Water supply and sanitation (WSS) in the European Union (EU) is the responsibility of each member state, but in the 21st century union-wide policies have come into effect.[ citation needed ] Water resources are limited and supply and sanitation systems are under pressure from urbanisation and climate change [ citation needed ]. Indeed, the stakes are high as the European Environmental Agency found that one European out of ten already suffers a situation of water scarcity [1] and the IEA measured the energy consumption of the water sector to be equivalent to 3,5% of the electricity consumption of the EU. [2]
This article needs to be updated.(April 2022) |
The water policy of the EU is primarily codified in the following directives:
EU member states have enacted national legislation in accordance with these directives. The institutional organisation of public water supply and sanitation does not fall under the purview of the EU, but remains a prerogative of each member state.
The Council Directive on Urban Waste Water Treatment [3] concerns the collection, treatment and discharge of urban waste water and the treatment and discharge of waste water from certain industrial sectors. Its aim is to protect the environment from any adverse effects due to discharge of such waters.
According to the directive's timetable:
However, in the case of Spain changes were made at the time of transposing the Directive. In Article 2 of the Directive, a collecting system means "a system of conduits which collects and conducts urban waste water" and therefore all sewers and drains, both public and private were included. However, in the Spanish transposition (Real Decreto-Ley 11/1995 of 28 December 1995), the definition of a collecting system was changed to mean "all systems of conduits which collect and conduct urban waste water, from the municipal sewer and drainage networks and go to the treatment plants". The added words mean that when the Spanish definition is applied to Article 3 of the Directive the municipal sewer and drainage networks are excluded. If the municipal network did not exist, as in the case of many urbanisations (housing estates) developed in the 1960s and 1970s and within agglomerations of over 2000 p.e. no collecting system needed to be provided at all, under the Real Decreto-Ley 11/1995. Obviously if waste water is not collected it cannot be treated, therefore the changed definition also affected Article 4 of the Directive. Even so, Spain had to and still has to comply fully with the Directive. On 5 March 2009, the Catalan Autonomous Government finally approved a law (La Llei de la millora d’urbanizacions) to deal with deficits of infrastructures, such as sewers in urbanisations in Catalonia, 18 years after the Directive was approved by the European Parliament.
The directive also allows the establishment of less sensitive coastal areas, for which primary treatment would be sufficient, if it can be shown that there is no adverse impact on the environment (Art. 6).
Member states had to establish lists of sensitive areas. It has been estimated that in 2004 about 34 percent of the pollutant load from wastewater that falls under the scope of the directive is discharged into sensitive areas. [5]
This Directive was amended by the Commission Directive 98/15/EC. [6]
Commission Decision 93/481/EEC defines the information that Member States should provide the commission on the state of implementation of the Directive. [7]
The European Commission published three reports on the implementation of the directive, the latest in 2004. The report noted that the wastewater treatment situation in Europe is still very unsatisfactory and that none of the deadlines has been met by all member countries. Only Austria, Denmark and Germany fully complied with the directive. The report noted that BOD levels in European rivers have been reduced by 20–30 percent since the enactment of the directive, but that other pollution parameters such as nitrogen levels remained high. The reason is that much of the nitrogen pollution comes from non-point sources in agriculture, and the still insufficient nutrient removal by wastewater treatment plants. The eutrophication of the Baltic Sea, North Sea and considerable parts of the Mediterranean thus remains a "severe problem". [8] The report also noted that it is estimated that more than 50 percent of the discharges into sensitive areas was not treated sufficiently. Even for non-sensitive areas, although the picture was less bleak, only 69% of the discharge received treatment and the 2000 deadline was not met by most member countries. 25 out of 556 cities in the EU still had no wastewater treatment system at all.
The directive triggered substantial investment in sewage treatment throughout the EU. A controversial aspect of the directive is the requirement for all agglomerations with more than 2,000 inhabitants to have a wastewater collection system, which has been widely interpreted as requiring connection to a sewer system even if existing on-site sanitation systems perform adequately. The cost of connecting houses to sewers in small rural towns with dispersed housing patterns is often very high and imposes a high financial burden on users.
According to the European Commission, the directive represents the most cost intensive European legislation in the environmental sector. The EU estimates that the equivalent of €152 billion were invested in wastewater treatment from 1990 to 2010. [9] The EU provides support for the implementation of the directive in the order of 5 billion Euro per year.
The European Commission is currently undergoing a consultation on the Urban Waste Water Treatment Directive. As the directive was adopted in 1991, its challenge will be to integrate the commitments taken with the Paris agreement as the wastewater treatment sector consumes 1% of the global total energy consumption. [2] Under a business as usual scenario, this figure is expected to increase by 60% by 2040 compared to 2014. With the introduction of energy efficiency requirements, the energy consumption of the wastewater treatment sector can be reduced by 50% only by using current technologies. On top of that, there are also opportunities to produce enough energy from wastewater to turn the whole water sector energy neutral. It uses the energy embedded in the sludge by producing biogas through anaerobic digestion. These features have been mainly overlooked due to the over-riding objective for utilities to meet existing and future needs for wastewater treatment. In the European Union, 0.8% of total energy consumption goes to wastewater treatment facilities. [10] [11]
Parts of this article (those related to documentation) need to be updated. The reason given is: EU Directive 2020/2184 has since replaced Council Directive 98/83/EC.(August 2022) |
The Directive is intended to protect human health by laying down healthiness and purity requirements which must be met by drinking water within the Community (see water quality). It applies to all water intended for human consumption apart from natural mineral waters and waters which are medicinal products.
Member States shall ensure that such drinking water:
In setting contaminant levels the directive applies the precautionary principle. For example, the EU contaminant levels for pesticides are up to 20 times lower than those in the WHO drinking water guidelines, [12] because the EU directive not only aims at protecting human health but also the environment. The WHO contaminant levels themselves are already set so that there would be no potential risk if the contaminant was absorbed continuously over a person's lifetime. [13] EU drinking water standards and cases where these standards are temporarily exceeded by a small margin should be interpreted in this context.
Compared to the previous European drinking water directive of 1980 the number of parameters has been reduced, allowing member to add parameters such as magnesium, total hardness, phenols, zinc, phosphate, calcium and chlorite. [14]
The directive requires member states to regularly monitor the quality of water intended for human consumption by using the methods of analysis specified in the directive, or equivalent methods. Member states also have to publish drinking water quality reports every three years, and the European Commission is to publish a summary report. Within five years Member States had to comply with the Directive. Exemptions can be granted on a temporary basis, provided that they do not affect human health.
Until 2006 the European Commission has not published a summary report on drinking water quality. No EU country achieves full compliance with the directive, mainly because of the geological nature of its soil and agricultural activity. [14] in 2003 the European Commission initiated a broad consultation process to prepare a revision of the Directive. One key aspect of the revision would be to move away from a pure end-of-pipe standard setting approach. Instead the whole water supply process from the basin to the tap would be assessed to identify risk and the most effective control points, through so-called Water safety plans. [15] Another important challenge will be to integrate the new environmental, climate and energy goals of the EU. The issue is substantial as in average 23% of the treated water in the EU is leaked, with some countries facing leakage rates as high as 60%. [16]
Under this Directive, [17] member states have to identify all the river basins lying within their national territory and assign them to individual river basin districts. By 22 December 2003 at the latest, a competent authority had to be designated for each of the river basin districts. In addition, member states have to analyse the characteristics of each river basin and have to carry out an economic analysis of water use. Nine years after the entry into force of the directive, a management plan must be produced for each river basin district. The measures provided for in the river basin management plan seek to:
By 2010, Member States must ensure that water pricing policies provide adequate incentives for users to use water resources efficiently and that the various economic sectors contribute to the recovery of the costs of water services including those relating to the environment and resources. This cost recovery rule is expected to impact particularly irrigated agriculture, where users have not paid the full costs of water supply.
At the latest twelve years after the date of entry into force of the Directive, the European Commission has to publish a report on the implementation of the Directive.
Some countries, such as France and Spain, had already established basin agencies before the enactment of the directive. They should thus find it easy to implement that part of the directive. Other countries that have historically managed their water resources through institutions whose geographical limits were determined by administrative boundaries, such as in the case of Germany where the states (Laender) manage water resources, are in the process of setting up co-ordinating mechanisms for each river basin. Other elements of the directive, such as the protection of groundwater and cost recovery rules, may be more difficult to implement, especially in Southern member countries that have extensive irrigated agriculture.
In March 2007 the EU commission published its first progress report on the implementation of the EU Framework Directive. [18] The report notes mixed results. Almost all member countries have transposed the directive into national law, but the report notes that "the legal transposition of the Directive in national law is poor and in many cases inadequate". Indeed, the report finds that only in three countries the national law (Austria, Malta and Portugal) is in conformity with the Directive. Furthermore, there have been significant delays in the analysis of the characteristics of each river basin. Since the establishment of this knowledge base is a precondition for Basin Plans, this delay jeopardises progress of the implementation of the entire Directive.
Average connection rates to sanitation systems between 80%–90% are reported for Northern, Southern and Central Europe. Eastern Europe still copes with much lower rates of 40%–65% of the population connected to primary wastewater treatment at least. [19] Europe in general is improving: Over the last decade more households accessed public treatment plants or even upgraded their treatment system (e.g. from secondary to tertiary treatment). [20]
As access is dependent on each member state so is service quality. It ranges from very good service quality in Northern and Southern States of the European Union for example in Spain or Germany to insufficient or poor services especially in Eastern European states. The history of WSS within the member states and different states in development can partly explain the heterogeneous state of the supply and treatment systems. [21]
The supply of water and its disposal has been managed in Europe for many centuries. Centralised water supply and sanitation started with the Romans who were responsible for the construction of aqueducts and systems to collect and distribute water. During the Middle Ages water was distributed through private carriers or/and organised through local communities or cities. The Industrial Revolution and the construction of modern industrialised conurbations in Europe was dependent upon managed water supplies. The United Kingdom pioneered urban planning at that time.
The time of industrialisation and development of cities (between 1800 and 1900) in terms of WSS is called the time of simple regime followed by the regimes of lower complexity between 1900 and 1950, medium (1980–1970), high complexity (1970–1985) and the era finally ended up in an so called attempt of integration from 1985 onwards. The terms reflect the approach of most (Western) European countries towards WSS at that time. It steadily developed from privately organised co-operations to governmental influenced systems. Together with water management in general, it nowadays comes back to private initiatives manifested in Public-Private co-operations. [22]
The Blueprint to Safeguard Europe's Waters is the EU's policy response to the challenges of the implementation of the EU Water Framework Directive. It is basically structured in four parts:
Main text:Water Supply and Sanitation Technology Platform
One international nonprofit association (under Belgian law) supporting the European Union in dealing with the challenges of water related issues is the WssTP. This platform was built up in 2004 with financial support of the European Commission and is steadily growing ever since. The association is dealing with water supply and sanitation issues within Europe and all over the world. Nowadays, it is funded through fees paid by its 127 members from industry, research and education. [23] The aim of the association is to support the development of the water related sector within Europe, assist both the EU and developing countries in achieving the Millennium Development Goals, and provide Research and Development roadmaps and recommendations on water related issues especially involving the European Commission. [24]
The Water Information System for Europe (WISE) is a partnership of the European Commission, the Directorate-General for the Environment (European Commission), Eurostat, the Joint Research Centre and the European Environment Agency. Since 2007 this web-based service platform provides the public with information about ongoing research projects, policies, data, and reports connected to water in the EU. The target group of this online information system is researchers and professionals dealing with water related issues within the framework of the EU. The platform helps to store and administer data and output handed in by member states and agencies connected to the reporting requirements of the European Commission. [25]
The Environmental Action Programme (EAP) is a policy adopted by Environment Ministers in 1993 in a conference in Switzerland. An international Task Force was established later on to support mainly states of countries in the Eastern Europe, Caucasus and Central Asia. In WSS they are supporting the financial strategies of a number of countries to achieve the Millennium Development Goals. Furthermore, they are working on indicators and monitoring systems in those countries to collect data of water utilities to check their performance. Apart from that, the EAP task force is figuring out the potentials of the private sector to participate in the water sector especially in water supply and sanitation in the EECCA countries and they consult local partners in financial planning and investment. They are also collaborating with the EU Water Initiative since 2005. [26]
Major challenges of the EU concerning WSS are connected with modern pressures to the system. Climate change, demographic developments, urbanization, economic progress, social changes influence the water sector in many ways. The European Union is said to be very effective concerning water management and policies. However, especially the new member states located in Eastern Europe are in need of enormous investments to ensure the sustainability of the water infrastructure. [27]
The existing and foreseen problems are the lack of investments in the rural and municipal water supply which led to poor services (e.g. water leakages, interruption of service, insufficient water availability during drought, etc.), the limited availability of water resources and its energy consumption which can represent up to 50% of municipalities' electricity bill. [2] [28] [29] Technologies are actually available and with a quick return on investment but the sole focus on water quality has diverted the attention for the increasing need of sustainability from the water sector in the context of climate change.
Water supply limitation counts as major concern. The first and most rational answer should be to tackle the water leakage problem Europe is facing as almost 1/4 of treated water is leaked in average in the EU. [16] Moreover, research shows that water reuse and recycling are also solutions in the long-term. Furthermore, expert's advice say that water supply and waste water treatment systems should be decentralised. [30] Another challenge within the water sector in Europe is privatisation and lobbyism in the water sector. In France, recent problems emerged regarding the privatising of water supply companies. [31]
The European Union needs to make extra investments of €90 billion in the water and waste sector to meet its 2030 climate and energy goals. However, wastewater resources can be useful. In the European Union, an estimated 60–70% of wastewater's potential value is still untapped (in heat, energy, nutrients, minerals, metals, chemicals). [10] [32] [33]
Although the complete eradication of micropollutants in water is not presently a legal requirement in the EU, Switzerland has previously approved a regulation (in effect since March 2014) to minimize micropollutant loads from wastewater treatment plants serving at least 2 000 people. [34] [35] Many Member States, including France, Germany, and the Netherlands, are contemplating adding treatments to the usual primary, secondary, and tertiary treatment procedures to reduce micropollutants in treated wastewater. These further water treatments are referred to as the "fourth step or quaternary therapy" combined. [36] [37]
According to an EU-funded study, "Europe and the Mediterranean countries are lagging behind" California, Japan, and Australia "in the extent to which reuse is being taken up." According to the study "the concept (of reuse) is difficult for the regulators and wider public to understand and accept." [38]
The second largest waste reclamation program in the world is in Spain, where 12% of the nation's waste is treated. [39] By 2023, a new EU agriculture law may raise water reuse by six times, from 1.7 billion m3 to 6.6 billion m3, and cut water stress by 5%. [10] [40]
The indirect potable reuse (IDP) project in Wulpen, Belgium, discharges recycled water to an unconfined dune aquifer. Initially the recycled water comprised 90% RO permeate and 10% MF permeate (approx. 6,000,000 m3 per year). However, it was observed that some herbicides were present in the recycled water at levels below drinking water standards due to detection of herbicides in the MF permeate. As a result, since May 2004, only the RO permeate after UV disinfection is injected into the aquifer with addition of sodium hydroxide to adjust the pH. [41] [42]
Water reclamation is the process of converting municipal wastewater or sewage and industrial wastewater into water that can be reused for a variety of purposes. It is also called wastewater reuse, water reuse or water recycling. There are many types of reuse. It is possible to reuse water in this way in cities or for irrigation in agriculture. Other types of reuse are environmental reuse, industrial reuse, and reuse for drinking water, whether planned or not. Reuse may include irrigation of gardens and agricultural fields or replenishing surface water and groundwater. This latter is also known as groundwater recharge. Reused water also serve various needs in residences such as toilet flushing, businesses, and industry. It is possible to treat wastewater to reach drinking water standards. Injecting reclaimed water into the water supply distribution system is known as direct potable reuse. Drinking reclaimed water is not typical. Reusing treated municipal wastewater for irrigation is a long-established practice. This is especially so in arid countries. Reusing wastewater as part of sustainable water management allows water to remain an alternative water source for human activities. This can reduce scarcity. It also eases pressures on groundwater and other natural water bodies.
The water industry provides drinking water and wastewater services to residential, commercial, and industrial sectors of the economy. Typically public utilities operate water supply networks. The water industry does not include manufacturers and suppliers of bottled water, which is part of the beverage production and belongs to the food sector.
Water supply and sanitation in France is universal and of good quality. Salient features of the sector compared to other developed countries are the high degree of private sector participation using concession and lease contracts and the existence of basin agencies that levy fees on utilities in order to finance environmental investments. Water losses in France (26%) are high compared to England (19%) and Germany (7%).
Public water supply and sanitation in Germany is universal and of good quality. Some salient features of the sector compared to other developed countries are its very low per capita water use, the high share of advanced wastewater treatment and very low distribution losses. Responsibility for water supply and sanitation provision lies with municipalities, which are regulated by the states. Professional associations and utility associations play an important role in the sector. As in other EU countries, most of the standards applicable to the sector are set in Brussels. Recent developments include a trend to create commercial public utilities under private law and an effort to modernize the sector, including through more systematic benchmarking.
The energy policy of the European Union focuses on energy security, sustainability, and integrating the energy markets of member states. An increasingly important part of it is climate policy. A key energy policy adopted in 2009 is the 20/20/20 objectives, binding for all EU Member States. The target involved increasing the share of renewable energy in its final energy use to 20%, reduce greenhouse gases by 20% and increase energy efficiency by 20%. After this target was met, new targets for 2030 were set at a 55% reduction of greenhouse gas emissions by 2030 as part of the European Green Deal. After the Russian invasion of Ukraine, the EU's energy policy turned more towards energy security in their REPowerEU policy package, which boosts both renewable deployment and fossil fuel infrastructure for alternative suppliers.
The Water supply and sanitation services in Portugal have seen important advances in access to services, technologies used and service quality over the past decades (1980s–1990s), partially achieved thanks to important funds from the European Union. Nevertheless, sanitation still remains relatively low in mountain rural areas and some people have their own sources of water controlled by municipalities.
Sewage treatment is a type of wastewater treatment which aims to remove contaminants from sewage to produce an effluent that is suitable to discharge to the surrounding environment or an intended reuse application, thereby preventing water pollution from raw sewage discharges. Sewage contains wastewater from households and businesses and possibly pre-treated industrial wastewater. There are a high number of sewage treatment processes to choose from. These can range from decentralized systems to large centralized systems involving a network of pipes and pump stations which convey the sewage to a treatment plant. For cities that have a combined sewer, the sewers will also carry urban runoff (stormwater) to the sewage treatment plant. Sewage treatment often involves two main stages, called primary and secondary treatment, while advanced treatment also incorporates a tertiary treatment stage with polishing processes and nutrient removal. Secondary treatment can reduce organic matter from sewage, using aerobic or anaerobic biological processes. A so-called quarternary treatment step can also be added for the removal of organic micropollutants, such as pharmaceuticals. This has been implemented in full-scale for example in Sweden.
Public water supply and sanitation in Denmark is characterized by universal access and generally good service quality. Some important features of the sector in Denmark as compared to other developed countries are:
Water supply and sanitation services in Ireland are governed primarily by the Water Services Acts of 2007 to 2014 and regulated by the Commission for Energy Regulation. Until 2015, the relevant legislation provided for the provision of water and wastewater services by local authorities in Ireland, with domestic usage funded indirectly through central taxation, and non-domestic usage funded via local authority rates. From 2015, the legislation provided for the setup of a utility company, Irish Water, which would be responsible for providing water and wastewater services, and funded through direct billing. The transition between these models, and certain aspects of operation of the new company, caused controversy in its initial period of operation.
Drinking water supply and sanitation in Egypt directly impact the country's public health, industrial developments, and agriculture. Egypt's water and sanitation industry is characterized by both achievements and challenges. Among the achievements are an increase of piped water supply between 1998 and 2006 from 89% to 100% in urban areas and from 39% to 93% in rural areas despite rapid population growth; the elimination of open defecation in rural areas during the same period; and in general a relatively high level of investment in infrastructure. Access to an at least basic water source in Egypt is now practically universal with a rate of 98%. On the institutional side, the regulation and service provision have been separated to some extensions through the creation of a national Holding Company for Water and Wastewater in 2004, and of an economic regulator, the Egyptian Water Regulatory Agency (EWRA), in 2006. Despite these successes, many challenges remain. Only about one half of the population is connected to sanitary sewers. Because of this low sanitation coverage, about 50,000 children die each year because of diarrhea. Another challenge is low cost recovery due to water tariffs that are among the lowest in the world. This in turn requires government subsidies even for operating costs, a situation that has been aggravated by salary increases without tariff increases after the Arab Spring. Furthermore, poor operation of facilities, such as water and wastewater treatment plants, as well as limited government accountability and transparency, are also issues.
Water supply and sanitation in Belgium is provided by a large variety of organizations: Most of the 581 municipalities of Belgium have delegated the responsibility for water supply and sanitation to regional or inter-municipal utilities. There are more than 62 water supply utilities, including 2 regional, 30 inter-municipal and 30 municipal utilities. Another 100 mostly small municipalities provide services directly without having a legally of financially separate entity for water supply. Water is not scarce in Belgium and water supply is generally continuous and of good quality. However, wastewater treatment has long lagged behind and Brussels only achieved full treatment of its wastewater in 2007. In 2004 the European Court of Justice ruled condemning Belgium's failure to comply with the EU wastewater directive, and the ruling has not been fully complied with so far. Wallonia satisfies 55% of the national needs in drinking water while it counts only 37% of the population. Flanders and Brussels are dependent on drinking water from Wallonia, at a level of 40% and 98% respectively.
The Urban Waste Water Treatment Directive 1991 European Union directive concerning urban waste water "collection, treatment and discharge of urban waste water and the treatment and discharge of waste water from certain industrial sectors". It aims "to protect the environment from adverse effects of waste water discharges from cities and "certain industrial sectors". Council Directive 91/271/EEC on Urban Wastewater Treatment was adopted on 21 May 1991, amended by the Commission Directive 98/15/EC.
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 Turkey is characterized by achievements and challenges. Over the past decades access to drinking water has become almost universal and access to adequate sanitation has also increased substantially. Autonomous utilities have been created in the 16 metropolitan cities of Turkey and cost recovery has been increased, thus providing the basis for the sustainability of service provision. Intermittent supply, which was common in many cities, has become less frequent. In 2004, 61% of the wastewater collected through sewers was being treated. In 2020 77% of water was used by agriculture, 10% by households and the rest by industry.
Water supply and sanitation in Lebanon is characterized by a number of achievements and challenges. The achievements include the reconstruction of infrastructure after the 1975–90 Civil War and the 2006 war with Israel, as well as the reform of the water and sanitation sector through a water law passed in 2000. The law created four Regional Water Establishments to consolidate numerous smaller utilities.
The Drinking Water Directive 2020 is an EU law that protects the quality of drinking water and forms part of the regulation of water supply and sanitation in the European Union.
Water supply and sanitation in Italy is characterized by mostly good services at prices that are lower than in other European countries with similar income levels. For example, the average monthly residential water and sewer bill in Italy is 20 Euro compared to 31 Euro in France. According to the OECD, water in Italy has been underpriced for a long time. With about 240 liter per day, per capita water use for residential uses in Italy is higher than in Spain or in France, where it is about 160 liter per day. Water resources in Italy are distributed unevenly, with more abundant resources in the North and scarcer resources in the South. Most water withdrawals are for agriculture and industry, with only 18 percent of water withdrawals made for drinking water supply. About one third of the water withdrawn for municipal supply is not billed to the customers because of leakage, malfunctioning water meters and water theft.
Water supply and sanitation in Georgia is characterized by achievements and challenges. Among the achievements is the improvement of water services in the capital Tbilisi where the water supply is now continuous and of good quality, major improvements in the country's third-largest city Batumi on the Black Sea where the country's first modern wastewater treatment plant now is under operation, as well as a general increase in access to drinking water in the entire country. Water and sewer tariffs remain affordable, with the private water company Georgian Water and Power (GWP) serving the capital being financially viable and profitable, while the public water company serving most of the rest of the country remains financially weak. The improvements were achieved after the Rose Revolution of 2004 when the government decided to reform the sector and to invest in it after many years of neglect.
European Federation of National Associations of Water Services (EurEau) is the organisation represents water service providers at the European level and offers expertise on the water sector to EU bodies and decision-makers, assists policy makers at the European level in the development of directives and other legislation affecting the water sector, and is also a network for its members to meet and exchange information and experience. Founded in 1975, the corporation has grown to represent drinking and waste water service providers from 31 countries across Europe. These countries pertain to EU Member States, EFTA, and the EEA.
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