Newspaper article The Christian Science Monitor

Salt Water and Waste Heat - Presto! - Drinking Supply

Newspaper article The Christian Science Monitor

Salt Water and Waste Heat - Presto! - Drinking Supply

Article excerpt

Every day, some 10,350 plants around the world create more than 8.3 billion gallons of drinking water for a growing thirsty population.

They do it by turning salt water into fresh, using steadily cheaper techniques. Now, two engineering professors at the University of Florida have taken that technology a step further with a novel idea.

Since power plants need water for cooling purposes and desalination plants need heat, why not combine the needs of both? The professors - James Klausner and Renwei Mei - calculate that their process would shave a sixth of the cost from today's most efficient technology.

"Water is critical to power production which requires a large amount of it," says Barbara Carney, desalination project manager with the National Energy Technology Laboratory, an arm of the United States Department of Energy in Morgantown, W.Va. Now, "instead of power plants being a net user of water, they will be producers of water."

Currently, desalination plants - most of them located in the Middle East - use one of two processes to turn salt water into fresh. One involves boiling salt water and condensing the vapor to produce fresh water, a process called distillation. The other uses high-pressure pumps to force salt water through fine filters that trap and remove waterborne salts and minerals in a process called reverse osmosis. Both technologies are energy intensive and not cost- effective on a large scale, except in areas such as Saudi Arabia where water is short and energy is cheap.

The new technique - called diffusion-driven desalination or DDD - uses heat wasted by electrical power plants.

Since that heat lacks the intensity to boil salt water, Professors Klausner and Mei simply use it to heat the water. The water is then sprayed into the top of a diffusion tower - a column packed with a matrix that creates a kind of slow-motion waterfall. Meanwhile, warm air is pumped up from the bottom of the tower. As the trickling salt water meets the air, evaporation occurs. The evaporated - and now salt-free - water is captured. "Instead of releasing the evaporated water, it will be condensed to produce fresh water," explains Ms. …

Search by... Author
Show... All Results Primary Sources Peer-reviewed

Oops!

An unknown error has occurred. Please click the button below to reload the page. If the problem persists, please try again in a little while.