Abstract: The liquid cooling system has a heat exchanger having a fluid inlet and an outlet; a fluid supply conduit leading to the inlet of the heat exchanger; a fluid return conduit extending from the outlet of the heat exchanger; a bypass conduit extending between the fluid supply conduit and the fluid return conduit; a thermal valve configured for selectively closing the bypass conduit, the valve having a temperature sensing element positioned downstream of both the heat exchanger and the bypass conduit, the temperature sensing element configured to selectively move the thermal valve in response to a temperature change of the liquid which the temperature sensing element is exposed to relative to a temperature threshold of the valve; and a deflector positioned between the temperature sensing element and at least one of the bypass conduit and the heat exchanger outlet.

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 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: According to an embodiment, a smoothing device includes a predicting unit, a calculating unit, and a control unit. The predicting unit predicts a calculation load of operation at a first time slot on the basis of weather prediction information of operation areas in which facility devices that perform environmental control according to control values resulting from the operation based on weather information are installed. The calculating unit calculates a calculation load of operation at a second time slot earlier than the first time slot on the basis of the weather information of the operation areas. The control unit controls an executing device that executes the operation so that part of the operation to be executed at the first time slot is executed at the second time slot.

Abstract: A solar thermal power plant, wherein, in an intermediate superheater in the water-steam circuit, steam is heated to a settable setpoint temperature value at the outlet by a heat carrier medium which has been heated solar-thermally, wherein, for the heating of the steam to a set setpoint temperature value, a mass flow of the heat carrier medium entering the intermediate superheater is controlled as a function of a determined enthalpy difference of the heat carrier medium between the entry and exit thereof into and out of the intermediate superheater and as a function of a determined enthalpy difference of the steam between the exit and entry thereof out of and into the intermediate superheater is provided.

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 solar heating system for a hot water heater. The system has at least one solar heating unit that heats water contained therein and is fluidly connected to a water storage tank. The water storage tank is enclosed underneath the surface of the earth and is fluidly connected to the hot water heater in order to provide hot water to the hot water heater. An active over-heat protection system for the heating panels that tilts away from the sun when heating isn't needed. An active system that maintains proper water temperature in the storage tank during use of hot water and during reheating of water.

Abstract: A heating and cooling system and a method for controlling and regulating the temperature within a building envelope (10) having roof and wall cavities (14) adapted to receive replaceable foam liquid. The interior of the building envelope (10) is maintained at any specific controlled temperature by controlling the temperature of the liquid foam. The temperature of the liquid foam within the roof and wall cavities (14) is sensed and when a change in temperature is detected, a dynamic liquid foam regeneration unit is triggered so as to supply new liquid foam at an appropriate temperature so as to maintain the overall temperature of the liquid foam in the roof and wall cavities (14) substantially constant.

Abstract: Apparatus for converting solar energy to thermal and electrical energy including a substantially unsealed enclosure, an array of photovoltaic cells for converting solar energy to electrical energy located within the enclosure, and a plurality of interconnected heat collecting tubes located within the enclosure and disposed on the same plane as the array of photovoltaic cells for converting solar energy to thermal energy in a fluid disposed within the heat collecting tubes.

Abstract: A solar collector for use in association with a building, the system having a concave mirror located on the exterior of the building and defining a focal point, a moveable mounting for moving the mirror to aim it directly at the sun at least over a predetermined period of the daylight hours, a secondary reflector located at the focal point of the concave mirror to receive the sun's rays reflected from the mirror means, an opening in the concave mirror to receive a concentrated beam of the sun's rays reflected from the secondary reflector, a third reflector located on the convex side of the concave mirror to receive the concentrated beam of the sun's rays from the secondary reflector reflected through the opening, and to redirect it along a heat storage path, a support connected to the concave mirror to receive the redirected beam, the support passing from the exterior to the interior of the building, an energy conversion system within the building interior to receive the redirected light beam from the mirror

Abstract: Applicant's invention is a lightweight solar collection system, supported overhead, having a parabolic reflecting trough which continuously rotates about a fluid-filled collection conduit located at the trough's focal point. The system is supported overhead preventing bending of the collection conduit, ensuring that solar rays reflected off the trough will continuously focus on the conduit. A tracking system, cooperating with the reflection assembly, monitors the location of the sun, cuing the motor when rotation of the trough is required for maximum heat collection. The efficiency acquired through a reflection assembly supported and braced overhead used in cooperation with a system monitoring movement of the sun, allows solar heat collection for operation of a cooling and heating unit simply and economically.

Abstract: A supplementary heat and air supply system for a building includes a solar panel mounted to the exterior of the building, and a solar panel duct extending between the solar panel and the return air manifold of the building's conventional heating system. A fan or blower is positioned within the solar panel duct. The solar panel has a fresh air intake to provide fresh outdoor air to the interior of the solar panel. During daytime hours, when the temperature of air within the solar panel attains a predetermined level, the blower is operated to supply the heated air to the interior of the structure through the solar panel duct, with the heated air being supplied through the return air manifold. When the building's furnace operates, it draws air from the return air manifold, which also acts to draw air from the solar panel through the solar panel duct. The system acts to pressurize the building's interior during operation of the blower, to deter seepage of gases, such as radon, into the building's interior.