Abstract: The disclosed technology includes a liquid storage tank having a heating element, an inlet for receiving unheated liquid, an outlet for outputting heated liquid, and a partition configured to divide the tank into a first portion and a second portion. The partition can have an aperture such that the first portion and the second portion are in fluid communication. The liquid storage tank can include an actuator in mechanical communication with the partition and configured to linearly move at least a portion of the partition based at least in part on the temperature of liquid within the tank.

Abstract: The present disclosure solves the problem of solar energy capture and storage for solar power generating devices. This power system does not rely on batteries to accomplish energy generation during nighttime operating hours or during cloudy days. Solar energy is collected in a chamber equipped with opposing parabolic mirrors and a gaseous medium. The solar energy collector traps the majority of incoming sunlight and, through the processes of thermal radiation, heat conduction, and heat convection, converts said sunlight into useable heat energy. The heated gaseous medium is pumped to a Stirling engine for the purpose of conversion to mechanical power.

Abstract: A disclosed windshield washer fluid storage system includes a fluid storage container with a thermal interface. The thermal interface provides for the transference of thermal energy into the container from a heat producing electrical component. Thermal energy from the component is communicating into the container to cool the component and heat washer fluid within the container.

Abstract: In one embodiment, a concentrated solar power system includes a solar tower, multiple solar receivers mounted to the solar tower at different vertical elevations, and a plurality of heliostats provided on the ground within a heliostat field, wherein each heliostat is configured to concentrate solar radiation on any of the solar receivers mounted to the solar tower.

Abstract: The present disclosure describes an apparatus that may be used to generate desalinated water from a supply of untreated water using a photovoltaic cell. The front surface of the photovoltaic cell is partially enclosed to form an evaporation chamber. The front surface of the photovoltaic cell is exposed to sunlight or another light source. This exposure results in power generation by the photovoltaic cell and also heats the air in the evaporation chamber. Untreated water is subsequently introduced into the evaporation chamber. Upon contacting the heated air and the front surface of the photovoltaic cell, a portion of the untreated water evaporates to generate water vapor. The water vapor is then removed from the evaporation chamber and transported to a condensation chamber. The water vapor is cooled in the condensation chamber to yield desalinated water.

Abstract: A combination boiler provides heated water to a boiler loop and domestic hot water (DHW) to a domestic water loop. The combination boiler includes a primary heat exchanger (PHE) connected to the boiler loop and a burner to provide heat to the primary heat exchanger. A secondary heat exchanger (SHE) transfers heat energy from the boiler loop to the domestic water loop. A controller monitors a PHE inlet temperature and a DHW output temperature, obtains a pre-heat initialization temperature threshold and a pre-heat cancellation temperature threshold, and detects a low temperature condition. A pre-heat operation is initiated responsive to the low temperature condition by circulating heated water from the PHE to the SHE. The burner is selectively fired at least in part according to an outlet temperature of the PHE.

Abstract: Disclosed is a multilayer body, comprising a base (2) and a carbon material layer (1) on the base (2), wherein the base (2) is water-permeable, and the carbon material comprises one or more of the following materials: graphite, graphene, graphene oxide, a chemical function group-modified graphene and carbon nanotubes. Further disclosed are a method for preparing the multilayer body, the use of the multilayer body, and a light-absorbing device containing the multilayer body.

Abstract: The present disclosure describes an apparatus that may be used to generate desalinated water from a supply of untreated water using a photovoltaic cell. The front surface of the photovoltaic cell is partially enclosed to form an evaporation chamber. The front surface of the photovoltaic cell is exposed to sunlight or another light source. This exposure results in power generation by the photovoltaic cell and also heats the air in the evaporation chamber. Untreated water is subsequently introduced into the evaporation chamber. Upon contacting the heated air and the front surface of the photovoltaic cell, a portion of the untreated water evaporates to generate water vapor. The water vapor is then removed from the evaporation chamber and transported to a condensation chamber. The water vapor is cooled in the condensation chamber to yield desalinated water.

Abstract: A solar window system for a building is provided. The solar window system includes multiple heat generation encasements. Air inside each heat generation encasement is heated by solar energy. The solar window system further includes a storage tank for storing heat from the heated air. The solar window system also includes a set of connection pipes, wherein the set of connection pipes draw cold air from an indoor space inside the building into the plurality of heat generation encasements, connect each of the heat generation encasements to at least two other heat generation encasements, and transfer the heated air from the set of heat generation encasements to the storage tank.

Abstract: A system for dispensing a fluid includes a container including a sidewall defining an interior space for holding the fluid and configured to separate the fluid into a liquid and a vapor. The system also includes at least one fluid inlet disposed in the sidewall, at least one liquid outlet disposed in the sidewall, a first sensor, a second sensor, and a controller. The first sensor is positioned adjacent to or upstream of the at least one fluid inlet and configured to detect a first temperature of the fluid. The second sensor is positioned adjacent to or downstream of the at least one liquid outlet and configured to detect a second temperature of the fluid. The controller is configured to determine a fluid temperature differential based on the first and second temperatures and determine an operational status of the system based on the fluid temperature differential.

Abstract: A fire starting canteen that has internal fire starting lenses. The lenses can be solid or water lenses. The canteen has two internal chambers, one for holding water and the other for holding water and forming a fire burning lens. The fire starting canteens can be combined reversibly or permanently to form an inner canteen and an outer canteen with larger water-carrying capacity and fire starting capability than a single canteen. The lenses are, preferably, convex but can also be concave or a combination of both. A divider in the interior of the canteen forms the two internal chambers. The divider has a convex shape and, in combination with the chamber filled with water, forms the fire starting lens.

Abstract: An underground heat exchange system is provided to reduce energy consumption for circulation of a heat transfer medium and reduce construction, management, and maintenance costs. The underground heat exchange system includes: a double-pipe heat exchanger that is buried underground to convert a heat transfer medium into a usable form; a medium collector that collects the heat transfer medium that has dispersed its heat via a heat consumption area to circulate the same to the ground heat exchanger; and a plurality of circulation loops. The medium collector includes first and second reservoirs that are arranged in two tiers: upper and lower, spaced apart from each other, an upstream pump is provided in a first circulation loop between the first and second reservoirs, and the second reservoir is placed higher than the first reservoir. The ground heat exchanger may enhance heat exchange efficiency by increasing the contact area and time between the ground and the heat transfer medium.

Abstract: A concentrated solar power (CSP) system includes channels arranged to convey a flowing solids medium descending under gravity. The channels form a light-absorbing surface configured to absorb solar flux from a heliostat field. The channels may be independently supported, for example by suspension, and gaps between the channels are sized to accommodate thermal expansion. The light absorbing surface may be sloped so that the inside surfaces of the channels proximate to the light absorbing surface define downward-slanting channel floors, and the flowing solids medium flows along these floors. Baffles may be disposed inside the channels and oriented across the direction of descent of the flowing solids medium. The channels may include wedge-shaped walls forming the light-absorbing surface and defining multiple-reflection light paths for solar flux from the heliostat field incident on the light-absorbing surface.

Abstract: A solar-thermal refrigerant compression system employing refrigerants, such as R410a and R500, and a method of employing the system in refrigeration and air-conditioning units. The system includes a refrigerant storage tank, an evaporator, a mixing chamber, a condenser and an isochoric thermal compressor comprising a condensate heat exchanger and a heating coil connected to a solar collector field.

Abstract: A fluid temperature stabilization system may employ an exterior casing defining an internal cavity, one or more phase change material may be located within the internal cavity. A fluid inlet may be located at a first end of the casing providing access into the internal cavity, and an outlet may be located at a second end of the casing providing fluid access from the internal cavity.

Abstract: A combined compact hot and ozonated cold water unit which comprises a framework that accommodates a hot water heater device, a ozone generator device and a combined temporary storage tank having both a hot water compartment and a separate cold water compartment. The hot water heater device is connected with the hot water compartment of the combined temporary storage tank for heating the water contained therein. The ozone generator device is connected with only the water compartment of the combined temporary storage tank for supplying ozone to the water contained therein.

Abstract: A thermal solar system having a fire rating of at least A. In a specific embodiment, the system includes a thermal solar module having an aperture region and a backside region. The system has a shaped thickness of material having a first side and a second side. In a preferred embodiment, the shaped thickness of material is characterized by a fire rating of at least A. The material has a thickness suitable to be free from penetration of moisture according to one or more embodiments. The thickness of material also has a structural characteristic capable of maintaining a shape and coupling to the backside region of the thermal solar module according to one or more embodiments. The system also has an air plenum provided between the thermal solar module and the thickness shaped thickness of material. In a preferred embodiment, the system further has a frame assembly operably coupled to the shaped thickness of material to support the shaped thickness of material and the thermal solar module.

Abstract: The present invention relates to a heating arrangement for heating a fluid, comprising a first heat exchanger loop (5), arranged to act on a fluid to be heated, and a second heat exchanger loop (8), arranged to also act on said fluid to be heated, wherein said second heat exchanger loop (8) is connected to a panel (4) that serves as a solar collector and that is arranged to heat at least a part of said second heat exchanger loop (8).

Abstract: A non electric, temperature controlled system for passing or bypassing a solar water heating apparatus includes a temperature controlled water distribution valve directing water to flow from a main supply of water toward a user depending on the setting and configuration of the temperature controlled water distribution valve within the system.

Abstract: 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.

Abstract: A system for regulating the temperature and flow rate of a heat transfer fluid for use in a hybrid steam-generating plant is described. A bypass section may be incorporated into the piping network of a primary steam-generating source to route heat transfer fluid from a hot source to a mixer downstream of at least one heat exchanger. Heat transfer fluid from the hot source may be mixed with cooler heat transfer fluid exiting the heat exchanger in the event that the supply from a secondary steam-generating source is lost or becomes intermittent. The result is a system that maintains a constant flow rate of heat transfer fluid through the heat exchangers while minimizing adverse temperature gradient effects that may result from steam production variability and plant operation outside of design point parameters.

Abstract: A building using solar energy for heating and cooling without any air conditioning equipment is disclosed. The building comprises a fluid channel arranged for a fluid to transfer absorbed solar heat, a solar heat storage bank to store and supply the solar heat, and a mechanism for directing and controlling the flow of the fluid throughout the building. A insulating glass style solar heat collector (IGSHC) and building element comprises a insulating glass or the like; a solar heat absorber is arranged in hollow space of the insulating glass, and separates the space into two subspaces; a fluid channel is connected to the solar heat absorber; the channel connected to a convergent tube; and an air inlet and an air outlet are provided for drawing heated air out from one of the divided subspaces, each of the air inlet and air outlet has a respective cover for closing or opening the air channel.

Abstract: Systems and methods for solar fluid heating in a multi-story building. A system in accordance with an aspect of the present disclosure includes solar collectors installed in solar-facing walls of the multi-story building, in which fluid receives thermal energy from the solar collectors. The system also includes fluid storage vessels. The system further includes a circulating pump coupled to the solar collectors to circulate the heated fluid between the solar collectors and the fluid storage vessels on a floor of the multi-story building.

Abstract: This invention relates to a heating/cooling system operating on the basis of a novel SPLIT BUFFER TANK; representing an efficiency improvement alternative to HVAC systems functioning with existing commercial buffer tanks. Currently, commercial buffers have the heat source provider (HSP)-return and system-return discharging to a common buffer/vessel. Novel SPLIT BUFFER is provided with a SEPARATION DISK placed inside the tank as mechanical way of separating the hot water inflow from the HSP from the warmer water inflow from system return. The disk moves up and down along the tank driven by demanded water supply and return. Pump-1 circulates hot water from the hot section of the buffer to the secondary system claiming for heat. Pump-2 circulates warmer water from the warmer section of the buffer through the HSP where it is reheated, and subsequently stored in the hot section of the buffer to reinitiate this cycle again.

Abstract: The current invention relates to a building installation comprising a building comprising a slab or cellar floor placed in contact with a piece of earth under the building. A fluid hose is placed in the piece of earth under the slab or cellar floor and contains earth circuit fluid which is thermally coupled to a fluid circulation circuit in or by the building such that the earth circuit fluid receives heat from the heated solar collector fluid for circulation in the fluid hose through which heat energy is released to the surrounding piece of earth.

Abstract: A solar thermal collector including a carrier, channels and a solar selective coating is provided. The channels are embedded in the carrier for a heat transfer fluid flowing therein. The solar selective coating is deposited on an outer surface of the carrier. The solar selective coating includes a damping layer, an absorbing layer and an anti-reflecting layer. The damping layer is deposited on the outer surface of the carrier. The absorbing layer is deposited on the damping layer, wherein the absorbing layer has a transition region including plural sub-layers and located adjacent to the damping layer. The anti-reflecting layer is deposited on the absorbing layer, wherein a light beam is adapted to enter the absorbing layer through the anti-reflecting layer, and irradiation energy of the light beam is transformed by the collector into thermal energy, which is then transmitted to the heat transfer fluid in the channels.

Abstract: A solar heater with a primary circuit course in a panel for heating two separate inter connected storage reservoirs.

Abstract: The invention disclosure provides a hot water supply system and method thereof which can control a solar heating unit, a first heat-pump unit, a boiler unit, and an electric heater unit through a control unit to heat water. The control unit operates in a pre-heating period and a heating period after the pre-heating period. In the pre-heating period, the solar heating unit and the first heat-pump unit preheat water. In the heating period, the boiler unit further heats water coming from the solar heating unit and the first heat-pump unit to an exit temperature and stores water in the boiler unit and the electric heater unit so as to provide water to an outflow device. The invention integrates many water heaters in one system, so as to improve the efficiency of generation of hot water and achieve the objectives of energy conservation and carbon reduction.

Abstract: Two sheets of polymer are sealed (S) and produce some dams (Ch1, Ch2, Ch3, . . . ) behind which water is trapped. These dams (Ch1, Ch2, Ch3, . . . ) trap some water around 3-5 liter water per 1 square meter of collector. Water remains behind these dams (Ch1, Ch2, Ch3, . . . ) till its temperature raises. Hot water goes out and cold water is replaced. The temperature of water is controlled by a thermostat (W) which its sensor (T) is located under the collector (FIG. 2) exactly under the dams { Ch (n?1) } where the water is trapped.

Abstract: Some embodiments of the invention relate to a solar preheater having a central body, which includes a base and an outer cover, wherein the base is arranged to receive the outer cover. The solar preheater includes a first thermal collection mechanism and a second thermal collection mechanism.

Abstract: The invention relates to a radiant energy powered water heating methods and apparatus, particularly, to the open-loop solar radiation collection systems. At least one nozzle is directed against a reflection surface facing an evaporation surface to spray at least one jet with reflection to diffuse the fluid within the inner cavity in an atomized plume having the evaporation surface been moisturized by a part of the sprayed fluid and said moisturizing part of the sprayed fluid been sufficiently vaporized or evaporated (see FIG. 3).

Abstract: There is provided a fluid distribution system for optimising consumption of energy, the system comprising: a thermal controller configured to be connected to an external fluid tank containing external fluid having an external fluid temperature adapted to be heated by solar energy, and to an internal fluid tank containing an internal fluid having an internal fluid temperature and a heater adapted to be heated by a non-renewable energy, the thermal controller being configured to be connected to thermostats located a the internal and external tanks for determining the internal fluid temperature and the external fluid temperature; a valve in fluid communication with the internal and external tanks; a fluid controller connected to the thermal controller and to the valve, the fluid controller being configured to operate the valve based on the internal and external fluid temperatures in such a manner to optimise consumption of the non-renewable energy for heating the internal fluid.

Abstract: The invention relates to a measuring device for measuring a level of a fluid in a container for holding a fluid, specifically a level sensor. The container is provided with a conduit for at least one of the supply and the removal of the fluid. A dynamic pressure probe, such as a pitot tube, is arranged in the conduit. The dynamic pressure probe is connected to a pressure sensor for measuring the pressure in the dynamic pressure probe. The fluid level in the container can be determined by using the measured pressure.

Abstract: A solar water heating system, including: (a) a solar heating collector, having: (i) an array of convex lenses; (ii) a panel disposed below the array of convex lenses, wherein the array of convex lenses focuses sunlight on the panel to heat areas of the panel; (iii) a fluid chamber disposed below the panel; and (iv) a plurality of members extending from the panel into the fluid chamber to transfer heat from the panel into fluid in the fluid chamber; (b) a fluid reservoir; (c) a fluid inlet line for moving fluid from the fluid reservoir into the fluid inlet of the solar heating collector; (d) fluid outlet line for moving fluid from the fluid chamber of the solar heating collector to the fluid reservoir; and (e) a pump for moving fluid cyclically through the fluid chamber of the solar collector and the fluid reservoir.

Abstract: A solar liquid-heating-and-cooling system (20) includes: 1. a hot-liquid storage-tank (22); 2. a hot-liquid manifold-tank (26); 3. a coaxial heating-and-cooling-tube (24) that connects downward from the hot-liquid storage-tank (22) to the hot-liquid manifold-tank (26); 4. a double layer heating-and-cooling collector-array-panel (32) located beneath the hot-liquid manifold-tank (26), the panel (32) including, connected to the hot-liquid manifold-tank (26) a. an upper layer of glazed heating-tubes (36); and b. a lower layer of unglazed cooling-tubes (56); 5. parabolic-trough mirror reflectors (64) that are located between the upper and lower layers of tubes (36, 56); 6. cold-liquid manifold-tank (92) located below the panel (32) connected to lower ends both of the glazed heating-tubes (36) and of the unglazed cooling-tubes (56); 7. a cold liquid storage tank (98); and 8.

Abstract: A hybrid photovoltaic and solar thermal system for generating electrical energy and providing heated water for storage or immediate use. The system includes photovoltaic solar panels, each attached to base with an open top, a bottom, and sides. A base cover is connected to the base sides to define a fluid reservoir. A fluid inlet disposed in each side of the bases provide water to the reservoir from a water supply. A fluid outlet disposed in the sides of each base discharges heated water from the reservoirs through a discharge pipe connected to hot water storage tanks. Electrically controlled valves on the inlet and outlets are under the control of a controller coupled to temperature sensors in the reservoirs, such that water is released from the reservoirs and replenished to the reservoirs only after water contained in the reservoirs reaches a predetermined temperature.

Abstract: Methods and systems for solar water heating are provided herein. A modular pipe system for a solar water heater is provided in one embodiment. The system includes a plurality of first manifolds which are interchangeably connectable to any other first manifold. The system also includes a plurality of second manifolds which are interchangeably connectable to any other second manifold. The system further includes a plurality of pipe panels which are interchangeably connectable to any other panel, any first manifold, and any second manifold. Connecting the first manifolds and the second manifolds end to end expands the system along a first axis, and connecting a plurality of panels expands the system along a second axis perpendicular to the first axis.

Abstract: A thermal storage and transfer method for use in both indirect and direct heating solar power plants that involves the use of nitrogen gas as a thermal storage medium for heat transfer in circumstances where little or no solar radiation is available to produce the thermal energy needed to convert water into steam and generate electricity.

Abstract: An apparatus for harnessing solar energy that generates heat from solar radiation, which can be used in various applications. The apparatus for harnessing solar energy comprises a telescope reflector that projects a collimated beam towards a heat accumulator, wherein heat may be generated and used or stored for later use.

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 thermoregulation apparatus for a solar thermal energy capture system comprising a piping infrastructure in fluid communication with a fluid storage tank and one or more solar thermal energy collectors. The thermoregulation apparatus comprises: (i) a thermostatically actuated valve interposed the piping infrastructure downstream from the one or more solar energy collectors and upstream from the fluid storage tank, and (ii) piping for interconnecting the thermostatically actuated valve with the piping infrastructure, and the fluid storage tank. The thermostatically actuated valve can be configured for diverting the flow of working fluid away from the fluid storage tank when the temperature of the working fluid is below a selected set point for actuating the valve, and for diverting the flow of working fluid to the fluid storage tank when the temperature of the working fluid is about or greater than the selected set point.

Abstract: A fuel heating apparatus capable of heating fluid by use of solar energy to provide water for daily life is provided. The fuel heating apparatus includes a water tank, a lifting part and a control part. The water tank is configured to form an accommodation formed therein to store fluid, has an inlet/an outlet which are formed through the water tank to receive and discharge fluid, respectively, and is formed using light passing material or thermal conductive material. The lifting part is vertically installed at facing sides of the window to lift the water tank such that the fluid is heated through sunlight or solar heat introduced through the window. The control part controls operations of the lifting part. The heated fluid provided to the water tank is used for daily life water.

Abstract: A solar power system having a heat exchanger, a heat-focusing device used to receive sunlight, a power-generating device, a power-transforming device coupled to the power-generating device, and a power storage coupled to the power-transforming device is provided. The heat exchanger has a first guiding channel for a first heat-exchange fluid and a second guiding channel for a second heat-exchange fluid. Sunlight is focused to the first heat-exchange fluid flow in the first guiding channel by the heat-focusing device. One end of the power-generating device is communicated with the outlet of the second guiding channel, and the second heat-exchange fluid is suitable for driving the power-generating device to produce a mechanical energy. The power-transforming device is suitable for transforming the mechanical energy into an electric power and storing the electric power into the power storage.

Abstract: Technologies and implementations for reflective roofs are generally disclosed.

Abstract: An apparatus for utilizing radiation is disclosed. The apparatus may comprise a collector unit, a transfer unit and a working unit. The collector unit comprises at least one radiation reflecting surface adapted to focus radiation and to direct said radiation to said transfer unit. The transfer unit may comprise at least one transparent section, which is integrated into a wall of a first working fluid reservoir of said working unit. The first working fluid reservoir may comprise working fluid, wherein said transfer unit is arranged such as to directly transmit radiation to said working fluid to heat said working fluid.

Abstract: An energy conversion system includes a heat to power conversion unit to convert thermal energy of a high temperature fluid into electricity. A space heating element is connected to a heated fluid storage unit to provide heating. A heat driven cooling element is connected to the heated fluid storage unit to provide refrigerated fluid to provide cooling. An array of sensors is distributed to measure system parameters and collect data. A central processing unit is coupled to the array of sensors to process data from the array of sensors, electrical grid data from a utilities operator and data history on water, heat, and power used to calculate operation parameters for components of the energy conversion system. A memory unit coupled to the central processing unit to store processing instructions to be executed by the central processing unit and to store the data history on water, heat, and power used.

Abstract: A drainback tank having a solar return pipe, at least a portion of the solar return pipe being located within the internal body of the tank, the solar return pipe having a hole that is in close proximity to the hole of an output pipe, such that the fluid in the solar return pipe flows into the output pipe and leaves the tank housing to be used to heat the fluid of a corresponding hot water tank via convection in a heat exchanger.

Abstract: Methods and systems for solar water heating are provided herein. A modular pipe system for a solar water heater is provided in one embodiment. The system includes a plurality of first manifolds which are interchangeably connectable to any other first manifold. The system also includes a plurality of second manifolds which are interchangeably connectable to any other second manifold. The system further includes a plurality of pipe panels which are interchangeably connectable to any other panel, any first manifold, and any second manifold. Connecting the first manifolds and the second manifolds end to end expands the system along a first axis, and connecting a plurality of panels expands the system along a second axis perpendicular to the first axis.

Abstract: A steam generation system of an embodiment has a first to fourth heating units. The first heating unit heats a first heat medium by collected solar heat. The second heating unit heats a second heat medium different from the first heat medium by the collected solar heat. The third heating unit heats water or steam by heat of the heated second heat medium. The fourth heating unit further heats the heated water or steam by heat of the heated first heat medium so as to generate steam which is further increased in temperature.

Abstract: A brewery plant with at least one mash container, a lauter tun, a wort pan and a water housing, wherein at least part of the thermal energy requirement of the brewery is covered with solar collectors, and the solar collectors directly or indirectly heat a fluid. Also, a brewing method where the thermal energy requirement for at least of a part of the brewing process stages is at least partially covered with a fluid heated directly or indirectly by solar collectors.