Abstract: A modular solar air heater comprises an extruded metal frame having fingers operable to secure a glazing, an absorber, and an insulating back sheet to the frame. The heater may also operate as a cooler. The heater further comprises an active air circulation system, such as a fan, which may be coupled with an air inlet of the heater. The heater has an air outlet and may further include a bypass channel to direct the airflow alternatively through one or both the bypass channel and the air outlet. A heating element and a cooling element may be coupled with the air outlet to further heat and also cool the air through the air outlet, respectively. A photovoltaic panel may be included to provide electrical power to the heater.

Abstract: A solar heater includes a plurality of suspended vertical components that cover at least a portion of an interior side of a window and have open top and bottom ends. Each suspended vertical component has a heat absorbing body position within the transparent sheath. The heat absorbing body is located a first spaced distance from the inner sheath surface of a first side portion of the sheath and a second spaced distance from the inner sheath surface of a second side portion of the sheath. The open bottom end of the sheath receives cool ambient air that is heated while passing between the heat absorbing body and the inner sheath surface of the first side portion and between the heat absorbing body and the inner sheath surface of the second side portion. The open top end of the sheath exhausts the heated air to an interior space of a building.

Abstract: A solar collector system is for support in a building opening to furnish heated air to the interior of the building. The solar collector system includes a collector shell supported at the opening and including a front heating chamber, at least one air intake channel and at least one air outlet channel and a fan disposed within the collector shell for providing a closed loop air circulation from the air intake channel, through the heating chamber and to the air outlet channel. The front heating chamber is defined in part by a parabolic reflector having a focal point facing out from the heating chamber. A heat exchanger is disposed within the parabolic reflector for absorbing solar energy directed to the heating chamber.

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: A solar collector panel is disclosed for heating of air, in which the conventional insulation material on the back panel facing away from the sun is replaced by a spacing between a permeable back panel and a permeable heat absorber means, so that a heat convection airflow through the back panel and into the interior of the solar energy panel against the temperature gradient prevents the convection heat loss in the opposite direction. The back panel also reduces the radiation heat loss from the heat absorber means. Furthermore, in case the flow of air through the solar energy panel is stopped, the convection-insulation will no longer be effective, and a photovoltaic cell panel placed within the solar energy panel and generating electricity from the solar radiation will not be subjected to the damaging high stagnation temperature of a traditionally insulated solar collector panel.

Abstract: An air type solar system of the present invention has a heat-collecting unit for heating air by solar heat, and a blower fan for blowing the air as a heat medium from the heat-collecting unit. The blower fan is of a large scale, which is capable of: blowing the air at a rate of about 100 to 2000 m3/hour; and rotating by a direct-current generated from solar cells under normal conditions. In addition, the amount of airflow is confined by an automatic electrical control in winter to adjust the temperature of heat-collected air to an appropriate temperature for heating and humidification. Therefore, the air type solar system of the present invention can be appropriately operated in quest of an effective use of the solar cells while there is no need to use any storage cell.

Abstract: A device for transferring heat between a panel heated by solar radiation and a wall surface, including an insulating plate mounted parallel between the panel and the wall surface, to define a closed external space between the panel and the insulating plate, and a closed internal space between the insulating plate and the wall. An air circulator is interposed between the external space and the internal space and can be put selectively in an open state allowing circulation of air between the external space and the internal space, and thus allowing thermal transfer between the panel and the wall, and a closed state preventing circulation of air between the external space and the internal space, and thus preventing thermal transfer between the panel and the wall.

Abstract: The present invention is a self-contained, solar powered heating and cooling system for a building. The collector has an insulated heating chamber, and a light transmissive cover and a thermostatically controlled vent. The chamber contains absorptive columns standing on the floor. An internal liquid conduit exposes the liquid to the heat within the chamber. The collector is connected to a remote thermal reservoir such that a liquid circuit and a separate gas circuit both circulate heated fluid to the reservoir. Heat can be stored in any of a liquid reservoir, thermal mass reservoir and gas reservoir. Wind powered generators and photovoltaic cells provide power for the system or other applications. The thermal reservoir has heat exchangers which deliver stored heat to the building or operate a heat operated refrigeration machine (e.g., a liquid absorption chiller). Additional self sustaining power sources may optionally be incorporated into the present invention.

Abstract: A compound solar water heating and dehumidifying device including an adsorption bed disposed at a lower rim of a plate type heat collector of a solar water heating element for causing a heat collector element to absorb heat in the day-time and the adsorption bed to regenerate and accumulate heat. At night, the heat of adsorption and heat of condensation are released to the heat collector element to retard the drop of temperature of water in water channels that are in contact with the heat collector element. Therefore, dissipation of heat from the hot water in a water tank may be retarded and water moisture may be removed.

Abstract: In a solar collector assembly, one or more absorber tubes are made up of a plurality of discarded metal can bodies in end-to-end relation, one or more collector tubes are made up of a plurality of discarded transparent pop bottles arranged in end-to-end relation to one another and in surrounding relation to the absorber tubes. A blower is positioned in one of the absorber tubes to force air through the absorber tube and through a discharge conduit into a space to be heated.

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.