3 Examples of Solar Collectors

The flatplate solar collector is the simplest type, which is composed of a rectangular box with a glass cover and a heatabsorbent bottom layer. When Sunlight passes through the glass, the interior would be warmed, water or air flow through a series of pipes or ducts and absorb the heat from ambient. Unglazed flatplate collectors leave out the glass and the sealed box, and simply rely on the sun's heat, warming the pipes themselves. Another variation includes a roofmounted water tank painted to absorb solar heat. These types of collectors are best suited for warm climates, since even the sealedbox version will allow collected heat to escape readily into cold air.

For colder climates or applications that require higher water temperatures, an evacuated tube system offers better insulation. In these collectors, each pipe passes through a sealed glass tube with no air inside. This allows the tube to function like a thermos, minimizing the heat transfer from the interior heated pipe to the outside environment. Evacuated tube collectors may be able to maintain water temperatures of more than 50 degrees Celsius (122 degrees Fahrenheit) above the ambient temperature.

If you need a system that can consistently provide very hot water, a solar concentrator is your best bet. Concentrators use mirrors to reflect and concentrate the sun's energy on water pipes, greatly increasing the temperature of the water within. Since the mirrors in solar concentrators curve to focus the sun's rays, they work best when pointed directly at the sun, and often include tracking systems to follow the sun across the sky for maximum exposure. Solar concentrators are common in largescale solarpower plants, which contain large fields of troughshaped mirrors heating a network of water pipes to create steam. This steam drives a turbine, creating electricity.

One variation of the solar concentrator design is the solar tower. Instead of a field of concentrators each warming a section of a network of water pipes, a solar tower system uses a field of mirrors all focusing their energy on a single central tower. This raises the temperature at the focus point so high that instead of water, the tower can contain solid matter like salt that becomes molten under the intense heat. Water pipes pass through the structure, absorbing heat from the molten substance, and the steam provided drives a turbine to generate electricity. Molten salt systems have a significant advantage over traditional solar concentrators, because the salt remains hot enough to create steam long after the sun goes down. This can allow a solar plant to create electricity 24 hours a day instead of falling dormant at night.