Desalination
Desalination or
desalinization refers to any of several processes that remove the excess
salt and other
minerals from
water in order to obtain
fresh water suitable for
animal consumption or
irrigation, and if almost all of the salt is removed, for
human consumption, sometimes producing
table salt as a
by-product.Desalination of
brackish water is already commonplace in the
U.S., where it is used to meet treaty obligations for river water entering
Mexico. Indeed, desalination has spread into use in over a hundred countries, with
Saudi Arabia accounting for about 24% of total world capacity.
Kuwait built the world's first large-scale desalination plant in the 1960s. Kuwait's energy reserves are so great that Kuwait is unique in using desalinated water for
agriculture. The world's largest (
reverse osmosis) desalination plant is in
Ashkelon,
Israel. It began operating on
August 4,
2005, and it is capable of producing 100 million cubic meters of water per year.
|
Shevchenko BN350 desalination unit situated on the shore of the Caspian Sea. |
#
Distillation##
Multi-Stage Flash (MSF)##
Multiple-Effect (MED|ME)##
Vapor Compression (VC)##Evaporation/Condensation#Membrane Processes##
Electrodialysis Reversal (EDR)##
Reverse osmosis (RO)##Nanofiltration (NF)##
Forward osmosis (FO)#
Freezing#Membrane Distillation#
Geothermal#
Solar Humidification (HDH,MEH)#
Ethane Hydrate Crystallisation#High grade water recycling
As of July 2004, the two leading methods were Reverse Osmosis (47.2% of installed capacity world-wide) and Multi Stage Flash (36.5%). (Source: 2004 IDA Worldwide Desalting Plants Inventory Report No 18; published by Wangnick Consulting: [
1].
Desalination of
ocean water is common in the
Middle East and the Caribbean, and is growing fast in the USA, North Africa, Spain, Australia and China. It is also used on
ships,
submarines and
islands.
The traditional process used in these operations is
distillation â€" essentially the boiling of water at less than atmospheric pressure, and thus a much lower temperature than normal. Due to the reduced temperature, energy is saved.
In the last decade, membrane processes have grown very fast, and
Reverse Osmosis (R.O.) has taken nearly half the world's installed capacity. Membrane processes use semi-permeable membranes to filter out dissolved material or fine solids. The systems are usually driven by high-pressure pumps, but the growth of more efficient energy-recovery devices has reduced the power consumption of these plants and made them much more viable; however, they remain energy intensive and, as energy costs rise, so will the cost of R.O. water.
Cogeneration
There are circumstances in which it may be possible to use the same energy more than once. With
cogeneration this occurs as energy drops from a high level of activity to an ambient level. Distillation processes, in particular, can be designed to take advantage of co-generation. In the
Middle East and
North Africa, it has become fairly common for dual-purpose facilities to produce both
electricity and water. The main advantage being that a combined facility can consume less fuel than would be needed by two separate facilities.
Concentrate disposal
Regardless of the method used, there is always a highly concentrated waste product consisting of everything that was removed from the created "fresh water". With coastal facilities, it may be possible to return it to the sea without harm if this concentrate does not exceed the normal ocean salinity gradients to which
osmoregulators are accustomed. Reverse Osmosis, for instance, may remove 50% or more of the water, doubling the salinity of ocean waste. The
benthic community cannot accommodate such an extreme change and many filter feeding animals are destroyed when the water is returned to the ocean. It is more of a problem as you move inland, as one needs to avoid ruining existing fresh water supplies such as ponds, rivers and aquifers. As such, proper disposal of "concentrate" needs to be investigated during the design phase.
Economics
The energy needed for desalination, particularly R.O. has declined but not as fast as energy has increased in price recently. A modern, large, efficient plant is within 20% of the cost of developing a new, local source of fresh water in some places. Desalination stills now control pressure, temperature and brine concentrations to optimize the water extraction efficiency.
Nuclear-powered desalination might be economical on a large scale, and there is a
pilot plant in the former USSR.
A number of factors determine the capital and operating costs for desalination: capacity and type of facility, location, feed water, labor, energy, financing and concentrate disposal. Generally the cost of removing salt from seawater will be about 3-5 times that of removing salt from brackish water.
Environmental
From an environmental point of view, in some locations geothermal desalination can be preferable to using
fossil groundwater or surface water for human needs, as in many regions the available surface and groundwater resources already have long been under severe stress.
Aside from the energy costs of the process, desalination plants produce hypersaline
brine that must be disposed of. These concentrates are classified by the U.S.
Environmental Protection Agency as
industrial wastes. The hypersaline brine has the potential to harm
ecosystems, especially marine environments in regions with low turbidity and high evaporation that already have elevated salinity. Examples of such locations are the
Persian Gulf, the
Red Sea and, in particular,
coral lagoons of
atolls and other
tropical islands around the world.
In the past many novel desalination techniques have been researched with varying degrees of success. Some are still on the drawing board now while others have attracted research funding. For example,to offset the energetic requirements of desalination, the U.S. Government is working to develop practical
Solar Desalination. This development has much potential, since the regions in which desalination is most needed often have an abundance of solar energy.
Other approaches involve the use of geothermal energy. An example would be the work being done by
SDSU Center for Advanced Water Technologies. [
2]
*
Soil salination*
Encyclopedia of Desalination and water and Water Resources*
Global Water Intelligence - monthly newsletter featuring 'Desal Project Tracker'*
Water Desalination Report - weekly newsletter on international desal*
International Desalination Association*
Desalination & Water Reuse - Official magazine of the International Desalination Association*
European Desalination Society*
Middle East Desalination Research Centre*
IAEA - Nuclear Desalination*
German Desalination Society - DME*
Geothermal Desalination*
SDSU (San Diego State University) Center for Advanced Water Technology*
"Desalination Journal" and Desalination Directory of the European Desalination Society*
Desalination by humidification and dehumidification of air: state of the art*
Zonnewater - optimized solar thermal desalination (distillation)*
Solar Desalination using the MEH-Method*
Article: Water issues prompt new look at desalination*
Desalination bibliography Library of Congress*
Water-Technology*[
3] Water Desalination Worldewide, Market, Technologies and Companies
*
Cheap Drinking Water from the Ocean - Carbon nanotube-based membranes will dramatically cut the cost of desalination
