This article needs additional citations for verification .(May 2016) |
Desalination plant | |
---|---|
Location | Lonsdale, South Australia |
Daily capacity | 300 megalitres per day, but has been operating (since 2012) at 10% of its capacity. [1] |
Annual capacity | 100 gigalitres per annum |
Cost | A$1.83 billion |
Energy generation offset | Renewable (TBA) |
Technology | Reverse Osmosis |
Percent of water supply | 50% of Adelaide |
Completion date | December 2012 |
Website | www.sawater.com.au |
The Adelaide Desalination plant (ADP), formerly known as the Port Stanvac Desalination Plant, is a sea water reverse osmosis desalination plant located in Lonsdale, South Australia which has the capacity to provide the city of Adelaide with up to 50% of its drinking water needs.
In September 2007, South Australian Premier Mike Rann announced that the State Government would fund and build a desalination plant to ensure Adelaide's water supply against drought. [2] The plant was financed and built by SA Water, a state-owned corporation.
The plant was initially planned to have a capacity of 50 gigalitres (GL) of water per year but was later doubled in capacity to 100 GL/year with the assistance of funding from the Australian Government. The expanded capacity represents around 50% of Adelaide's domestic water supply.
The project has engaged professional political lobbyists, including Michael O'Reilly. [3]
The plant was completed on time and within the original budget ($1.83 billion).
Stage one of the plant commenced operations in October 2011, and stage two commenced in July 2012. [4] [5] The plant was officially opened on 26 March 2013. [6]
The Adelaide Desalination Project is the largest infrastructure project that the State of South Australia has funded, owns, and has completed successfully.[ citation needed ]
Since 2012, the plant has been operating at 10% of its capacity to keep it functioning. In 2017, it produced 2% of the state's water supply. [1]
South Australia, as the "driest state in the driest (inhabited) continent", [7] has experienced severe water shortages during periods of drought. As drought conditions worsened during 2006-7, reduced inflows into the River Murray lead to the introduction of progressively harsher water restrictions and the future of Adelaide's water supply came to the fore as a political issue. [8]
In light of the drought, South Australian Premier Mike Rann announced on 11 September 2007 that the State Government would fund and build a desalination plant to guarantee Adelaide's water supply. He said the plant would provide an insurance policy against future droughts and cost more than $1.4 billion. [2]
In the leadup to the November 2007 federal election campaign Prime Minister John Howard promised that, if re-elected, his Coalition government would contribute towards the capital cost of a desalination plant to reduce the city's dependence on the River Murray. Then Opposition Leader Kevin Rudd made similar pledges. [9]
The site for the main desalination plant was purchased by SA Water from ExxonMobil in December 2008. [10] Construction commenced in March 2009.
The plant is located on the eastern shore of Gulf St Vincent just north of ExxonMobil's disused Port Stanvac Oil Refinery. It lies within the industrial suburb of Lonsdale within the local government area of the City of Onkaparinga. The residential area just north of the plant lies within the suburb of Hallett Cove (part of the City of Marion).
The plant was originally intended to be capable of producing 50 GL per year and projected to cost almost $1.4 billion.
During late 2008 and early 2009, the South Australian Government was actively considering doubling the capacity to 100 GL/year at an incremental cost of around $450 million. It sought funding from the Australian Government for the full cost of this expansion. [11]
In May 2009 the Australian Government, under Prime Minister Rudd, announced a grant of $100 million to support the initial stage of the project under the National Urban Water and Desalination Plan. [11] This announcement fulfilled Rudd's commitment during the 2007 election campaign.[ citation needed ]
As part of this announcement, the Australian Government also committed a further $228 million for the expansion to 100 GL/year. The South Australian Government subsequently committed to the expansion in June 2009.
The final capital cost of A$1.83 billion for the Adelaide Desalination Project included:
In February 2008, the State Government appointed SA Water as the lead agency responsible for the delivery of the project and also appointed a steering committee of chief executives of key agencies to provide strategic oversight and review of all key decisions prior to approval by the SA Water Board and or the Government and Parliament; this steering committee had an independent chair (Mr Kevin Osborn).
In February 2008, the SA government approved an initial funding of $9.5M for the design, construction, operation and maintenance of a small Temporary Pilot Desalination Plant with a capacity of 100,000 litres per day. [12] Construction of this temporary pilot plant commenced in June 2008 and was completed on 4 August 2008. [13] The pilot plant was operated for two years through to October 2010 and provided valuable information to further optimise the design of the main plant.
The procurement process for the construction of the plant was:
The preferred respondent was a consortium (AdelaideAqua D&C) consisting of McConnell Dowell, Abigroup and Acciona. A 20-year operations and maintenance contract was awarded to AdelaideAqua Pty Ltd, a consortium comprising Acciona and Trility. [14]
Completion of the initial 50 GL/year stage was initially targeted for the end of June 2012. Subsequently, with deteriorating drought in South Australia, the project was fast-tracked to compress the planning and procurement program and target early 'first water' (or 10% of plant output) up to 12 months earlier, followed by progressive completion of the remaining 50 GL per year plant.
The first stage of the project began producing drinking water in October 2011, and the expanded plant began producing drinking water in July 2012. [4] [5]
The plant was officially opened on 26 March 2013. [6]
The Adelaide Desalination Plant removes salt from, or desalinates, seawater using the process of reverse osmosis. This involves three main stages:
The health and safety of all workers and stakeholders associated with the project was a key concern for SA Water and the AdelaideAqua consortium.[ citation needed ]
In July 2010, worker Brett Fritsch was killed by a steel beam which fell from a soft sling at the construction site. Following a Safework SA investigation, the rigging company Ferro Con SA and its director Paolo Maione were found to be responsible and each was fined $200,000 by the Industrial Court. [15] No charges were laid on SA Water or the principal contractor, AdelaideAqua.
The Adelaide Desalination Project has been internationally recognised by professional organisations, industry bodies and independent judges. Awards include:
The SA and Australian governments agreed to make all power used by the plant renewable.
The plant uses 3.47 to 3.70 kilowatt-hours of electricity per kilolitre of water produced. [16]
The plant sources all its electricity from 100% GreenPower accredited Renewable Energy sources from within South Australia. The plant sources its electricity from renewable energy sources provided by AGL Energy under a 20-year contract at an annual cost initially estimated at over $75 million per year (for the first 50 GL plant). [17] Energy supply cost is part of the overall operating cost of the facility which was confirmed by SA Water in December 2010 at $130 million per year (for double the capacity or 100 GL plant). SA Water advised that the $130 million per year would result in one of the lowest operating cost per unit of desalinated drinking water of any desalination plant in Australia. This was possible because of energy efficient technologies and innovations throughout the plant.
The plant's buildings have been designed to maximise natural light during the day and a selection of high thermal materials (e.g. solid precast concrete walls and insulation) to improve thermal properties, thereby minimising energy consumption. More specifically, solar photovoltaic cells have been placed on the reverse osmosis buildings for localised power generation. Each reverse osmosis building has an approximately 100 kW solar cell array providing a site capacity of approximately 200 kW at peak sun hours. The high pressure pumps feeding the reverse-osmosis membranes are the largest consumers of energy in the plant. Energy recovery devices are installed to harness the pressure in the saline concentrate stream and use it to pressurise some of the feed water. As a result, the high pressure pumps are only needed to deliver half of the water feeding the reverse osmosis system, reducing energy consumption in the plant by up to 40 per cent. Likewise, two turbine generators in the outfall tunnel take advantage of the plant elevation 50 metres above sea level. This mini-hydroelectric system is capable of producing 1,290 kW of renewable electricity which is fed back into the plant, reducing energy consumption by approximately 2.5%.
The lack of tidal movement for up to 2–3 days during dodge tides, which occur twice a month in Gulf St Vincent, reduces mixing of the water column. This raised concerns during the planning phase of the project about the potential effects of the brine discharge on benthic flora and fauna. [18] [19]
Dodge tides and other local conditions were taken into account in the design of the outfall system. Discharge to the sea occurs via a 1,080 m undersea tunnel, with dispersal through one of 6 specially designed diffusers. Each diffuser has a head consisting of four duck bill valves that assist in maintaining high discharge velocity for optimum mixing, independent of plant operating conditions.[ citation needed ]
Marine monitoring buoys placed at 100-metre radius from the outfall structures allow real time data monitoring via the plant control system, to assess performance against Environment Protection Agency discharge licence conditions. Monitoring of the surrounding marine environment started before construction of the plant began and will continue into the future to ensure no adverse environmental impact.[ citation needed ]
The Adelaide Desalination Plant has been controversial as the high cost of construction has contributed to water price increases, even when the plant is not in use.[ citation needed ] While the plant was used quite intensively between 2013 and 2015, its utilisation has reduced due to greater water availability in metropolitan reservoirs and from the Murray River. This is shown in the table below, which demonstrates that the plant produced around 8 GL in the year from November 2015 to October 2016, compared to over 100 GL between December 2012 and October 2015.
Date | Water produced since plant start |
---|---|
December 2012 | 17 GL [5] |
20 October 2015 | 126.3 GL [20] |
End October 2016 | 134 GL [21] |
As of January 2016, the desalination plant was continuing to run at around 10 per cent capacity, despite having sufficient reservoir capacity and water allocation from the Murray River. [22] [1]
During the course of determining water prices for South Australia, the Essential Services Commission of South Australia (ESCOSA) commissioned expert engineering advice from to assess SA Water's proposal to operate the desalination plant at minimum capacity, rather than place it into 'cold standby'. Based on this advice, ESCOSA allowed for SA Water to recover $4.1 million per year to cover the cost of operating the plant in minimum operation mode (approximately 8 GL/year), noting that doing so:
In November 2019 an agreement was reached between the Australian Federal Government and the South Australian government to significantly increase production of water to supply the Adelaide metropolitan area. The agreement was reached to allow farmers affected by drought to access more water from the Murray River.
Since much of Adelaide's household water supply is sourced from the River Murray, allowing the desalination plant to produce the city's water frees allocation from the river to be used upstream. The river water saved will then be allocated to drought-affected farmers along the river's irrigation area with farmers in this area able to bid for the water at a discounted rate. [24]
The development of a solar farm on 14 hectares of land adjacent to the desalination plant is expected to significantly reduce the plant's electricity bills. [25]
Desalination is a process that takes away mineral components from saline water. More generally, desalination refers to the removal of salts and minerals from a target substance, as in soil desalination, which is an issue for agriculture. Saltwater is desalinated to produce water suitable for human consumption or irrigation. The by-product of the desalination process is brine. Desalination is used on many seagoing ships and submarines. Most of the modern interest in desalination is focused on cost-effective provision of fresh water for human use. Along with recycled wastewater, it is one of the few rainfall-independent water resources.
A reverse osmosis plant is a manufacturing plant where the process of reverse osmosis takes place. Reverse osmosis is a common process to purify or desalinate contaminated water by forcing water through a membrane. Water produced by reverse osmosis may be used for a variety of purposes, including desalination, wastewater treatment, concentration of contaminants, and the reclamation of dissolved minerals. An average modern reverse osmosis plant needs six kilowatt-hours of electricity to desalinate one cubic metre of water. The process also results in an amount of salty briny waste. The challenge for these plants is to find ways to reduce energy consumption, use sustainable energy sources, improve the process of desalination and to innovate in the area of waste management to deal with the waste. Self-contained water treatment plants using reverse osmosis, called reverse osmosis water purification units, are normally used in a military context.
A solar-powered desalination unit produces potable water from saline water through direct or indirect methods of desalination powered by sunlight. Solar energy is the most promising renewable energy source due to its ability to drive the more popular thermal desalination systems directly through solar collectors and to drive physical and chemical desalination systems indirectly through photovoltaic cells.
The Perth Seawater Desalination Plant, located in Naval Base, south of Perth, Western Australia, turns seawater from Cockburn Sound into nearly 140 megalitres of drinking water per day, supplying the Perth metropolitan area.
The Thames Gateway Water Treatment Works or Beckton Desalination Plant is a desalination plant in Beckton, London, adjacent to Beckton Sewage Treatment Works. The plant takes brackish water from the River Thames and converts it into drinkable water through a reverse osmosis process. The first of its kind in the UK, it was built for Thames Water by a consortium of Interserve, Atkins Water and Acciona Agua. It was opened by Prince Philip, Duke of Edinburgh, on 2 June 2010. It was planned to provide up to 150 million litres of drinking water each day – enough for 900,000 Londoners. – but by 2023 had only operated on three occasions, and at two-thirds of its planned capacity.
CETO is a wave-energy technology that converts kinetic energy from ocean swell into electrical power and directly desalinates freshwater through reverse osmosis. The technology was developed and tested onshore and offshore in Fremantle, Western Australia. In early 2015 a CETO 5 production installation was commissioned and connected to the grid. As of January 2016 all the electricity generated is being purchased to contribute towards the power requirements of HMAS Stirling naval base at Garden Island, Western Australia. Some of the energy will also be used directly to desalinate water.
The Point Paterson Desalination Plant was a planned municipal-scale solar-powered desalination plant with land-based brine disposal near Point Paterson in the locality of Winninowie in the Australian state of South Australia about 13 kilometres (8.1 mi) south of the city centre of Port Augusta. The Point Paterson Project was to utilise a salt flat owned by a salt company but which has not been in use for solar salt production for decades. The plant would have integrated renewable energy and desalination technologies to create environmentally-friendly electricity and water. In particular, the project would have significantly reduced the usual greenhouse impacts associated with grid electricity demand for desalination. The project had attracted the interest of internationally renowned climatologist, the late Professor Stephen Schneider, who joined the Board of Acquasol in 2006.
The Victorian Desalination Plant is a water desalination plant in Dalyston, on the Bass Coast in southern Victoria, Australia. The project was announced by Premier Steve Bracks in June 2007, at the height of the millennium drought when Melbourne's water storage levels dropped to 28.4%, a drop of more than 20% from the previous year. Increased winter-spring rains after mid-2007 took water storage levels above 40%, but it was not until 2011 that storages returned to pre-2006 levels.
The Sydney Desalination Plant also known as the Kurnell Desalination Plant is a potable drinking water desalination plant that forms part of the water supply system of Greater Metropolitan Sydney. The plant is located in the Kurnell industrial estate, in Southern Sydney in the Australian state of New South Wales. The plant uses reverse osmosis filtration membranes to remove salt from seawater and is powered using renewable energy, supplied to the national power grid from the Infigen Energy–owned Capital Wind Farm located at Bungendore.
Fujairah F1 Independent Water and Power Plant or Fujairah F1 IWPP is an independent water and power plant (IWPP) at Qidfa', Fujairah in the United Arab Emirates. It is located next to the Fujairah F2 IWPP. It is 5 kilometres (3.1 mi) south of Khor Fakkan and 20 kilometres (12 mi) north of the city of Fujairah. When constructed, the Fujairah plant was the first hybrid plant in the Middle East, and the largest desalination hybrid plant in the world.
Water supply and sanitation in Israel are intricately linked to the historical development of Israel. Because rain falls only in the winter, and largely in the northern part of the country, irrigation and water engineering are considered vital to the country's economic survival and growth. Large scale projects to desalinate seawater, direct water from rivers and reservoirs in the north, make optimal use of groundwater, and reclaim flood overflow and sewage have been undertaken. Among them is the National Water Carrier, carrying water from the country's biggest freshwater lake, the Sea of Galilee, to the northern part of the Negev desert through channels, pipes and tunnels. Israel's water demand today outstrips available conventional water resources. Thus, in an average year, Israel relies for about half of its water supply on unconventional water resources, including reclaimed water and desalination. A particularly long drought in 1998–2002 had prompted the government to promote large-scale seawater desalination. In 2022, 85% of the country's drinkable water was produced through desalination of saltwater and brackish water.
As Australia's supply of freshwater is increasingly vulnerable to droughts, possibly as a result of climate change, there is an emphasis on water conservation and various regions have imposed restrictions on the use of water.
The 2000s drought in Australia, also known as the millennium drought is said by some to be the worst drought recorded since European settlement.
Australia is the driest habitable continent on Earth and its installed desalination capacity has been increasing. Until a few decades ago, Australia met its demands for water by drawing freshwater from dams and water catchments. As a result of the water supply crisis during the severe 1997–2009 drought, state governments began building desalination plants that purify seawater using reverse osmosis technology. Approximately one percent of the world's drinkable water originates from desalination plants.
The Whyalla Steelworks is a fully integrated steelworks and the only manufacturer of rail in Australia. Iron ore is mined in the Middleback Range to feed the steelworks, resulting in the distribution of finished steel products of over 90 different grades. It occupies a 1,000 ha site on the shore of False Bay, Spencer Gulf and is the largest employer in Whyalla, South Australia.
Chennai Metropolitan Water Supply and Sewerage Board, known shortly as CMWSSB, is a statutory board of Government of Tamil Nadu which provides water supply and sewage treatment to the city of Chennai and its metropolitan region.
The Minjur Desalination Plant is a reverse osmosis, water desalination plant at Kattupalli village, a northern suburb of Chennai, India, on the coast of the Bay of Bengal that supplies water to the city of Chennai. Built on a 60-acre site, it is the largest desalination plant in India. Construction works were carried out by the Indian company IVRCL and the Spanish company Abengoa, under the direction of the Project Manager Fernando Portillo Vallés and the Construction Manager Juan Ignacio Jiménez-Velasco, who returned to Europe after the inauguration of the plant to work on renewable energy projects. Originally scheduled to be operational by January 2009, the work on the plant was delayed due to Cyclone Nisha in October 2008, which damaged a portion of the completed marine works and destroyed the cofferdam meant for the installation of transition pipes. The trial runs were completed in June 2010 and the plant was opened in July 2010. Water from the plant will be utilised chiefly for industrial purposes such as the Ennore Port and North Chennai Thermal Power Station. However, during droughts, water from the plant will be supplied to the public, serving an estimated population of 1,000,000.
There are approximately 16,000 operational desalination plants, located across 177 countries, which generate an estimated 95 million m3/day of fresh water. Micro desalination plants operate near almost every natural gas or fracking facility in the United States. Furthermore, micro desalination facilities exist in textile, leather, food industries, etc.