Water supply and sanitation in Singapore

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Singapore: Water and Sanitation
Flag of Singapore.svg
Data
Access to an improved water source 100% [1]
Access to improved sanitation 100% [1]
Continuity of supply (%)100 [1]
Average urban water use (liter/capita/day)148 (2016) [2] [3]
Average urban domestic water and sewer tariff per m3US$2.00 (S$2.74, 2023, for a consumption of 10m3 per month) [4]
Share of household metering100%
Annual investment in water supply and sanitationUS$609 million (2010), or $117/capita/year [5]
FinancingSelf-financing through retained earnings, debt financing through bonds and project finance for desalination
Institutions
DecentralizationNo
National water and sanitation company Public Utilities Board (PUB)
Water and sanitation regulator Ministry of Sustainability and the Environment
Responsibility for policy setting Ministry of Sustainability and the Environment
Sector law
Number of urban service providers1

Water supply and sanitation in Singapore are intricately linked to the historical development of Singapore. It is characterised by a number of outstanding achievements in a challenging environment with geographical limitations. Access to water in Singapore is universal, affordable, efficient and of high quality. [6]

Contents

Innovative hydraulic engineering and integrated water management approaches such as the reuse of reclaimed water, the establishment of protected areas in urban rainwater catchments and the use of estuaries as freshwater reservoirs have been introduced along with seawater desalination in order to reduce the country's dependence on untreated imported water. [7]

As a result of such efforts, Singapore has achieved self-sufficiency with its water supply since the mid-2010s. [8] Examples include its "Four National Taps" for its water supply. [9] Five desalination plants [lower-alpha 1] have been opened throughout the country since 2003, which in total are able to produce a maximum capacity of approximately 195,000 million imperial gallons (890,000,000 m3) per day. [10]

Singapore's approach does not simply rely on physical infrastructure, but it also emphasises proper legislation and enforcement, water pricing, public education as well as research and development. [11] In 2007, Singapore's water and sanitation utility, the Public Utilities Board, received the Stockholm Industry Water Award for its holistic approach to water resources management. [12]

Singapore was also the first country in Asia to institute a comprehensive fluoridation programme which covers the entirety of its population. The water was fluoridated at 0.7 ppm using sodium silicofluoride. [13]

History

Early local water supply (until 1979)

The history of common water supply in Singapore began with the construction of the MacRitchie Reservoir, which was built by the British in 1866.

During the drought of 1902 the Water Department cut supply to just 2–3 hours per day. Singapore faced a severe shortfall in water and stored water was estimated to be 70 million gallons, or less, against consumption of 2.5 million gallons per day. Evaporation from the reservoir made the situation worse and there were daily records of the falling water level in the reservoir. [14]

There was public pressure to prioritise the town's water supply over 'shipping interests'. The leader writer in the Singapore Free Press Weekly recognised the needs of the port and shipping industry for fresh water had to be considered as 'most important' otherwise '[Singapore] may as well be shut up'. [15]

Water meters were already in use in Singapore in 1902. In an article during the 'Water Famine' a householder complained of his meter whizzing round even though only air came through the pipe. The householder feared being charged the tariff (20 cents per 1,000 gallons or 4.4 cents per m3) but was assured by the Water Department that his bill would be corrected to the average consumption over previous months. [16] The same article highlights that, in searching for water and drilling artesian wells, it was discovered that no geological survey of the island of Singapore had ever been undertaken.

Another faulty water meter resulted in a court case involving attempted bribery of a Water Department official. A large water consumer was convicted of offering a bribe to have his faulty water meter left alone and uncorrected. [17]

Lower Peirce Reservoir and the Upper Seletar Reservoir were completed in 1913 and 1949 respectively, in order to supply the rapidly modernising colonial city with sufficient water. In 1927 the municipal leadership of Singapore and Sultan Ibrahim of the state and territories of Johor in neighboring Malaya signed an agreement that allowed Singapore to rent land in Johor and use its water for free. The Municipal Water Department, under David J. Murnane, began importing raw water from Gunong Pulai in 1927 and filtered water on 31 December 1929. The water filtration and pipeline capacity from Gunong Pulai was doubled in 1939. [18]

In 1938, another pipeline was built to return a quantity of treated water to Johor. During the Fall of Singapore in 1942, the causeway that linked Singapore with the Malay Peninsula was blown up by retreating British troops to slow down the Japanese advance, thus destroying the pipeline, which left Singapore with decreased water reserves that could last at most two weeks. [19] According to Lee Kuan Yew, this was one of his motives to envision water self-sufficiency for Singapore going forward when he became the country's first prime minister. [11]

Expansion of water imports and of local reservoirs (1965–1997)

Map of Singapore showing in the Northeast the mouth of the Johor River, Singapore's main source of mud, and streams in the Central Catchment Area in the middle of Singapore. Singapore2021OSM.png
Map of Singapore showing in the Northeast the mouth of the Johor River, Singapore's main source of mud, and streams in the Central Catchment Area in the middle of Singapore.

After the war, Singapore continued to grow rapidly and more water was needed to sustain the city’s growth. The 1927 agreement was superseded by two new agreements signed in 1961 and 1962 between the independent federation of Malaya and the self-governing British territory of Singapore. They foresaw the payment of a water rate in addition to the rent for the land. [20]

Under these agreements Singapore built two water treatment plants in Singapore and a new, expanded pipeline from Johor. [21] Singapore also supplied treated water to Johor far below the cost of treating the water. At the time of the agreements it was expected that Singapore would become part of Malaysia, as it did for a brief period beginning in 1963.

When Singapore separated from Malaysia in 1965, then Malaysian Prime Minister Tunku Abdul Rahman said that "If Singapore’s foreign policy is prejudicial to Malaysia’s interests, we could always bring pressure to bear on them by threatening to turn off the water in Johor". Decades later, Malaysia clarified that the statement should be seen in context that at the time, Malaysia and Indonesia were engaged in a confrontation and that the remark referred to the possibility of Singapore siding with Indonesia. [22]

This was another motive for Singapore to further develop its local water resources, according to Lee Kuan Yew. Therefore, in parallel to the gradual expansion of water imports from Johor the Public Utilities Board, created in 1963, embarked on the construction of more water schemes inside Singapore. They included the damming of river estuaries to allow for greater storage volumes. For example, the Kranji-Pandan Scheme, completed in 1975, included the damming of the estuary of the Kranji river and the construction of a reservoir at Pandan. In the same year, the Upper Peirce Reservoir was completed. As part of the Western Catchment Scheme, completed in 1981, another four rivers were dammed. [21]

In 1983, a dam was built across the estuary of the Seletar River to form the Lower Seletar Reservoir. But these amounts were still not sufficient, and seawater desalination was too expensive at the time to be considered. Singapore was thus interested in building a dam on the Johor River in Malaysia and an associated new water treatment plant. After six years of difficult negotiations, the Prime Ministers of Singapore and Malaysia signed a Memorandum of Understanding (MOU) in 1988 paving the way for an agreement in 1990 with Johor that allowed the construction of a dam (Linggiu Dam) in the state that will be operated by Singapore. [20] Ever since, Singapore's Public Utilities Board has operated a water treatment plant in Kota Tinggi, Johor, known as the Johor River Water Works.

Water negotiations (1998–2002)

In 1998, Singapore began new negotiations with Malaysia to extend its water agreements beyond 2011 and 2061 respectively. In return, Malaysia initially asked to increase the raw water price to 60 sen per 1,000 imperial gallons (4,500 L), corresponding to 4 US cents per cubic meter. [23] [24] This price was still much lower than the cost of desalinated seawater or of NEWater. However, in 2002 Malaysia asked for a much higher price of 6.4 Malaysian Ringgit per 1,000 imperial gallons (4,500 L) (US$0.45 per cubic meter), arguing that Hong Kong paid the equivalent of 8 Malaysian Ringgit per 1,000 imperial gallons (4,500 L) for water from China. [24] [25] [26]

The new price proposed by Malaysia was close to the price of desalinated water. The government of Singapore said that Malaysia had no right to alter the price of water because of the deal that they have, which included Malaysia receiving treated water from Singapore. It further clarified that the price paid by Hong Kong included payment for substantial infrastructure provided by China, while Malaysia provided only access to raw water and the infrastructure necessary to convey the water inside Malaysia was entirely paid for by Singapore. Singapore decided to refuse to accept a higher price and its initial goal to extend the agreements beyond 2061. Instead, Singapore decided to achieve a different path of self-sufficiency in its water supply before 2061. Subsequently, negotiations would end in 2003 without result.

Towards water self-sufficiency (2002–2011)

Panoramic view of Upper Peirce Reservoir, Singapore.jpg
The Upper Peirce Reservoir, one of the reservoirs located in Singapore's Central Catchment Nature Reserve (CCNR).

While the negotiations were ongoing however, Singapore was already prepared for greater water self-sufficiency through an integrated water management approach including water reuse and desalination of seawater. In 1998, the government initiated a study, the Singapore Water Reclamation Study (NEWater Study), to determine if reclaimed water treated to potable standards was a viable source of water. In order to facilitate the new integrated approach, the Public Utilities Board, which had previously been in charge of water supply only, was given the responsibility for sanitation as well in 2001. Previously sanitation had been under the direct responsibility of the Ministry of Environment. The new policy was called the "Four Taps": The first and second taps were local water catchments and water imports.

In 2002, Singapore commissioned its first reclaimed water plant, thus opening a "Third Tap". This was done carefully, after a monitoring period of two years to ensure safe water quality. There was also an active marketing campaign that included the opening of a visitor center, the sale of NEWater in bottles and the Prime Minister drinking a bottle of NEWater in front of the cameras. [19] In 2005 Singapore opened its first seawater desalination plant, the "Fourth Tap". In the meantime it also further expanded its reservoirs, the "First Tap". Today's largest reservoir, the Marina Bay reservoir, was inaugurated in 2008. It is located in the estuary of a river that has been closed off by a barrage to keep the seawater out. Two similar barrages were completed in July 2011, forming the Punggol Reservoir and the Serangoon Reservoir. When the 1961 water agreement with Malaysia ended in August 2011, Singapore could thus afford to let it expire without any issues to its water supply.

Singapore's water usage reaches a demand of about 430 million gallons per day. Of the Four Taps of Supply, Imported water from Johor satisfies about 50 percent of the demand, NEWater can meet up to 40 percent, Desalination up to 25, and the local catchments help to make up the rest. [27] Furthermore, Singapore has become a global water research and technology hub with active support from the government.

Self-sufficiency and outlook (2011–present)

Shortly after its independence, Singapore has set a goal to be entirely water self-sufficient before the 1962 long-term water supply agreement with Malaysia expires in 2061. Nevertheless, a 2003 analysis by the Institute of Southeast Asian Studies stated that such efforts made within the last few decades meant that Singapore has achieved self-sufficiency decades earlier beginning from 2011 and that "the 'water threat' is now significantly less than what it seemed to be". [28] This analysis eventually proved true; a report in 2016 has shown that Singapore has achieved self-reliance with its water supply during the mid-2010s. [8]

Nevertheless, water demand in Singapore is expected to double from 380 to 760 million gallons per day between 2010 and 2060. Demand are to keep up with this increase. By the mid-21st century, water demand is expected to be met by reclaimed water at the tune of 50% and by desalination accounting for 30%, compared to only 20% supplied by internal catchments. [29] [30] In response, the government especially since the 2010s has constructed multiple desalination plants throughout the country to keep up with the demand. These include the Tuas South Desalination Plant, Tuas Desalination Plant, the Keppel Marina East Desalination Plant and the Jurong Island Desalination Plant, which began operations in 2013, 2018, 2020 and 2022 respectively. [31]

Water sources and integrated management

The water resources of Singapore are especially precious given the small amount of densely settled land. Singapore receives an average of 2,400 mm of rainfall annually, well above the global average of 1,050 mm. The constraint is the limited land area to catch and store the rainfall, and the absence of natural aquifers and lakes. [11] Therefore, Singapore relies on four water sources, called the "Four National Taps": [32]

This "four tap" strategy aims to reduce reliance on foreign water supply by increasing the volume supplied from the three other sources, or "national taps". Since water demand in 2011 was 380 million imperial gallons (1,700,000 m3) per day, Singapore could actually already have been water self-sufficient in 2011 except in years of very low rainfall. The official figures downplay the share of reclaimed and desalinated water in water supply, and thus the ability of the country to be self-sufficient. However, the Chairman of PUB admitted in 2012 that water self-sufficiency could be achieved well before the target year of 2061.

In Singapore, water management is closely integrated with land management. The latter is tightly controlled in order to prevent any pollution of water resources through sewage, sullage or other sources of pollution. The management of water supply, sanitation and stormwater drainage is managed by a single agency, the Public Utilities Board, in an integrated and coordinated manner.

Water from catchment areas

The Marina Barrage. Marina Barrage Closeup 300522.jpg
The Marina Barrage.

Two thirds of the country's surface area are classified as partly protected catchment areas with certain restrictions on land use, so that the rainwater can be collected and used as drinking water. As of 2012, surface water was collected in 17 raw water reservoirs. [33] Singapore's oldest reservoirs - MacRitchie, Lower Peirce, Upper Selatar as well as the more recently built Upper Peirce Reservoir - are all located in the Central Catchment Nature Reserve, a protected area that has been reforested to protect the water resources and act as a "green lung" for the city. The larger reservoirs, however, have been built after independence and are located in river estuaries that have been closed off by barrages.

Reservoir water is treated through chemical coagulation, rapid gravity filtration and disinfection. [34]

Imported water

Singapore's imported water comes through a pipeline that runs along a 1 km bridge, the Johor–Singapore Causeway, that also carries a road and a railway. Imported water has gradually reduced over the years; as of 2009, imported water had been reduced from 50% previously to 40% of total consumption. [35] After the expiry of a 1961 water agreement between Malaysia and Singapore in 2011, two agreements are in force now. One was signed in 1962 and another one in 1990. Both will expire in 2061. Under the first agreement the price of raw water was set at 3 Malaysian sen per 1,000 imperial gallons (4,500 L), corresponding to about 0,2 US cents per cubic meter. [36]

Under this agreement Singapore is entitled to receive up to 250 million imperial gallons (1,100,000 m3) per day, corresponding to 56% of its water use of 380 million imperial gallons (1,700,000 m3) in 2011. Furthermore, under the 1990 agreement, Singapore is entitled to buy an additional unspecified quantity of treated water from the Linggiu Dam at a price that is higher than under the previous agreement.

Reclaimed water

Bottles of NEWater for distribution during the National Day Parade celebrations of 2005 at Marina South. NEWater.jpg
Bottles of NEWater for distribution during the National Day Parade celebrations of 2005 at Marina South.

In Singapore, reclaimed water is branded as NEWater and is bottled directly from an advanced water purification facility for educational and celebratory purposes. Though most of the reused water is used for high-tech industry in Singapore, a small amount is returned to reservoirs for drinking water. NEWater is the brand name given to ultra-pure water that is produced from reclaimed water. Wastewater, which is called "used water" in Singapore, is treated in conventional advanced wastewater treatment plants that are called reclamation plants in Singapore. The effluent from the reclamation plants is either discharged into the sea or undergoes further microfiltration, reverse osmosis and ultraviolet treatment.

Reclaimed water provides 40% of Singapore's water requirements. Using the NEWater technology, cleaned water is recycled to create ultra-clean, premium reclaimed water. Up to 55% of Singapore's water demand is anticipated to be satisfied by NEWater by 2060. [37] [38]

The quality of NEWater is monitored by, among others, an international panel of experts and exceeds the World Health Organization (WHO) standards for drinking water, much higher than imported water. In 2012, there were four NEWater factories, located at the Bedok, Kranji, Ulu Pandan and Changi next to five water reclamation plants.

At the end of 2002, the programme had garnered a 98 percent acceptance rate among Singaporeans, with 82% of respondents indicating that they would drink the reused water directly, another 16% only when mixed with reservoir water. [39] The produced NEWater after stabilization (addition of alkaline chemicals) is in compliance with the WHO requirements and can be piped off to its wide range of applications (e.g. reuse in industry, discharge to a drinking water reservoir). [40] NEWater now makes up around 30% of Singapore's total use, by 2060 Singapore's National Water Agency plans to triple the current NEWater capacity as to meet 50% of Singapore's future water demand. [41]

Most of the NEWater is used by industries for non-potable uses such as wafer fabrication. The rest is fed into nearby reservoirs. As of 2019, according to PUB, NEWater was able to meet 30% of Singapore's water requirements. [42] The high purity of the water has actually allowed industries to reduce their costs. [19] With the construction of the Deep Tunnel Sewerage System the decentralized water reclamation plants and NEWater factories are expected to be gradually closed and replaced by the single, much larger water reclamation plant and NEWater factory at Changi at the Eastern end of Singapore Island.

The Bedok reclamation plant was the first one to be decommissioned in 2009, followed by the Seletar plant in 2011. The Bedok NEWater plant, however, continued to operate, while the Seletar NEWater plant was decommissioned along with the reclamation plant. [43] The Kranji, Ulu Pandan and Bedok reclamation plants had been upgraded in 1999–2001, making them more compact so that they needed less land and covering them for odor control in order to make nearby land more valuable. [44]

Desalinated seawater

On 13 September 2005, the country opened its first desalination plant, SingSpring Desalination Plant, in Tuas at the southwestern tip of Singapore Island. The S$200 million plant, built and operated by Hyflux, can produce 30 million imperial gallons (140,000 m3) of water each day and meets 10% of the country's water needs. [45]

In 2007, the Sungei Tampines was established as a test project for future large-scale desalination projects. This project would influence further desalination projects in the country, as the reliability of the dual-purpose desalination concept was tested on a smaller scale. That facility, which also draws freshwater and seawater from surrounding sources, is able to produce around one million gallons a day. [46] [47]

The bid to build and operate Singapore's second and largest desalination plant, Tuaspring Desalination Plant (since renamed Tuas South Desalination Plant), with a capacity of 70 million imperial gallons (320,000 m3) per day, also located at Tuas, was launched in June 2010. [48] Hyflux won the contract in April 2011, and the plant began operations two years later in 2013. [49] In May 2019, following financial losses from the plant, PUB took over the Tuaspring Desalination Plant. [50] [51]

In June 2018, a third desalination plant, the Tuas Desalination Plant (TDP), was opened. [52] Functioning also as a test bed for energy saving technology, the plant can produce 30 million imperial gallons (140,000 m3) of water per day. Together, desalinated water from SingSpring, Tuaspring and the Tuas Desalination Plants can meet up to 30% of Singapore's current water needs as of 2019. [53]

In 2019, government has identified five other coastal sites for future plants in the coming decades, with the objective of bringing the installed capacity to one million m³ per day, so that desalination will be able to meet up to 30% of Singapore's future water demand by 2060. [54]

In June 2020, Singapore began operating its fourth desalination plant, the Keppel Marina East Desalination Plant (KMEDP). [55] [56] In April 2022, a fifth desalination plant began operations, the Jurong Island Desalination Plant (JIDP). [57]

Plant nameDate of commissioningMaximum capacity (ML/day)Operator
SingSpring Desalination Plant2005137 [58] Keppel
Tuaspring (renamed Tuas South Desalination Plant; TSDP)2013320 [46] PUB
Tuas Desalination Plant (TDP)2018137 [59] PUB
Keppel Marina East Desalination Plant (KMEDP)2020137 [60] Keppel
Jurong Island Desalination Plant (JIDP)2022137 [61] Tuas Power–Singapore Technologies Marine (TP–STM) consortium

Water research and technology

Sanitation

Until 2010, wastewater in Singapore was collected through a sewer system that included 139 pumping stations that pumped water to six wastewater treatment plants. These pumping stations and plants were gradually decommissioned while a newer system, the Deep Tunnel Sewerage System (DTSS) was made operational. [62] The Changi Water Reclamation Plant, the heart of the first phase of the DTSS, was opened by Prime Minister Lee Hsien Loong in June 2009. [63]

The first phase of the DTSS consists of a 48-km long deep tunnel sewer that runs 20 to 55 metres below ground, and channels used water to the Changi Water Reclamation Plant at the Eastern end of the island. The plant had an initial capacity of 176 million imperial gallons (800,000 m3) per day. Most of the treated used water is discharged into the sea through an outfall, while some of it is further purified into NEWater.

The deep tunnel works entirely by gravity, eliminating the need for pumping stations, and thus the risks of used water overflows. At one-third the size of conventional plants, the Changi Water Reclamation Plant is designed to be compact. Centralisation of used water treatment at Changi also allows for economies of scale. In a second phase of the DTSS, the deep tunnel system is to be expanded to the entire island, with a second wastewater treatment plant at Tuas at the Western end of the island. [62]

Stormwater management

The stormwater drainage system in Singapore is completely separated from the sewer system. It consists of 7,000 km of public roadside drains and about 1,000 km of major canals and waterways that are regularly cleaned of debris and maintained by private companies under performance-based contracts with PUB. [64] This system has reduced the flood-prone area from 3,200 hectares in the 1970s to about 49 hectares today[ when? ] despite increased urbanization, which usually would have resulted in more floods. PUB plans to further reduce flood prone areas to 40 hectares by 2013. In the 1960s and 1970s widespread flooding was common in Singapore, especially in the city centre, which is built on relatively low-lying land. [65] Nevertheless, flash floods caused by unusually heavy rains and blocked drains caused damage in 2010 and 2011. [66]

Water use, conservation and efficiency

There have also been campaigns to urge people to conserve water, reducing consumption from 165 litres per person per day in 2003 to 155 litres in 2009. The target is to lower it to 140 litres by 2030. [2] Public education was an important instrument to promote water conservation. For example, a Water Efficiency Labeling Scheme for taps, showerheads, toilets and washing machines was introduced so that consumers could make informed choices when making purchases.

The tariff structure was also modified. While tariffs historically included a cross-subsidy from industries that paid a higher price to residential users that paid a lower price for social reasons, this policy was ended and residential users were charged a tariff that covers the full costs of supply. [11] The level of water losses - more precisely defined as non-revenue water - is one of the lowest in the world at only 5%.

Responsibility for water supply and sanitation

The headquarters of the Public Utilities Board (PUB). Environment Building 2, Feb 06.JPG
The headquarters of the Public Utilities Board (PUB).

Within the government of Singapore, the Ministry of Sustainability and the Environment is in charge of policy setting for water and sanitation. The Public Utilities Board, a statutory board under the Ministry, is in charge of providing drinking water as well as of sanitation and stormwater drainage. It also monitors compliance of potential polluters on the basis of the Sewerage and Drainage Act. Thus, PUB is both a service provider and a regulator, but its regulatory role only encompasses other entities. The National Environment Agency monitors PUB's compliance with environmental as well as drinking water quality standards on the basis of the Environmental and Public Health Act. Legislation is effectively implemented, with heavy fines, and the various agencies in charge of water work together in a coordinated manner under a common framework. [11]

Research and development

In 2006, the Singapore government identified water as a new growth sector and committed to invest S$330 million over the following five years in order to make Singapore a global hub for water research and development. [11] PUB has an active research and development program that includes upstream research, pilot projects and demonstration projects. [67] An Environment and Water Industry Development Council (EWI) has been established to support, together with the National Research Foundation, a Strategic Research Programme on Clean Water. [68] [69]

Leading Japanese companies such as Toshiba and Toray have established water research centers in Singapore. [70] [71] Singapore is home to over 70 local and international water companies and 23 research and development centers working on about 300 projects valued at $185 million. [72]

Furthermore, the Lee Kuan Yew School of Public Policy at National University of Singapore established an Institute of Water Policy in 2008. Also since 2008, the country has hosted the Singapore International Water Week, a key event for the global water industry.

Financial aspects

Tariffs. Water and sewer tariffs in Singapore are set at a level allowing cost recovery, including capital costs. Water and sewer tariffs were raised substantially in the late 1990s, so that the average monthly domestic bill including taxes increased from S$13 in 1996 to S$30 in 2000. [73] The sewerage tariff (called "waterborne fee") is S$0.30/m3 for domestic users plus a fixed tariff of S$3 per "chargeable fitting" per month. The water tariff includes a conservation tax set at 30% that increases to 45% for domestic consumption above 40 m3 per month. A general service tax of 7% is added to the bill. As of 2012, a household consuming 20 m3 per month and that has three "chargeable fittings" faces a water bill of S$32.5 per month and a sewer bill of S$15 per month, both including all taxes. The total of S$47.5 (USD 37.7) per month corresponds to S$2.38/m3 (US$1.88/m3). Industrial water tariffs are set lower at S$0.52/m3. [74] Water and sewerage tariffs are lower than tariffs in some European countries such as in Germany where the average water and sewer tariff including taxes was Euro 3.95 per m3 in 2004. From 2017, the water tariff will increase by 30% in two phases.

Investment. In the financial year 2010 PUB undertook investments of S$411 million (USD 290 million) in its own assets, mainly for water supply and NEWater, and S$451 million (USD 319 million) for assets belonging to the government, mainly for sanitation and stormwater drainage. [5] This corresponds to annual investments of USD 117 per capita, which is higher than in the United States where the corresponding figure is USD 97.

Financing. In 2005 PUB issued for the first time a bond, raising S$400 million, to finance part of its investment program. Since then, bonds have been issued regularly, including a S$300 million bond with a maturity of 20 years in 2007. [75] During the financial year 2010, PUB Group received an operating grant of S$185 million to fund the operation and maintenance of the stormwater drainage network and operating costs of certain water infrastructure assets such as the Marina, Serangoon and Punggol Reservoir schemes. [5]

Notes

  1. The five desalination plants are: SingSpring Desalination Plant, Tuas South Desalination Plant (TSDP), Tuas Desalination Plant (TDP), Keppel Marina East Desalination Plant (KMEDP), and Jurong Island Desalination Plant (JIDP).

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Tampa Bay Water (TBW) is a regional wholesale drinking water utility that serves customers in the Tampa Bay, Florida region. The agency is a special district of the state created by inter-local agreement among six member governments. A nine-member board of directors composed of two elected commissioners from each member county and one elected representative from each member city oversees the policy decisions of the agency. The member governments that make up the board of directors are: The cities of New Port Richey, St. Petersburg, Florida, and Tampa, and Hillsborough County, Pasco County, and Pinellas County. These member governments provide water to over 2.5 million citizens.

Water supply and sanitation in Greece is characterised by diversity. While Athens receives its water from a series of reservoirs, some of which are located 200 km away, some small islands are supplied with water from tankers. Greeks have suffered from repeated droughts, the most recent one occurring in 2007. The EU supported the construction of numerous wastewater treatment plants since the 1990s in order to achieve EU environmental standards. While the wastewater discharge of the biggest cities is now in compliance with these standards, some smaller towns still lag behind.

Water supply and sanitation in Malaysia is characterised by numerous achievements, as well as some challenges. Universal access to water supply at affordable tariffs is a substantial achievement. The government has also shown a commitment to make the sector more efficient, to create a sustainable funding mechanism and to improve the customer orientation of service providers through sector reforms enacted in 2006. The reform creates a modern institutional structure for the water sector, including an autonomous regulatory agency, an asset management company and commercialised state water companies that have to reach certain key performance indicators that will be monitored by the regulatory agency. The government has also stated its intention not to embark on new private sector contracts for water provision, after a bout of such contracts during the 1990s showed mixed results.

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.

<span class="mw-page-title-main">Water supply and sanitation in Namibia</span>

Namibia is an arid country that is regularly afflicted by droughts. Large rivers flow only along its northern and southern borders, but they are far from the population centers. They are also far from the country's mines, which are large water users. In order to confront this challenge, the country has built dams to capture the flow from ephemeral rivers, constructed pipelines to transport water over large distances, pioneered potable water reuse in its capital Windhoek located in the central part of Namibia, and built Sub-Saharan Africa's first large seawater desalination plant to supply a uranium mine and the city of Swakopmund with water. A large scheme to bring water from the Okavango River in the North to Windhoek, the Eastern National Water Carrier, was only partially completed during the 1980s.

Tuas Power Ltd is one of the largest power generation companies and a key provider of energy solutions, multi-utilities and environmental services in Singapore.

Beijing, the capital of China, is characterized by intense water scarcity during the long dry season as well as heavy flooding during the brief wet season. Beijing is one of the most water-scarce cities in the world. Total water use is 3.6 billion cubic meters, compared to renewable fresh water resources of about 3 billion cubic meters. The difference is made up by the overexploitation of groundwater. Two-thirds of the water supply comes from groundwater, one third from surface water. Average rainfall has substantially declined since the 1950s. Furthermore, one of the two main rivers supplying the city, the Yongding River, had to be abandoned as a source of drinking water because of pollution. Water savings in industry and agriculture have compensated for these losses and freed up water for residential uses.

<span class="mw-page-title-main">Water supply and sanitation in Algeria</span>

Drinking water supply and sanitation in Algeria is characterized by achievements and challenges. Among the achievements is a substantial increase in the amount of drinking water supplied from reservoirs, long-distance water transfers and desalination at a low price to consumers, thanks to the country's substantial oil and gas revenues. These measures increased per capita water supply despite a rapidly increasing population. Another achievement is the transition from intermittent to continuous water supply in the capital Algiers in 2011, along with considerable improvements in wastewater treatment resulting in better water quality at beaches. These achievements were made possible through a public-private partnership with a private French water company. The number of wastewater treatment plants throughout the country increased rapidly from only 18 in 2000 to 113 in 2011, with 96 more under construction. However, there are also many challenges. One of them is poor service quality in many cities outside Algiers with 78% of urban residents suffering from intermittent water supply. Another challenge is the pollution of water resources. There has also been insufficient progress concerning reuse of treated water, a government priority in this dry country.

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.

Jurong Island desalination plant is a desalination plant on Jurong Island in Singapore. It is the fifth desalination plant in Singapore.

References

  1. 1 2 3 WHO/UNICEF:Joint Monitoring Program for Water Supply and Sanitation:Data resources and estimates - Introduction Archived 14 May 2011 at the Wayback Machine , accessed on 21 July 2012
  2. 1 2 Public Utilities Board:Conserve Archived 30 April 2010 at the Wayback Machine , accessed on 22 August 2010
  3. "Save Water". Archived from the original on 7 July 2017. Retrieved 19 June 2017.
  4. "Water price to rise from April 2024; Government to provide support for lower- and middle-income households" . Retrieved 28 September 2023.
  5. 1 2 3 Financial Report 2010/11. "Financial Review for Financial Year 2010" (PDF). Public Utilities Board. pp. 54–55. Archived from the original (PDF) on 25 February 2014. Retrieved 7 June 2012.{{cite web}}: CS1 maint: numeric names: authors list (link)
  6. "Water Quality". pub.gov.sg. Public Utilities Board. Archived from the original on 7 March 2022. Retrieved 7 March 2022.
  7. "Singapore Water Story". pub.gov.sg. Public Utilities Board. 17 April 2022. Archived from the original on 29 March 2022. Retrieved 17 April 2022.
  8. 1 2 Roman, David; Cheok, Melissa (13 June 2016). "Singapore Achieves Self Reliance in Water, Sees Demand Doubling". bloomberg.com. Bloomberg News. Archived from the original on 7 March 2022. Retrieved 7 March 2022.
  9. "Four National Taps". pub.gov.sg. PUB. Archived from the original on 9 October 2021. Retrieved 9 October 2021.
  10. Mohan, Matthew. "Singapore's first large-scale desalination plant capable of treating both seawater and freshwater opens". channelnewsasia.com. CNA. Archived from the original on 9 October 2021. Retrieved 9 October 2021.
  11. 1 2 3 4 5 6 Ivy Ong Bee Luan (2010). "Singapore Water Management Policies and Practices". International Journal of Water Resources Development. 26 (1): 65–80. doi:10.1080/07900620903392190. S2CID   154813810.
  12. Stockholm International Water Institute:Stockholm Industry Water and sexAward:PUB Singapore Archived 4 July 2010 at the Wayback Machine
  13. Loh T. (1996). Thirty-eight years of water fluoridation--the Singapore scenario. Community dental health, 13 Suppl 2, 47–50.
  14. "Untitled". Archived from the original on 2 February 2023. Retrieved 2 February 2023.
  15. "Municipal Water". Archived from the original on 2 February 2023. Retrieved 2 February 2023.
  16. "THE WATER FAMINE". Archived from the original on 2 February 2023. Retrieved 2 February 2023.
  17. "BRIBERY ENCOURAGED". National Library Board. Archived from the original on 25 July 2018. Retrieved 25 July 2018.
  18. David J. Murnane
  19. 1 2 3 "Singapore’s Water Cycle Wizardry," by Sandra Upson, IEEE Spectrum, June 2010, retrieved on 9 August 2012
  20. 1 2 Valerie Chew: Singapore-Malaysia water agreements Archived 9 June 2012 at the Wayback Machine , Singapore Infopedia, retrieved on 7 June 2012
  21. 1 2 Development of Water Supply Infrastructure: MacRitchy Reservoir History Archived 5 March 2016 at the Wayback Machine , retrieved on 7 June 2012
  22. quoting Professor Nur Anuak (6 January 2003). "History of water - according to Utusan Malaysia, in: Malaysia to stop purchasing treated water from singapore". Archived from the original on 28 October 2014. Retrieved 11 August 2012.
  23. The Star:WATER: The Singapore-Malaysia Dispute: THE FACTS [ permanent dead link ]
  24. 1 2 Cecilia Tortajada and Kimberly Pobre:The Singapore–Malaysia water relationship: an analysis of the media perspectives Archived 21 February 2014 at the Wayback Machine , Hydrological Sciences Journal, July 2011
  25. BBC:Malaysia raises water stakes Archived 3 March 2008 at the Wayback Machine , 15 February 2003, retrieved on 21 July 2012
  26. Baradan Kuppusamy Water war makes small splash Archived 21 February 2014 at the Wayback Machine , Asia Times, 1 August 2003
  27. "Finding ways to increase water supply from Johor River", The Straits Times, 17 January 2018
  28. Poh Onn Lee (2003). "The water issue between Singapore and Malaysia: No solution in sight?". Archived from the original on 20 December 2012. Retrieved 11 August 2012.
  29. Bloomberg interview with Chew Men Leong, chief executive of PUB (30 July 2012). "Singapore To Meet Water Target Before Deadline: Southeast Asia". Bloomberg News . Archived from the original on 5 August 2012. Retrieved 9 August 2012.
  30. PUB. "Four National Taps Provide Water for All". Archived from the original on 30 July 2012. Retrieved 10 August 2012.
  31. "Singapore officially opens fifth desalination plant". TODAY. 17 April 2022. Archived from the original on 17 April 2022. Retrieved 17 April 2022.
  32. Irvine, Kim; Chua, Lloyd; Eikass, Hans S. (2014). "The Four National Taps of Singapore: A Holistic Approach to Water Resources Management from Drainage to Drinking Water". Journal of Water Management Modeling. 22. doi: 10.14796/JWMM.C375 . hdl: 10536/DRO/DU:30071550 . Archived from the original on 24 April 2022. Retrieved 14 May 2022.
  33. PUB. "Local Catchment Water". Archived from the original on 25 July 2012. Retrieved 15 July 2012.
  34. PUB. "Water Treatment". Archived from the original on 15 July 2012. Retrieved 12 August 2012.
  35. "Key step to water adequacy". Straits Times. Archived from the original on 27 June 2009. Retrieved 24 June 2009.
  36. Valerie Chew:Singapore-Malaysia water agreements Archived 9 June 2012 at the Wayback Machine , Singapore Infopedia. This is based on an exchange rate of 3.11 Malaysian Ringgit per US dollar, as of 11 August 2012
  37. "Wastewater resource recovery can fix water insecurity and cut carbon emissions". European Investment Bank. Archived from the original on 29 August 2022. Retrieved 29 August 2022.
  38. "Singapore Turns Sewage into Clean, Drinkable Water, Meeting 40% of Demand". VOA. Archived from the original on 29 August 2022. Retrieved 29 August 2022.
  39. Water Sensitive Cities. IWA Publishing. Archived from the original on 11 June 2021. Retrieved 11 June 2021.
  40. "Singapore Public Utilities Board". Archived from the original on 28 May 2016. Retrieved 29 July 2016.
  41. "Global milestones in water reuse: keys to success and trends in development". Archived from the original on 11 September 2016. Retrieved 29 July 2016.
  42. PUB. "PUB, Singapore's National Water Agency". PUB, Singapore's National Water Agency. Archived from the original on 10 August 2019. Retrieved 24 August 2019.
  43. PUB. "Seletar Water Reclamation Plant Decommissioned". Archived from the original on 1 August 2013. Retrieved 10 August 2012.
  44. PUB. "Water Reclamation Plants". Archived from the original on 19 January 2013. Retrieved 9 August 2012.
  45. Dominique Loh. "PM Lee opens Asia's largest water desalination plant in Tuas". Channel NewsAsia. Archived from the original on 9 December 2005. Retrieved 13 September 2005.
  46. 1 2 "World's first large-scale desalination plant for sea and freshwater to open in Singapore in 2020". TODAYonline. Archived from the original on 6 October 2017. Retrieved 6 October 2017.
  47. "Pasir Ris PUB plant can treat sea and canal water". www.asiaone.com. Archived from the original on 6 October 2017. Retrieved 6 October 2017.
  48. "Hyflux to build Singapore's biggest desalination plant". Straits Times. Archived from the original on 8 March 2011. Retrieved 7 March 2011.
  49. PUB Press Release (6 April 2011). "PUB and Hyflux sign Water Purchase Agreement for Singapore's second and largest desalination project". Archived from the original on 22 September 2012. Retrieved 9 August 2012.
  50. PUB. "PUB, Singapore's National Water Agency". PUB, Singapore's National Water Agency. Archived from the original on 10 August 2019. Retrieved 24 August 2019.
  51. "From making waves to drowning in red ink: Hyflux, Tuaspring and how a business giant came undone". CNA. Archived from the original on 24 August 2019. Retrieved 24 August 2019.
  52. PUB. "PUB, Singapore's National Water Agency". PUB, Singapore's National Water Agency. Archived from the original on 10 August 2019. Retrieved 24 August 2019.
  53. PUB. "PUB, Singapore's National Water Agency". PUB, Singapore's National Water Agency. Archived from the original on 10 August 2019. Retrieved 24 August 2019.
  54. "4 firms vie to build and operate Singapore's fifth desalination plant". Archived from the original on 12 February 2019. Retrieved 12 February 2019.
  55. Tan, Audrey; Ng, Keng Gene (4 February 2021). "S'pore's fourth desalination plant, which can treat both sea and reservoir water, officially opens". www.straitstimes.com. Archived from the original on 17 April 2022. Retrieved 17 April 2022.
  56. PUB. "Keppel Marina East Desalination Plant begins commercial operations". PUB Web Site. Archived from the original on 14 July 2020. Retrieved 14 July 2020.
  57. Qing, Ang (17 April 2022). "Singapore's fifth desalination plant opens on Jurong Island". www.straitstimes.com. Archived from the original on 17 April 2022. Retrieved 17 April 2022.
  58. "Hyflux » SingSpring Desalination Plant, Singapore". www.hyflux.com. Archived from the original on 6 October 2017. Retrieved 6 October 2017.
  59. "Desalinated Water". PUB, Singapore's National Water Agency. Archived from the original on 6 January 2019. Retrieved 12 November 2018.
  60. "Keppel unveils designs for Marina East Desalination Plant". Water. desalination + reuse. Archived from the original on 12 November 2018. Retrieved 12 November 2018.
  61. "Jurong Island desalination project awarded on $0.91/cubic metre price". www.waterworld.com. Archived from the original on 6 October 2017. Retrieved 6 October 2017.
  62. 1 2 National Environment Agency:Deep Tunnel Sewerage System (DTSS) Archived 16 July 2011 at the Wayback Machine , News Release, 22 January 2001, accessed on 22 August 2010
  63. "Milestones: Largest and most advanced water reclamation plant in Southeast Asia". Public Utilities Board. Archived from the original on 18 July 2012. Retrieved 7 June 2012.
  64. "Drainage Maintenance". Archived from the original on 15 February 2013. Retrieved 9 August 2012.
  65. PUB. "Managing Flash Floods: Overview". Archived from the original on 25 August 2012. Retrieved 9 August 2012.
  66. Channelnewsasia.com (24 December 2011). "Managing flash floods is PUB's priority: CEO". Archived from the original on 14 August 2012. Retrieved 9 August 2012.
  67. PUB. "R&D Approach in PUB". Archived from the original on 20 September 2012. Retrieved 19 July 2012.
  68. National Research Foundation. "Strategic Research Programmes: Environmental & Water Technologies". Archived from the original on 9 March 2012. Retrieved 19 July 2012.
  69. Xinhua (5 July 2011). "Singapore to boost funding for water research, development". Archived from the original on 21 February 2014. Retrieved 19 July 2012.
  70. EDB Singapore (11 April 2012). "Toshiba opens water treatment research centre in Singapore". Archived from the original on 6 July 2012. Retrieved 19 July 2012.
  71. Toray (29 June 2010). "Inauguration of Toray Singapore Water Research Center - Toray's Water Treatment R&D Base in Singapore -". Archived from the original on 11 September 2011. Retrieved 19 July 2012.
  72. PUB Annual Report 2011. "Partnering for Water". Archived from the original on 17 October 2013. Retrieved 9 August 2012.{{cite web}}: CS1 maint: numeric names: authors list (link)
  73. Cecilia Tortajada (2006). "Water management in Singapore". International Journal of Water Resources Development. 22 (2): 227–240. doi:10.1080/07900620600691944. S2CID   153509584.
  74. Public Utilities Board:Water tariff Archived 13 June 2012 at the Wayback Machine , accessed on 16 July 2012
  75. Public Utilities Board. "PUB Bond, October 2007". Archived from the original on 18 July 2012. Retrieved 7 June 2012.