Desalination, desalinization,
and desalinisation refer to any of several processes that remove some
amount of salt and other minerals from
saline water. More
generally, desalination may also refer to the removal of salts and minerals,as
in soil desalination.
Salt water is desalinated to
produce fresh water suitable for human
consumption or irrigation. One potential byproduct of
desalination is salt. Desalination is used on many seagoing ships and submarines.
Most of the modern interest in desalination is focused on developing cost-effective
ways of providing fresh water for human use. Along with recycled wastewater,
this is one of the few rainfall-independent water sources.
Due to relatively high energy
consumption, the costs of desalinating sea water are generally higher than the
alternatives (fresh water from rivers or groundwater,
water
recycling and water conservation), but alternatives are not
always available.
Desalination is particularly
relevant to dry countries such as Australia, which traditionally
have relied on collecting rainfall behind dams to provide their drinking water
supplies. According to the International Desalination Association, in June
2011, 15,988 desalination plants operated worldwide, producing 66.5 million
cubic meters per day, providing water for 300 million people.is expected to
reach 120 million m3 by 2020; some 40 million m3 is planned
for the Middle
East. The world's largest desalination plant is the Jebel Ali
Desalination Plant (Phase 2) in the United Arab Emirates.The largest percent of
desalinated water used in any country is in Israel, which
produces 50% of its domestic water use from seawater desalination
Methods
The traditional process used in
these operations is vacuum distillation—essentially the boiling of
water at less than atmospheric pressure and thus a much lower temperature than
normal. This is because the boiling of a liquid occurs when the vapor
pressure equals the ambient pressure and vapor pressure increases with
temperature. Thus, because of the reduced temperature, low-temperature
"waste" heat from electrical power generation or industrial processes
can be used.
The principal competing processes
use membranes to desalinate, principally applying reverse
osmosis technology. Membrane processes use semipermeable membranes and
pressure to separate salts from water. Reverse osmosis plant membrane systems
typically use less energy than thermal distillation, which has led to a
reduction in overall desalination costs over the past decade. Desalination
remains energy intensive, however, and future costs will continue to depend on
the price of both energy and desalination technology.
Considerations and criticism
Energy consumption
Energy consumption of sea
water desalination can be as low as 3 kWh/m3, including
pre-filtering and ancillaries, similar to the energy consumption of existing
fresh water supplies transported over large distances, but much higher than
local fresh water supplies which use 0.2 kWh/m3 or less.
The laws of physics determine a
minimum energy consumption for sea water desalination around 1 kWh/m3,
excluding pre-filtering and intake/outfall pumping. Under 2 kWh/m3
has been achieved with existing reverse osmosis membrane technology, leaving
limited scope for further energy reductions.
Supplying all domestic water by
sea water desalination would increase US Domestic energy consumption by around
10%, about the amount of energy used by domestic refrigerators
Energy Consumption of Sea Water
Desalination Methods...
|
Desalination Method >>
|
||||
|
Electrical energy (kWh/m3)
|
4–6
|
1.5–2.5
|
7–12
|
3–5.5
|
|
Thermal energy (kWh/m3)
|
50–110
|
60–110
|
None
|
None
|
|
Electrical equivalent of thermal
energy (kWh/m3)
|
9.5–19.5
|
5–8.5
|
None
|
None
|
|
Total equivalent electrical
energy (kWh/m3)
|
13.5–25.5
|
6.5–11
|
7–12
|
3–5.5
|
Note: "Electrical
equivalent" refers to the amount of electrical current which could be
generated using a given quantity of thermal energy and appropriate turbine
generator.
Cogeneration
Cogeneration
is the process of using excess heat from electricity generation for another
task: in this case the production of potable
water from seawater or brackish groundwater in an integrated, or
"dual-purpose", facility where a power plant provides the energy for
desalination. Alternatively, the facility's energy production may be dedicated
to the production of potable water (a stand-alone facility), or excess energy
may be produced and incorporated into the energy grid (a true cogeneration
facility). Cogeneration takes various forms, and theoretically any form of
energy production could be used. However, the majority of current and planned
cogeneration desalination plants use either fossil
fuels or nuclear power as their source of energy. Most plants
are located in the Middle East or North
Africa, which use their petroleum resources to offset limited water
resources. The advantage of dual-purpose facilities is they can be more
efficient in energy consumption, thus making desalination a more viable option
for drinking water.
In a December 26, 2007, opinion
column in The Atlanta Journal-Constitution,
Nolan Hertel, a professor of nuclear and radiological engineering at Georgia Tech, wrote, "...
nuclear reactors can be used ... to produce large amounts of potable water. The
process is already in use in a number of places around the world, from India to Japan and Russia. Eight
nuclear reactors coupled to desalination plants are operating in Japan alone,
nuclear desalination plants could be a source of large amounts of potable water
transported by pipelines hundreds of miles inland..."
Additionally, the current trend in
dual-purpose facilities is hybrid configurations, in which the permeate from a reverse
osmosis desalination component is mixed with distillate from thermal
desalination. Basically, two or more desalination processes are combined along
with power production. Such facilities have already been implemented in Saudi
Arabia at Jeddah
and Yanbu.
A typical aircraft
carrier in the US military uses nuclear power to desalinate 400,000 US
gallons (1,500,000 l; 330,000 imp gal) of water per day.
Economics
Costs of desalinating sea water
(infrastructure, energy and maintenance) are generally higher than the
alternatives (fresh water from rivers or groundwater,
water
recycling and water conservation), but alternatives are not
always available. Achievable costs in 2013 range from 0.45 to 1 US$/cubic metre
(2 to 4 US$/kgal).
The cost of untreated fresh water
in the developing world can reach 5 US$/cubic metre.
|
Average water consumption and
cost of supply by sea water desalination (±50%)
|
|||
|
Area
|
Consumption USgal/person/day
|
Consumption litre/person/day
|
Desalinated Water Cost
US$/person/day
|
|
USA
|
100
|
380
|
0.29
|
|
Europe
|
50
|
190
|
0.14
|
|
Africa
|
15
|
60
|
0.05
|
|
UN recommended minimum
|
13
|
50
|
0.04
|
Factors that determine the costs
for desalination include capacity and type of facility, location, feed water,
labor, energy, financing, and concentrate disposal. Desalination stills now control
pressure, temperature and brine concentrations to optimize efficiency. Nuclear-powered
desalination might be economical on a large scale.
While noting costs are falling, and
generally positive about the technology for affluent areas in proximity to
oceans, a 2004 study argued, "Desalinated water may be a solution for some
water-stress regions, but not for places that are poor, deep in the interior of
a continent, or at high elevation. Unfortunately, that includes some of the
places with biggest water problems.", and, "Indeed, one needs to lift
the water by 2,000 metres (6,600 ft), or transport it over more than 1,600
kilometres (990 mi) to get transport costs equal to the desalination
costs. Thus, it may be more economical to transport fresh water from somewhere
else than to desalinate it. In places far from the sea, like New Delhi,
or in high places, like Mexico City, high transport costs would add to the high
desalination costs. Desalinated water is also expensive in places that are both
somewhat far from the sea and somewhat high, such as Riyadh and Harare. In many
places, the dominant cost is desalination, not transport; the process would
therefore be relatively less expensive in places like Beijing, Bangkok, Zaragoza, Phoenix,
and, of course, coastal cities like Tripoli."
After being desalinated at Jubail, Saudi Arabia, water is pumped 200 miles (320 km)
inland through a pipeline to the capital city of Riyadh. For coastal
cities, desalination is increasingly viewed as an untapped and unlimited water
source.
In Israel as of 2005, desalinating
water costs US$ 0.53
per cubic meter (0.053¢ per liter). As of 2006, Singapore was
desalinating water for US$0.49 per cubic meter. The city of Perth began operating a reverse osmosis
seawater desalination plant in 2006, and the Western Australian government
announced a second plant will be built to serve the city's needs. A
desalination plant is now operating in Australia's largest city, Sydney, and the Wonthaggi desalination plant was under
construction in Wonthaggi, Victoria.
The Perth desalination plant is
powered partially by renewable energy from the Emu Downs Wind Farm. A wind farm at Bungendore
in New South Wales was purpose-built to generate
enough renewable energy to offset the Sydney plant's
energy use, mitigating concerns about harmful greenhouse
gas emissions, a common argument used against seawater desalination.
In December 2007, the South
Australian government announced it would build a seawater desalination plant
for the city of Adelaide, Australia, located at Port Stanvac. The desalination plant was
to be funded by raising water rates to achieve full cost recovery. An online,
unscientific poll showed nearly 60% of votes cast were in favor of raising
water rates to pay for desalination.
A January 17, 2008, article in the
Wall Street Journal stated, "In
November, Connecticut-based Poseidon Resources Corp. won a key regulatory
approval to build the $300 million water-desalination plant in Carlsbad, north of San Diego.
The facility would produce 50,000,000 US gallons (190,000,000 l;
42,000,000 imp gal) of drinking water per day, enough to supply about
100,000 homes ... Improved technology has cut the cost of desalination in half
in the past decade, making it more competitive ... Poseidon plans to sell the
water for about $950 per acre-foot [1,200 cubic meters
(42,000 cu ft)]. That compares with an average [of] $700 an acre-foot
[1200 m³] that local agencies now pay for water." In June 2012, new
estimates were released that showed the cost to the water authority had risen
to $2,329 per acre-foot. Each $1,000 per acre-foot works out to $3.06 for 1,000
gallons, or $.81 per cubic meter.
While this regulatory hurdle was
met, Poseidon Resources is not able to break ground until the final approval of
a mitigation project for the damage done to marine life through the intake pipe
is received, as required by California law. Poseidon Resources has made
progress in Carlsbad, despite an unsuccessful attempt to complete construction
of Tampa Bay Desal, a desalination plant in Tampa Bay, FL, in 2001. The Board
of Directors of Tampa Bay Water was forced to buy Tampa Bay Desal
from Poseidon Resources in 2001 to prevent a third failure of the project.
Tampa Bay Water faced five years of engineering problems and operation at 20%
capacity to protect marine life, so stuck to reverse osmosis filters prior to
fully using this facility in 2007.
In 2008, a San Leandro, California company (Energy Recovery Inc.) was desalinating water
for $0.46 per cubic meter.
While desalinating 1,000 US
gallons (3,800 l; 830 imp gal) of water can cost as much as $3,
the same amount of bottled water costs $7,945.
Environmental
Intake
In the United
States, due to a 2011 court ruling under the Clean
Water Act, ocean water intakes are no longer viable without reducing
mortality of the life in the ocean, the plankton, fish
eggs and fish larvae, by 90%. The alternatives include beach wells to eliminate
this concern, but require more energy and higher costs, while limiting output.
The Kwinana Desalination Plant opened in
Perth in 2007. Water there and at Queensland's Gold Coast Desalination Plant and
Sydney's Kurnell Desalination Plant is withdrawn
at only 0.1 meters per second (0.33 ft/s), which is slow enough to let
fish escape. The plant provides nearly 140,000 cubic meters
(4,900,000 cu ft) of clean water per day.
Outflow
All desalination processes produce
large quantities of a concentrate, which may be increased in temperature, and
contain residues of pretreatment and cleaning chemicals, their reaction
byproducts, and heavy metals due to corrosion.Chemical pretreatment and
cleaning are a necessity in most desalination plants, which typically includes
the treatment against biofouling, scaling, foaming and corrosion in thermal
plants, and against biofouling, suspended solids and scale deposits in membrane
plants.
To limit the environmental impact
of returning the brine to the ocean, it can be diluted with another stream of
water entering the ocean, such as the outfall of a wastewater
treatment or power plant. While seawater power plant cooling water outfalls
are not as fresh as wastewater treatment plant outfalls, salinity is reduced.
With medium to large power plant and desalination plant, the power plant's
cooling water flow is likely to be at least several times larger than that of
the desalination plant. Another method to reduce the increase in salinity is to
mix the brine via a diffuser in a mixing zone. For example, once the pipeline
containing the brine reaches the sea floor, it can split into many branches,
each releasing brine gradually through small holes along its length. Mixing can
be combined with power plant or wastewater plant dilution.
Brine is denser than seawater due
to higher solute concentration. The ocean bottom is most at risk because the
brine sinks and remains there long enough to damage the ecosystem. Careful
reintroduction can minimize this problem. For example, for the desalination
plant and ocean outlet structures to be built in Sydney from late 2007, the
water authority stated the ocean outlets would be placed in locations at the
seabed that will maximize the dispersal of the concentrated seawater, such that
it will be indistinguishable beyond between 50 and 75 meters (164 and
246 ft) from the outlets. Typical oceanographic conditions off the coast
allow for rapid dilution of the concentrated byproduct, thereby minimizing harm
to the environment.
Alternatives without pollution
Some methods of desalination,
particularly in combination with evaporation
ponds, solar stills, and condensation
trap (solar desalination), do not discharge brine.
They do not use chemicals in their processes nor the burning of fossil fuels.
They do not work with membranes or other critical parts, such as components
that include heavy metals, thus do not cause toxic waste (and high
maintenance).
A new approach that works like a
solar still, but on the scale of industrial evaporation ponds is the integrated biotectural system. It can
be considered "full desalination" because it converts the entire
amount of saltwater intake into distilled water. One of the unique advantages
of this type of solar-powered desalination is the feasibility for inland
operation. Standard advantages also include no air pollution from desalination
power plants and no temperature increase of endangered natural water bodies
from power plant cooling-water discharge. Another important advantage is the
production of sea salt for industrial and other uses. Currently, 50% of the
world's sea salt production still relies on fossil energy sources.
Alternatives to desalination
Increased water conservation and efficiency remain the
most cost-effective priorities in areas of the world where there is a large
potential to improve the efficiency of water use practices. Wastewater
reclamation for irrigation and industrial use provides multiple benefits over
desalination. Urban runoff and storm water capture also provide benefits in
treating, restoring and recharging groundwater.
A proposed alternative to
desalination in the American Southwest is the commercial importation of bulk
water from water-rich areas either by very large
crude carriers converted to water carriers, or via pipelines. The idea is
politically unpopular in Canada, where governments imposed trade barriers to
bulk water exports as a result of a claim filed in 1999 under Chapter 11 of the
North American Free Trade Agreement
(NAFTA) by Sun Belt Water Inc., a company established in
1990 in Santa Barbara, California, to address pressing local needs due to a severe
drought in that area.
Experimental techniques and
other developments
Many desalination techniques have
been researched, with varying degrees of success.
Desalination powered by waste
heat
Diesel
generators are commonly used to provide electricity in remote areas. They
typically produce about 40%-50% of the energy as low-grade heat which leaves
the engine via the exhaust. By connecting a membrane distillation system to the diesel
engine exhaust it is possible to use this low-grade heat which is currently
wasted. Furthermore, the membrane distillation system actively cools
the diesel generator, improving its efficiency and
hence increasing its electricity output. This results in an energy-neutral
desalination solution. An example of such a desalination plant was commissioned
by Dutch company Aquaver
in March 2014 in the island of Gulhi, Maldives.
Low-temperature thermal
desalination
Originally stemming from ocean thermal energy conversion
research, low-temperature thermal desalination
(LTTD) takes advantage of water boiling at low pressures, potentially even at ambient temperature. The system uses vacuum
pumps to create a low-pressure, low-temperature environment in which water
boils at a temperature gradient of 8–10 °C (46–50 °F) between two
volumes of water. Cooling ocean water is supplied from depths of up to
600 m (2,000 ft). This cold water is pumped through coils to condense
the water vapor. The resulting condensate is purified water. LTTD may also take
advantage of the temperature gradient available at power plants, where large
quantities of warm wastewater are discharged from the plant, reducing the
energy input needed to create a temperature gradient.
Experiments were conducted in the
US and Japan to test the approach. In Japan, a spray-flash evaporation system
was tested by Saga University. In Hawaii, the National Energy Laboratory tested
an open-cycle OTEC plant with fresh water and power production using a
temperature difference of 20 C° between surface water and water at a depth of
around 500 m (1,600 ft). LTTD was studied by India's National
Institute of Ocean Technology (NIOT) from 2004. Their first LTTD plant opened
in 2005 at Kavaratti in the Lakshadweep islands. The plant's capacity is
100,000 L (22,000 imp gal; 26,000 US gal)/day, at a
capital cost of INR 50 million (€922,000). The plant uses deep water at a
temperature of 7 to 15 °C (45 to 59 °F).In 2007, NIOT opened an
experimental, floating LTTD plant off the coast of Chennai, with a
capacity of 1,000,000 L (220,000 imp gal;
260,000 US gal)/day. A smaller plant was established in 2009 at the
North Chennai Thermal Power Station to prove the LTTD application where power
plant cooling water is available.
Thermoionic process
In October 2009, Saltworks
Technologies, a Canadian firm, announced a process that uses solar or other
thermal heat to drive an ionic
current that removes all sodium and chlorine ions from the water using ion-exchange membranes.
Desalination through
evaporation and condensation for crops
The Seawater greenhouse uses natural evaporation
and condensation processes inside a greenhouse
powered by solar energy to grow crops in arid coastal land.
Other approaches
One such process was
commercialized by Modern Water PLC using forward
osmosis, with a number of plants reported to be in operation.
The US government is working to
develop practical solar desalination.
The Passarell process uses reduced
atmospheric pressure rather than heat to drive evaporative desalination. The
pure water vapor generated by distillation is then compressed and condensed
using an advanced compressor. The compression process improves distillation
efficiency by creating the reduced pressure in the evaporation chamber. The
compressor centrifuges
the pure water vapor after it is drawn through a demister (removing residual
impurities) causing it to compress against tubes in the collection chamber. The
compression of the vapor causes its temperature to increase. The heat generated
is transferred to the input water falling in the tubes, causing the water in
the tubes to vaporize. Water vapor condenses on the outside of the tubes as
product water. By combining several physical processes, Passarell enables most
of the system's energy to be recycled through its subprocesses, namely
evaporation, demisting, vapor compression, condensation, and water movement
within the system.
Geothermal energy can drive
desalination. In most locations, geothermal desalination beats using scarce
groundwater or surface water, environmentally and economically.
Nanotube
membranes may prove to be effective for water filtration and desalination
processes that would require substantially less energy than reverse osmosis.
Hermetic, sulphonated
nano-composite membranes have shown to be capable of cleaning most all forms of
contaminated water to the 'parts per billion' level. These nano-materials,
using a non-reverse osmosis process, have little or no susceptibility to high
salt concentration levels.
Biomimetic membranes are another approach.
On June 23, 2008, Siemens Water
Technologies announced technology based on applying electric fields that
purports to desalinate one cubic meter of water while using only 1.5 kWh of
energy. If accurate, this process would consume only one-half the energy of
other processes.Currently, Oasis Water, which developed the technology, still
uses three times that much energy. Researchers at the university of Texas at
Austin and the University of Marburg are developing more efficient methods of
electrochemically mediated seawater desalination.
Freeze-thaw desalination uses
freezing to remove fresh water from frozen seawater.
Membraneless desalination at
ambient temperature and pressure using electrokinetic shocks waves has been
demonstrated. In this technique anions and cations in salt water are exchanged
for carbonate anions and calcium cations respectively using electrokinetic
shockwaves. Calcium and carbonate ions then react to form calcium
carbonate, which then precipitates leaving behind fresh water. Theoretical
energy efficiency of this method is on par with electrodialysis
and reverse osmosis.
In 2009, Lux Research estimated
the worldwide desalinated water supply will triple between 2008 and 2020.
Existing facilities and
facilities under construction
Estimates vary widely between 15,000-20,000
desalination plants producing more than 20,000 m3/day. Micro
desalination plants are in operation nearly every where there is a natural gas
or fracking
facility in the United States.
Algeria
Believed to have at least 15
desalination plants in operation
- Arzew IWPP Power & Desalination Plant, Arzew
- Cap Djinet Seawater Reverse Osmosis(SWRO) 100,000 m3/d
- Tlemcen Souk Tleta 200,000 m3/day
- Tlemcen Hounaine 200,000 m3/day
- Beni Saf 200,000 m3/day
- Tenes 200,000 m3/day
- Fouka 120,000 m3/day
- Skikda 100,000 m3/day
- Hamma Seawater Desalination Plant 200,000 m3/day built by GE
- Mostaganem, once considered the largest in Africa
- Magtaa Reverse Osmosis (RO) Desalination Plant, Oran, Algeria
Aruba
The island of Aruba has a large
(world's largest at the time of its inauguration) desalination plant, with a
total installed capacity of 11.1 million US gallons (42,000 m3)
per day.
Australia
The Millenium Drought (1997-2009) led to a
water supply crisis across much of the country. A combination of increased
water usage and lower rainfall/drought in Australia caused state governments to
turn to desalination. As a result
several large-scale desalination plants were constructed .
Large-scale seawater reverse
osmosis plants (SWRO) now contribute to the domestic water supplies of several
major Australian cities including Adelaide, Melbourne, Sydney, Perth and the
Gold Coast. While desalination helped secure water supplies, it is energy
intensive (~$140/ML) and has a high carbon footprint due to Australia's
coal-based energy supply. In 2010, a Seawater Greenhouse went into operation in Port
Augusta.
A growing number of smaller scale
SWRO plants are used by the oil and gas industry (both on and offshore), by
mining companies to supply slurry pipelines for the transport of ore and on
offshore islands to supply tourists and residents.
Bahrain
Completed in 2000, the Al Hidd
Desalination Plant on Muharraq island employed a multistage flash process, and
produces 272,760 m3 (9,632,000 cu ft) per day. The Al
Hidd distillate forwarding station provides 410 million liters of distillate
water storage in a series of 45-million-liter steel tanks. A 135-million-liters/day
forwarding pumping station sends flows to the Hidd, Muharraq, Hoora, Sanabis,
and Seef blending stations, and which has an option for gravity supply for low
flows to blending pumps and pumps which forward to Janusan, Budiya and Saar.
Upon completion of the third
construction phase, the Durrat Al Bahrain seawater reverse osmosis (SWRO)
desalination plant was planned to have a capacity of 36,000 cubic meters of
potable water per day to serve the irrigation needs of the Durrat Al Bahrain
development. The Bahrain-based utility company, Energy Central Co contracted to
design, build and operate the plant.
Chile
- Copiapó Desalination Plant
China
China operates the Beijing
Desalination Plant in Tianjin, a combination desalination and coal-fired power
plant designed to alleviate Tianjin's critical water shortage. Though the
facility has the capacity to produce 200,000 cubic meters of potable water per
day, it has never operated at more than one-quarter capacity due to
difficulties with local utility companies and an inadequate local
infrastructure.
Cyprus
A plant operates in Cyprus near
the town of Larnaca.The
Dhekelia Desalination Plant uses the reverse osmosis system.
Egypt
- Dahab RO Desalination Plants Dahab 3,600 m3/day completed 1999
- Hurgada and Sharm El-Sheikh Power and Desalination Plants
- Oyoun Moussa Power and Desalination
- Zaafarana Power and Desalination
Germany
Fresh water on the island of Helgoland is
supplied by two reverse osmosis desalination plants.
Gibraltar
Fresh water in Gibraltar is
supplied by a number of reverse osmosis and multistage flash desalination
plants. A demonstration forward osmosis desalination plant also operates
there.
Grand Cayman
- West Bay, West Bay, Grand Cayman
- Abel Castillo Water Works, Governor's Harbour, Grand Cayman
- Britannia, Seven Mile Beach, Grand Cayman
Hong Kong
The HK Water Supplies Department
had pilot desalination plants in Tuen Mun and Ap Lei Chau using reverse osmosis
technology. The production cost was at HK$7.8 to HK$8.4 /m3. In
2011, the government announced a feasibility study whether to build a desalination
plant in Tseung Kwan O.Hong Kong used to have a desalination plant in Lok On Pai.
India
The largest desalination plant in South Asia
is the Minjur Desalination Plant near Chennai in India, which produces
36.5 million cubic meters of water per year.
A second plant at Nemmeli, Chennai is
expected to reach full capacity of 100 million litres of sea-water per day in
March 2013.
Iran
An assumption is that around
400,000 m3/d of historic and newly installed capacity is operational
in Iran. In terms of technology, Iran's existing desalination plants use a mix
of thermal processes and RO. MSF is the most widely used thermal technology
although MED and vapour compression (VC) also feature.
Israel
Israel Desalination Enterprises'
Sorek Desalination Plant in Palmachim provides up to 26,000 m³ of potable water
per hour (2.300 m³ p.a.). At full capacity, it is the largest desalination
plant of its kind in the world. Once unthinkable, given Israels history of
drought and lack of available fresh water resource, with desalination, Israel
can now actually produce a surplus of fresh water
The Hadera seawater
reverse osmosis (SWRO) desalination plant in Israel is the
largest of its kind in the world. The project was developed as a build–operate–transfer by a consortium of two
Israeli companies: Shikun and Binui, and IDE Technologies.
By 2014, Israel's desalination
programs provided roughly 35% of Israel's drinking water and it is expected to
supply 40% by 2015 and 70% by 2050.
|
Existing Israeli water
desalination facilities
|
||||
|
Location
|
Opened
|
Capacity
(million m3/year) |
Cost of water
(per m3) |
Notes
|
|
August 2005
|
120 (as of 2010)
|
NIS 2.60
|
||
|
May 2007
|
45
|
NIS 2.90
|
||
|
December 2009
|
127
|
NIS 2.60
|
||
|
2013
|
150 (expansion up to 300
approved)
|
NIS 2.01 – 2.19
|
||
|
Israeli water desalination
facilities under construction
|
||||
|
Location
|
Opening
|
Capacity
(million m3/year) |
Cost of water
(per m3) |
Notes
|
|
September 2014
|
100 (expansion up to 150
possible)
|
NIS 2.40
|
||
Malta
Ghar Lapsi II 50,000 m3/day
Maldives
Maldives is a
nation of small islands. Some depend on desalination as a source of water.
Oman
A pilot seawater greenhouse was
built in 2004 near Muscat, in collaboration with Sultan Qaboos University, providing a
sustainable horticultural sector on the Batinah
coast.
- Ghubrah Power & Desalination Plant, Muscat
- Sohar Power & Desalination Plant, Sohar
- Sur R.O. Desalination Plant 80,000 m3/day 2009
- Qarn Alam 1000 m3/day
- Wilayat Diba 2000 m3/day
There are at least two forward
osmosis plants operating in Oman
- Al Najdah 200 m3/day (built by Modern Water)
- Al Khaluf
Saudi Arabia
The Saline Water
Conversion Corporation of Saudi Arabia provides 50% of the municipal water
in the Kingdom, operates a number of desalination plants, and has contracted
$1.892 billion to a Japanese-South Korean consortium to build a new facility
capable of producing a billion liters per day, opening at the end of 2013. They
currently operate 32 plants in the Kingdom; one example at Shoaiba cost $1.06
billion and produces 450 million liters per day.
- Corniche RO Plant (Crop) (operated by SAWACO)
- Jubail 800,000 m3/day
- North Obhor Plant (operated by SAWACO)
- Rabigh 7,000 m3/day (operated by wetico)
- planned for completion 2018 Rabigh II 600,000 m3/day (under construction Saline Water Conversion Corporation)
- Shuaibah III 150,000 m3/day (operated by Doosan)
- South Jeddah Corniche Plant (SOJECO) (operated by SAWACO)
- Yanbu Multi Effect Distillation (MED), Saudi Arabia 68,190 m3/day
Spain
Lanzarote is
the easternmost of the autonomous Canary Islands. It is the driest of the
islands, of volcanic origin and has limited water supplies. A private,
commercial desalination plant was installed in 1964. This served the whole
island and enabled the tourism industry. In 1974, the venture was injected with
investments from local and municipal governments and a larger infrastructure
was put in place. In 1989, the Lanzarote Island Waters Consortium (INALSA) was
formed.
A prototype seawater greenhouse was constructed in Tenerife
in 1992.
- Alicante II 65,000 m3/day (operator Inima)
- Tordera 60,000 m3/day
- Barcelona 200,000 m3/day (operator Degremont) El Prat, near Barcelona, a desalination plant completed in 2009 was meant to provide water to the Barcelona metropolitan area, especially during the periodic severe droughts that put the available amounts of drinking water under serious stress.
- Oropesa 50,000 m3/day (operator TECNICAS REUNIDAS)
- Moncofa 60,000 m3/day (operator Inima)
- Marina Baja - Mutxamel 50,000 m3/day (operator Degremont)
- Torrevieja 240,000 m3/day (operator ACCIONA)
- Cartagena Escombreras 63,000 m3/day (operator COBRA | TEDAGUA)
- Edam Ibiza + Edam San Antonio 25,000 m3/day (operator Ibiza - Portmany)
- Mazarron 36,000 m3/day (operator TEDAGUA)
- Bajo Almanzora 65,000 m3/day
South Africa
Mossel Bay 15,000 m3/day
Transnet Saldanha 2,400 m3/day
Knysna 2,000 m3/day
Plettenberg Bay 2,000 m3/day
Bushman's River Mouth 1,800 m3/day
Lambert's Bay 1,700 m3/day
Cannon Rocks 750 m3/day
Transnet Saldanha 2,400 m3/day
Knysna 2,000 m3/day
Plettenberg Bay 2,000 m3/day
Bushman's River Mouth 1,800 m3/day
Lambert's Bay 1,700 m3/day
Cannon Rocks 750 m3/day
United Arab Emirates
The Jebel Ali desalination plant
in Dubai, a dual-purpose facility, uses multistage flash distillation and is
capable of producing 300 million cubic meters of water per year.
- Kalba 15,000 m3/day built for Sharjah Electricity and Water Authority completed 2010(operator CH2MHill)
- Khor Fakkan 22,500 m3/day (operator CH2MHill)
- Ghalilah RAK 68,000 m3/day (operator AQUATECH)
- Hamriyah 90,000 m3/day (operator AQUA Engineering)
- Taweelah A1 Power and Desalination Plant has an output 385,000,000 L (85,000,000 imp gal; 102,000,000 US gal) per day of clean water.
- Al Zawrah 27,000 m3/day (operator Aqua Engineering)
- Layyah I 22,500 m3/day (operator CH2MHill)
- Emayil & Saydiat Island ~20,000 m3/day (operator Aqua EPC)
- Umm Al Nar Desalination Plant has an output of 394,000,000 L (87,000,000 imp gal; 104,000,000 US gal)/day.
- Al Yasat Al Soghrih Island 2M gallons per day (GPD) or 9,000 m3/day
- Fujairah F2 is to be completed by July 2010 will have a water production capacity of 492,000,000 L (108,000,000 imp gal; 130,000,000 US gal) per day.
- A seawater greenhouse was constructed on Al-Aryam Island, Abu Dhabi, United Arab Emirates in 2000.
United Kingdom
The first large-scale plant in the
United
Kingdom, the Thames Water Desalination Plant,
was built in Beckton,
east London for Thames Water by Acciona Agua.
Jersey
The desalination plant located
near La Rosière, Corbiere, Jersey, is operated by Jersey Water. Built in 1970 in
an abandoned quarry, it was the first in the British Isles.
The original plant used a multistage flash (MSF) distillation
process, whereby seawater was boiled under vacuum, evaporated and condensed
into a freshwater distillate. In 1997, the MSF plant reached the end of its
operational life and was replaced with a modern reverse osmosis plant.
Its maximum power demand is
1,750 kW, and the output capacity is 6,000 cubic meters per day. Specific
energy consumption is 6.8 kWh/m3.
United States
Texas
There are a dozen different
desalination projects in the State
of Texas, both for desalinating groundwater and desalinating seawater from
the Gulf
of Mexico.
- El Paso: Brackish groundwater has been treated at the El Paso, Texas, plant since around 2004. It produces 27,500,000 US gallons (104,000,000 l; 22,900,000 imp gal) of fresh water daily (about 25% of total freshwater deliveries) by reverse osmosis. The plant's water cost — largely representing the cost of energy — is about 2.1 times higher than ordinary groundwater production. On average, the plant produces 3.5 million gallons per day (about 11 acre-feet) at an average production cost of $489 per acre-foot.
California
California has 17 desalination
plants in the works, either partially constructed or through exploration and
planning phases. The list of locations includes Bay Point, in the Delta,
Redwood City, seven in the Santa Cruz / Monterey Bay, Cambria, Oceaneo, Redondo
Beach, Huntington Beach, Dana Point, Camp Pendleton, Oceanside and Carlsbad.
- Carlsbad: The United States' largest desalination plant is being constructed by Poseidon Resources and is expected to go online 2016. It is expected to produce 50 million gallons a day to 110,000 customers in San Diego County at an estimated cost of $1b.
- Concord: Planned to open in 2020, producing 20 million gallons a day.
- Monterey County: Sand City, two miles north of Monterey, with a population of 334, is the only city in California completely supplied with water from a desalination plant.
- Santa Barbara: The Charles Meyer Desalination Facility was constructed in Santa Barbara, California, in 1991–92 as a temporary emergency water supply in response to severe drought. While it has a high operating cost, the facility only needs to operate infrequently, allowing Santa Barbara to use its other supplies more extensively.
Florida
Florida has five
water management districts. These are (north to south):
- Northwest Florida WMD
- Suwannee River WMD
- Saint Johns WMD Provides map of districts. Serves Jacksonville to Vero Beach.
- Southwest Florida WMD
- South Florida WMD Serves Orlando.
The St. Johns River Water
Management District (SJRWMD) provides a presentation (PDF) of the desalanation
process.
As of 2012, South Florida has 33
brackish and two seawater desalination plants operating with seven brackish
water plants under construction. The brackish and seawater desalination plants
have the capacity to produce 245 million gallons of potable water per day.
- Tampa Bay: The Tampa Bay Water desalination project near Tampa, Florida, was originally a private venture led by Poseidon Resources, but it was delayed by the bankruptcy of Poseidon Resources' successive partners in the venture, Stone & Webster, then Covanta (formerly Ogden) and its principal subcontractor, Hydranautics. Stone & Webster declared bankruptcy June 2000. Covanta and Hydranautics joined in 2001, but Covanta failed to complete the construction bonding, and then the Tampa Bay Water agency purchased the project on May 15, 2002, underwriting the project. Tampa Bay Water then contracted with Covanta Tampa Construction, which produced a project that failed performance tests. After its parent went bankrupt, Covanta also filed for bankruptcy prior to performing renovations that would have satisfied contractual agreements. This resulted in nearly six months of litigation. In 2004, Tampa Bay Water hired a renovation team, American Water/Acciona Aqua, to bring the plant to its original, anticipated design. The plant was deemed fully operational in 2007, and is designed to run at a maximum capacity of 25 million US gallons (95,000 m3) per day. The plant can now produce up to 25 million US gallons (95,000 m3) per day when needed.
Arizona
- Yuma: The desalination plant in Yuma, Arizona, was constructed under authority of the Federal Colorado River Basin Salinity Control Act of 1974 to treat saline agricultural return flows from the Wellton-Mohawk Irrigation and Drainage District into the Colorado River. The treated water is intended for inclusion in water deliveries to Mexico, thereby keeping a like amount of freshwater in Lake Mead, Arizona and Nevada. Construction of the plant was completed in 1992, and it has operated on two occasions since then. The plant has been maintained, but largely not operated due to sufficient freshwater supplies from the upper Colorado River. An agreement was reached in April 2010 between the Southern Nevada Water Authority, the Metropolitan Water District of Southern California, the Central Arizona Project, and the U.S. Bureau of Reclamation to underwrite the cost of running the plant in a year-long pilot project.
Trinidad and Tobago
The Republic of Trinidad and Tobago
uses desalination to open up more of the island's water supply for drinking
purposes. The country's desalination plant, opened in March 2003, is considered
to be the first of its kind. It was the largest desalination facility in the
Americas, and it processes 28,800,000 US gallons (109,000 m3)
of water a day at the price of $2.67 per 1,000 US gallons (3.8 m3).
This plant will be located at
Trinidad's Point Lisas Industrial Estate, a park of more than 12
companies in various manufacturing and processing functions, and it will allow
for easy access to water for both factories and residents in the country.
In nature
Evaporation of water over the
oceans in the water cycle is a natural desalination process.
The formation of sea ice is also
a process of desalination. Salt is expelled from seawater when it freezes.
Although some brine
is trapped, the overall salinity of sea ice is much lower than seawater.
Seabirds distill seawater using countercurrent exchange in a gland with a rete
mirabile. The gland secretes highly concentrated brine stored near the
nostrils above the beak. The bird then "sneezes" the brine out. As
freshwater is not available in their environments, some seabirds, such as pelicans, petrels, albatrosses, gulls and terns, possess this
gland, which allows them to drink the salty water from their environments while
they are hundreds miles away from land.
Mangrove trees
grow in seawater; they secrete salt by trapping it into parts of the root,
which are then eaten by animals (usually crabs). Additional salt removal is
done by storing it in leaves which then fall off. Some types of mangroves have
glands on their leaves, which work in a similar way to the seabird desalination
gland. Salt is extracted to the leaf exterior as small crystals, which
then fall off the leaf.
Willow trees and reeds
are known to absorb salt and other contaminants, effectively desalinating the
water. This is used in artificial constructed wetlands, for treating sewage.
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