active solar


Solar hot water Solar water heating (SWH) is heating water by sunlight Sunlight is a portion of the electromagnetic radiation given off by the Sun, in particular infrared, visible, and ultraviolet light. On Earth Earth is the third planet from ...
systems use
pumps A pump is a device that moves fluids (s or es), or sometimes , by mechanical action, typically converted from electrical energy into hydraulic energy. Pumps can be classified into three major groups according to the method they use to move the fl ...

fans Fan commonly refers to: * Fan (machine) Sounds from a household fan. A fan is a powered machine A machine is a man-made device that uses power to apply forces and control movement to perform an action. Machines can be driven by anima ...

to circulate fluid (often a mixture of water and glycol to prevent freezing during winter periods) or air, through solar collectors, and are therefore classified under active solar technology. Some of the basic benefits of active systems is that controls (usually electrical) can be used to maximize their effectiveness. For example, a passive solar thermal array which does not rely on pumps and sensors will only start circulating when a certain amount of internal energy has built up in the system. Using sensors and pumps, a relatively small amount of energy (i.e. that used to power a pump and controller) can harvest a far larger amount of available thermal energy by switching on as soon as a useful temperature differential becomes present. Controls also allow a greater variety of choices for utilizing the energy that becomes available. For example, a solar thermal array could heat a swimming pool on a relatively cool morning where heating a domestic hot water cylinder was impractical due to the different stored water temperatures. Later in the day as the temperature rises the controls could be used to switch the solar heated water over to the cylinder instead. Disadvantages of active solar systems include that the external power sources can fail (probably rendering them useless) and that controls require maintenance. Most solar collectors are fixed in their array position mounting, but can have a higher performance if they track the path of the sun through the sky (however it is unusual for thermal collectors to be mounted in this way). Solar trackers, used to orient solar arrays may be driven by either passive or active technology, and can have a significant gain in energy yield over the course of a year when compared to a fixed array. Again passive solar tracking would rely on the inherent thermo-dynamic properties of the materials used in the system rather than an external power source to generate its tracking movement. Active Solar Tracking would use sensors and motors track the path of the sun across the sky. This action can be caused by geographical and time data being programmed into the controls. However, some systems actually track the brightest point in the sky using light sensors, and manufacturers claim this can add a significant extra yield over and above geographical tracking.

See also

*Architectural engineering *Autonomous building *Carbon *Climate change *Passive solar *Photovoltaics *Renewable energy *Renewable heat *Solar air conditioning *Solar chemical *Solar Flower Tower *Solar power *Zero energy building Passive examples: -a tree in front of windows (a deciduous tree) -windows (large facing south, smaller facing north) Active examples: -collectors (solar panels) -storage (water heaters) -dispurts(pumps)

External links

Active solar tracking systems explained
{{DEFAULTSORT:Active Solar Solar architecture Construction