Abstract: A solar water heater includes a drainback unit with a drainback reservoir and an anti-airlock conduit for assuring that working fluid in the solar collectors is consistently drained from the solar collectors into a drainback reservoir once circulation the working fluid in the solar collectors has stopped. The drainback unit also provides rapid startup by positioning the heat exchanger outside of the drainback reservoir and by positioning the inlet and outlet of drainback reservoir in close proximity to each other.
Abstract: The invention relates to a method for controlling the orientation of a sun collector (K1, K2, K3, K4), with a heat collecting element (10) respectively arranged in the focal line. The temperature and/or the heat quantity of the heat transfer medium flowing through the heat collecting element (10) are measured in the region of a sun collector (K1, K2, K3, K4) in such a way that they can be associated with same, and the determined temperature values (T1, T2, T3, T4; T?1, T?2, T?3; T?4, T?5) and/or heat quantity values are supplied to a control unit controlling the orientation of each sun collector (K1, K2, K3, K4) and orienting the respective sun collector (K1, K2, K3, K4) according to a determined orientation parameter.
Abstract: A circuit board controller enables a solar hot water system to be used in conjunction with, and assist, a conventional heating system such as a furnace. If some heat is available from solar heating, then the solar heat is used for pre-heating so the conventional heating system does not have to perform as much work. If there is enough heat available from solar heating to provide all of the heat that is needed, then operation of the conventional heating system is locked out.
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 hot water system is provided, comprising an ambient temperature sensor, a controller, a valve, a water storage tank, having an inlet and an outlet, and at least a first solar panel, having an inlet in fluid communication with the water storage tank outlet and an outlet in fluid communication with the water storage tank inlet. When the temperature sensor indicates to the controller that the ambient temperature is above a predetermined level, the controller controls the valve to direct flow from the water storage tank outlet to the solar panel inlet and from the solar panel outlet to the water storage tank inlet. When the temperature sensor indicates to the controller that the ambient temperature is below a predetermined level, the controller controls the valve to direct flow from the solar panel inlet to the valve and so to atmosphere.
Abstract: The invention provides a system for providing heated domestic water. The system comprises a heating structure such as a solar collector and a tank connected by an upstream fluid path and a downstream fluid path. A control system is adapted to interrupt supply of water from a source to the system when the domestic water is delivered to a recipient. The invention further provides a heating system with a tank which is filled to a certain limit leaving a certain amount of free space, e.g. to adjust absorption of energy to a supplied amount of energy or for reserving space for drainage of the solar collector. The invention further relates to a solar collector which is protected against excessive temperatures. Furthermore, the intention provides a method for providing heated domestic water.
Abstract: The present invention relates to a semi-cylindrical solar collecting apparatus for a solar boiler that is provided with a plurality of solar collecting plates having a semi-cylindrical shape, thereby greatly enhancing solar collecting efficiencies, and that connects a plurality of heat-exchanging pipes adapted to be heated by the plurality of solar collecting plates with an underground heat-exchanging pipe by means of auxiliary pipes, such that water is circulated well by means of a circulation pump, thereby completely solving the frozen and burst problems of the heat-exchanging pipes and circulation pipes.
Abstract: In one aspect, the invention is directed to a solar energy water heating system for heating water in a water storage tank. In one particular embodiment, the system includes a controller, a solar energy collector whose energy contribution to water in the tank is controlled by the controller, and a non-solar heating system that is not controlled by the controller. Water in the tank may be heated by one or both of the non-solar heating system and energy from the solar energy collector. The controller can determine the amount of energy contributed by solar energy to the water in the tank. In another embodiment, the solar energy water heating system incorporates a controller that controls both the operation of the pump and the operation of the non-solar heating system. In another embodiment, a network of solar energy water heating systems is provided.
Abstract: An integral storage-collector solar water-heating system is disclosed. The system includes a tank and two absorbers, wherein the entire system is full of water. The water circulation goes from the bottom of the tank trough a fine-tube absorber plate, which is located between a transparent cover exposed to the sun and an insulated plate. The heated water passes through a second absorber that heats them to a usage temperature and cause them flows into the tank's space. The second absorber is created between the exposed wall of the tank, by a grid of tunnels that are grooved in a thermally insulated layer that are attached to the inside walls of the tank. The second absorber is covered with transparent cover too. The water flow into the upper part of the tank and a thermo-siphon valve prevents the back flow. After a double heating, the water is stored inside the tank and ready for use.
Abstract: A heating medium supply system (4) is provided which, even when a temperature fluctuation of a heating medium occurs continuously, is capable of relieving a bad thermal influence upon a heat exchanging device due to the temperature fluctuation.
Abstract: A system for heating water includes a first tank containing water and a heater element for heating the water, a solar panel, a control circuit coupling the solar panel to the heater element, and a second tank. The control circuit couples power to the heater element in proportion to available sunlight. The maximum temperature of the water in the first tank is higher than the maximum temperature of the water in the second tank. Water is drawn from the system through the second tank.
Abstract: A photovoltaic water heater includes a tank containing water and a heater element, a solar module, and a control circuit coupling the solar module to the heater element. One or more transducers in the system produce signals indicative of water usage. A microprocessor is programmed to produce a model of water usage from the signals and cause the heater element to heat water in accordance with the model.
Abstract: A solar heat collecting dome includes a frame having an odd number of frame elements extending upward and inward from a floor structure to a disk at the top of the dome. A dome shaped helical structure including two flexible tubes is woven to extend along and around the frame elements, with the dome shaped helical structure extending across alternating inner and outer sides of the frame elements, and with adjacent portions of the dome shaped helical structure extending across alternating inner and outer sides of each frame element. At an outer end of the dome shaped helical structure, the two tubes form an inlet and an outlet. At the inner end, the two tubes are joined. The frame may also include a fluid path, with the fluid moving in opposite directions in each of the frame elements.
Abstract: A furnace in combination with a heat pump and solar panels for providing domestic hot water and forced hot or cooled air utilizing heat pump achieved efficiency levels in an on-demand and unlimited domestic hot water, heating and air conditioning system. In heating mode, recycled air acquires heat from the heat pump's condenser coil and transfers this heat to the on-demand hot water.
Abstract: This invention provides novel devices and methods for the heating of air with solar radiant energy. The devices of the present invention feature a housing partitioned into essentially isolated sections wherein the sections are in fluid communication with each other through a plurality of channels located within the partitions. The two unique features of the invention, essentially isolated sections and partitions comprising a plurality of channels, increase the temperature achieved by the solar heater by 1) creating multiple, sequential sections that function independently of each other providing a higher starting temperature in each section and, therefore, a higher final temperature, 2) providing second means of heating the air within the channels located within the partitions and, 3) by virtually eliminating the mixing of incoming cold air with the heated air of the solar air heater.
Abstract: Solar heating systems are provided which transfer heat from a solar thermal energy source to a hot water heating system, e.g., a domestic hot water system or a radiant heating loop. These systems utilize a circulator pump with an integrated controller which provides solar differential temperature control, optimizing functioning of the solar heating system.
Abstract: A high concentration central receiver system and method provides improved reflectors and a unique heat removal system. The central receiver has a plurality of interconnected reflectors coupled to a tower structure at a predetermined height above ground for reflecting solar radiation. A plurality of concentrators are disposed between the reflectors and the ground such that the concentrators receive reflective solar radiation from the reflectors. The central receiver system further includes a heat removal system for removing heat from the reflectors and an area immediately adjacent the concentrators. Each reflector includes a mirror, a facet, and an adhesive compound. The adhesive compound is disposed between the mirror and the facet such that the mirror is fixed to the facet under a compressive stress.
Type:
Grant
Filed:
January 12, 2004
Date of Patent:
June 28, 2005
Assignee:
The Boeing Company
Inventors:
James B. Blackmon, Jr., Nelson Edwin Jones, Robert E. Drubka
Abstract: A passive solar collector has a reflector or a plurality of reflectors in a tube that is in a partial vacuum and is entirely or partly transparent. An absorber collects light reflected by the reflector or plurality of reflectors and delivers energy from the collected light to a central tube where it heats a substance such as water or other fluid. The absorber is disposed at an angle to the axis of the passive solar collector. The passive solar collector is protected against overheating by one or more devices such as a getter that releases a gas to reduce the vacuum or an opaque shield that is placed so as to cover the reflector in response to an indication of overheating. Reflecting surfaces of the solar collector may be symmetrical or asymmetrical, and they may be smooth or they may have dents, protrusions, or both. The surfaces of the solar collector may be smooth, ridged with smooth curves, or ridged with sharp curves.
Abstract: An energy system for buildings uses solar absorbers, heat exchangers and heat accumulators, and has the following features to improve the thermal balance of the building: the solar absorber has tubes or pipes laid to form meanders between the roofing and an insulating layer arranged thereunder; the solar absorber is subdivided into at least two zones each with its own liquid circulation system; there is arranged below the building a solid heat-accumulator to which heat can be supplied or removed using embedded tubes or pipes; the heat accumulator is subdivided into at least two zones, i.e.
Abstract: A shutter (1; 10) for regulating the fluid flow in an absorber pipe (D) of a solar-thermal power plant comprises a shutter body (2) with a central shutter opening (3) for the fluid (F) and a movable throttle element (4; 12) at least partly closing the shutter opening (3; 11). The throttle element (4) is connected to a motion element (6) that is in thermal contact with the fluid (F) and changes its shape as a function of the fluid temperature so that in case of an increased temperature of the fluid (F), the opening cross section of the shutter opening (3; 11) is enlarged, whereby the mass flow of the fluid (F) increases and the temperature thereof drops.
Type:
Grant
Filed:
August 13, 1998
Date of Patent:
August 31, 1999
Assignee:
Deutsches Zentrum fuer Luft- und Raumfahrt e.V.
Inventors:
Bernhard Hoffschmidt, Robert Pitz-Paal, Peter Rietbrock, Manfred Boehmer
Abstract: A solar energy collecting system includes a water tank and a solar collector and a pump for pumping water from the water tank to the solar collector. A sensor is arranged close to the solar collector. A CPU is connected to the pump and the temperature sensor in order to circulate the water according to the water temperature at the inlet of the solar collector. The water can be circulated in a fast speed when at noon. The water may be heated with a lengthened heating time and may be heated with a smaller temperature difference so as to effectively collect solar energy.
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.