to the brew valve and to the coffee grounds to brew coffee. and to the coffee grounds to produce brewed coffee, and into the inner chamber.

Abstract: A solar thermal energy transmission system having a bellows that sealingly interconnects a first structure to a second structure is disclosed. The bellows includes a surface that is compatible with a molten salt and is configured to resiliently deform in response to contraction and expansion of at least one of the first and second structures, to thereby accommodate relative movement of the structure(s) to which it is coupled.