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USA: Solar Energy Powers Desalination Process
Gainesville, Florida - October 3, 2003
A solution to the growing need for fresh water in
many parts of the world may come from the sun, as engineers at the University
of Florida (UF) have developed a system that uses a gravity-induced vacuum
and solar energy instead of electricity or fossil fuels to desalinate water.
The system, according to UF, is significantly more efficient than previous
solar "stills" for removing salt, yet is simple and inexpensive enough
to be built in remote locations where conventionally powered technologies
would be either too expensive or impractical.
"We know that nature uses solar energy to get fresh
water from salt water," said Yogi Goswami, a professor of mechanical engineering
and director of the UF's Solar Energy and Energy Conversion Laboratory.
"We use the same process as nature, except we enhance the process."
Goswami and a 2003 UF doctoral graduate in mechanical
engineering recently appeared in the Proceedings of the 2003 International
Solar Energy Conference.
A lack of potable water is a growing problem worldwide,
according to a United Nations report released in March. The World Water
Development Report says many countries in the Middle East, Africa and Asia
currently face severe water crises, and the number is likely to grow in
coming years as increasing populations and worsening pollution chip away
at fresh-water supplies. In less than half a century, 7 billion people
in 60 countries could face water scarcity, the report says.
Seawater desalination has long been seen as an attractive
solution since the world's oceans, which contain 97.5 percent of the Earth's
water, are inexhaustible. But current desalination systems are heavy energy
users, which makes them impractical for poor countries facing water shortages,
Goswami said.
Nature has its own process for desalination. Fresh
water evaporates from the ocean, forms clouds, condenses and falls to the
ground as rain. Goswami sought to recreate and enhance this process by
exploiting solar energy and natural barometric pressure.
The guts of their system consist of a U-shaped pipe
placed upside down, with one end of the pipe suspended in a tank of salt
water and one in fresh water. When the 32-foot-high pipe is filled with
water, some of it drops into the tanks, leaving behind a vacuum. The area
of the pipe where the vacuum occurs is surrounded by an evaporator that
circulates water heated in a solar collector. The heat forces the salt
water to begin evaporating - a process facilitated by the vacuum because
it significantly lowers the boiling or evaporating temperature of the water.
The resulting steam then enters a condenser. The fresh water drips from
the condenser down the pipe into the tank.
Tests on a small, experimental version of the system
revealed it is 90 percent efficient, which means 90 percent of the solar
energy piped into the evaporator was used in the desalination. Previous
"flat basin" solar stills were only 50 percent efficient, according to
Goswami. Although the system produced only about a half cup of fresh water
an hour, it can be scaled up to provide more, Goswami said.
The system, which consists of off-the-shelf pipes
and other readily available parts, offers a potentially low-cost solution
to desalinating seawater in remote or inaccessible areas, said E. Delyannis,
a scientist and solar desalination expert at the National Center for Scientific
Research's Solar & Other Energy Research Laboratory in Athens, Greece.
"Dr. Goswami's system is promising (as) a new method
that will improve solar distillation efficiency," Delyannis said. "But
you have to keep in mind that all these systems are not compatible to conventional
desalination plants of large capacity. They can be applied in small communities
lacking fresh or good-quality water or to remote places to provide the
people leaving there with small quantities of water."
