WATER GLOBAL PRACTICE Wastewater: From Waste to Resource The Case of Atotonilco de Tula, Mexico Reuse of Treated Wastewater for PHOTO 1. Aerial View of Atotonilco Waste Water Agriculture, Energy Generation, and Treatment Plant Transfer of Value to Stakeholders in the Valley of Mexico Context The Valley of Mexico metropolitan area (Zona Metropolitana del Valle de México [ZMVM]) is the ­ picenter. country’s financial, political, and cultural e The ZMVM is the OECD’s third largest metro area and the world’s largest metro area outside Asia (OECD, 2015). It is composed of over 50 municipalities and is ­ City. Nearly home to the federal government in Mexico ­ 20 million people live in this area and in the last decade 1.2 percent the population has grown at an average of ­ Source: Acciona. per ­year. Currently, only about 6 percent of wastewater gen- and a  source of reliable income for about 60,000 erated in the area is ­ treated. For the past 80 years, families. Local farmers value wastewater (whether ­ most of the wastewater produced in the ZMVM has raw, partially treated, or mixed with rainfall) for its been sent to the Tula Valley (also known as Mezquital ­ uality. However, the waste- ability to improve soil q Valley)—a region located in the state of Hidalgo— water contains pathogenic organisms and toxic without treatment, and has been used by farmers chemicals constituting a health risk for farmers and for ­ irrigation. Given the large amounts of wastewa- ­ roducts. To manage the consumers of agricultural p ter and storm water available, what used to be an health risks, there is a crop restriction policy for arid landscape transformed into a highly  produc- reuse of the untreated wastewater: the wastewater tive irrigation district of more than 80,000 hectares can be used only for certain crops that will not be 1 uncooked. Crops grown in the valley are pre- eaten ­ Solution dominantly alfalfa and maize, and there is a small The Mexican federal government included the production of restricted crops in the lower section of Atotonilco WWTP project in the PSHCVM program coriander. the valley including lettuce, cabbage, and ­ to ensure municipal and local government compli- Crop restriction policies can be difficult to enforce, ance with federal laws for wastewater ­ treatment. The and the policy limits the potential to grow higher Atotonilco WWTP, the largest wastewater treatment ­ rops. In addition, untreated waste- value vegetable c plant in Latin America and one of the largest in the water negatively affects the ecosystems of the nearby world, is located within the municipality of Atotonilco c anal. El Salto River and the Salto Tlamaco irrigation ­ ­ idalgo. It occupies 160 hectares de Tula in the state of H Through the national water commission (CONAGUA), with a capacity of 35,000 liters per second and a max- the federal government developed the Atotonilco imum capacity of 50,000 liters per second—to be able Wastewater Treatment Plant (WWTP) project to bene- ­ eason. The plant to absorb storm water during the wet s fit more than 1 ­ 0.5 million people (CONAGUA 2010) in has an estimated lifespan of 50 years and was built in a the ZMVM, and more directly, 700,000 people living strategic location at the end point of the central sewage in the Mezquital Valley and 300,000 who live in, or in pipeline and the beginning of the canals for irrigation close proximity to, the irrigation ­areas. The Atotonilco and the future east sewage pipeline (under construc- WWTP is part of the national program of sustain- ­ SHCVM). tion through the P able water use in the basin of the Valley of Mexico An innovation of the Atotonilco WWTP is that it uses (Programa de Sustentabilidad Hídrica de la Cuenca a combination of wastewater treatment processes 2007. The del Valle de México [PSHCVM]), initiated in ­ depending of the origin and end use of the ­ wastewater. Atotonilco WWTP is the program’s biggest project; it The Atotonilco WWTP was designed to operate with includes the construction of a plant that aims to treat two treatment processes: (a) a physical-chemical 60 percent of the residual waters from the Valley of process train, based on chemically enhanced pri- Mexico, solve the flooding issues during the rainy sea- mary treatment (CEPT) to clean up storm water flow son, improve water quality for irrigation, and use the discharged to the river; and (b) a high-rate activated emission of methane from sludge digestion to gener- sludge (biological) treatment for wastewater flow ate ­electricity. ­ 017). This to be reused in irrigation (Acciona Agua 2 treatment scheme optimizes the plant resources and ­ osts. The waste- reduces significantly the operational c CHALLENGE water treated for irrigation purposes meets the quality Urban growth has led to increased wastewater flow, untreated irrigation water, and threats to public health standards (NOM 003-SEMARNAT) to be used to irrigate OBJECTIVE up to 90,000 hectares in the Mezquital Valley, which is • Improve the quality of life of the 700,000 inhabitants of the the largest agricultural district in Mexico (and probably Mezquital Valley wastewater. in Latin America) irrigated with ­ • Provide high-quality water for farmland irrigation In the process of sludge stabilization in the anaerobic • Decrease water consumption digesters, biogas is generated, which is used for the • Achieve high energy efficiency in the plant production of electricity for self-consumption and • Improve the quality of water feeding into natural systems for heating the digesters (combined heat and power • Generate direct employment during the plant’s construction system). The installed capacity of 32.4 megawatts ­ and operation provides about 60 percent of the plant’s electric- • Use market-based instruments for financing requirements. The gas engines also have a heat ity ­ 2 Wastewater: From Waste to Resource recovery system that supplies thermal energy to the wastewater. In 2010, the con- the Valley of Mexico’s ­ process. Therefore, the project can supply digestion ­ tract for the construction, operation, and mainte- most of its own energy needs, greatly minimizing nance was awarded to the consortium Aguas Tratadas energy costs and improving energy efficiency (Bello, del Valle de México (ATVM), comprised of the fol- ­ 016). Furthermore, in cap- Contreras, and Rodriguez 2 lowing organizations and businesses: Promotora del turing methane and using it to generate energy, the Desarrollo de América Latina, Atlatec, Acciona Agua, plant will reduce greenhouse gas (GHG) emissions by Controladora de Operaciones de Infraestructura, about 145,000 tons of carbon dioxide (CO2) per year, Desarrollo y Construcciones Urbanas, and Green Gas allowing the Atotonilco WWTP to get and monetize Energy. Pioneer Crossing ­ credits. Moreover, the biosolid (stabilized carbon ­ The contract between ATVM and CONAGUA was estab- sludge) produced meets the quality standards to be lished as a 25-year concession project financed by type C sludge, which, according to the NOM-004- Fondadin, the infrastructure national fund of Mexico SEMARNAT-2002 standard (SEMARNAT 2002), is suit- (Fondo Nacional de Infraestructura in spanish), and able for application in forests, soil enhancement, and investors. Despite the investment cost, this private ­ reused. Finally, agriculture, and therefore could be ­ project was funded without the support of any mul- the plant uses recycled or treated water for the opera- tilateral financial ­ institution. CONAGUA relied on tion of plant, reducing the use of potable water by 93 Fonadin, which normally subsidizes projects up to percent ( Bello, Contreras, and Rodriguez ­ 2016). ­ PPs. In this case, however, 40 percent of the costs of P All these processes make the Atotonilco WWTP a very the threshold was raised to 49 percent because of the innovative project that uses wastewater as a resource, project size and the relatively low tariffs charged to giving value to all its byproducts: reusing wastewater users. The project allowed for low tariffs due water ­ for irrigation, producing electricity and thermal energy to the project’s economies of scale, the optimized from its sludge, and providing suitable quality biosol- use of biogas (generation of electricity and thermal ­ se. From an environmental point of ids for beneficial u energy), and the combination of treatment technol- view, the project will enhance the water quality flow- wastewater. Much of ogies for different end uses of ­ ing to the nearby water bodies (El Salto River and the capital remained in the form of debt and equity, with Salto Tlamaco Canal), improving existing ­ habitats. Banobras (Mexico’s development bank) leading the debt financing and attracting commercial banks, so that most funding was still dependent on the sponsors Financial and Contract Agreements project. With the subsidy successfully completing the ­ The project was planned as a private-public partner- fixed at 49 percent during the tender process, the win- ship (PPP) under a design–build, operate and trans- ning bid was chosen on the basis of the lowest tariffs fer contract, needing an initial investment of around requested. Construction has been underway since 2011 ­ US$686 million, which the Mexican government could and the first phase became operational in 2014 (Kenny, ­ wn. In 2009, CONAGUA launched a not cover on its o Lavanchy, and Kjorstad ­ 2012). tender for a wastewater plant to treat 60 percent of Existing Regulation Total investment: Mex$9,389 mdp (US$686 million) NOM 003-SEMARNAT is a regulation that establishes FONADIN (%) 49 the minimum water quality requirements to be used Consortium of partners (%) 20 agriculture. However, it does not differentiate by for ­ Commercial banks (%) 31 crop or type of ­ soil. It also establishes that it is not Wastewater: From Waste to Resource 3 permitted to irrigate vegetables that are consumed raw NOM-004-SEMARNAT is a regulation that establishes wastewater. The regulation should be with untreated ­ the minimum quality of sludge (biosolids) to be used improved and include directives to regulate the use of agriculture. However, this for fertilizing purposes in ­ treated wastewater for irrigation purposes, therefore regulation does not include any directive related to the way. fostering this sustainable practice in a safe ­ sludge. amount (dose) or the management of the ­ Benefits Economic Environmental and Social • Energy efficiency and operational costs reduced: reduction of • Cleaner water is expected to improve the health and living energy consumption from external suppliers standard of 700,000 people in the Mezquital Valley and 300,000 • Potential extra revenue from carbon credits of up to US$2 million inhabitants who live and work directly within the irrigation zone • ATVM estimated a reduction of 145,000 tons of CO2 carbon • Low water tariffs given the economies of scale and the plant’s efficiency dioxide in average per year • Better water quality flowing back into the natural ecosystem, • Generation of around 4,000 new employments during construction, and will provide 150 permanent jobs during recharging aquifers operation (20 years) • Environmental remediation: the project has invested in • Better quality of irrigation water, allowing farmers to diversify or reforestation using native plant species, with the aim of recovering switch to up to 10 times higher value crops; Crop restrictions in and improving the quality of environmental services in the site quality. the region will be lifted given the improved water ­ • Mexico’s overall water treatment rate is expected to rise from • Possibility to use drip irrigation given the improved quality of the 36 percent to 60 percent water, increasing water efficiency • Health improvement: decrease of gastrointestinal and skin • Potential new economic activities such as fish farming and diseases rate in the area previously irrigated with raw wastewater ecotourism • Reference case of wastewater reuse for irrigation • Beneficial use of sludge (biosolids) Lessons Learned wastewater. An important objec- and end use of the ­ tive was to preserve most of the nutrients to provide Innovative institutional arrangements and agreements farmers. The treatment capacity added value for the ­ for the management and execution of the project of the plant has been adapted to current flows, taking ­(PPP). The Atotonilco WWTP project was built on a into account the seasonal climate differences that char- PPP scheme with an approximate total investment of acterize a region with a dry period of seven months million. The project incentivized private par- US$900 ­ ­ months. followed by a rainy season of five ­ ties to participate, given that the successful bidder would design, build, and operate the plant for 25 ­ years. Holistic approach and sustainability focus. Since the proj- Moreover, of the initial investment, the Government of ect’s inception, sustainability has played an important Mexico through FONADIN financed 49 percent instead role. The holistic approach resulted in the use of out- ­ of the usual 40 percent, reducing the perceived risks by puts that would otherwise go unused or used in less desirable. the investors and making it ­ valuable ways: methane is used for biogas energy gen- Multiquality of wastewater tailored for the different uses eration, and treated wastewater is used to improve purpose). The treatment technology has been (fit to ­ and expand crop irrigation in the ­ area. Moreover, customized for the project, depending on the origin ­ fficiency. the project focused on energy and water e 4 Wastewater: From Waste to Resource The WWTP has won the Infraestructuras 360° award decrease. Therefore, CONAGUA put productivity will ­ from the Inter-American Development Bank (IDB) in in place several stakeholder engagement programs recognition of the comprehensive implementation of a to (a) clarify the issue; (b) explain the new opportu- sustainability ­strategy. nities that will arise from using treated wastewater (such as switching to higher vale crops); and (c) enable Clear ­regulations. Given the potential innovative uses the farmers to use drip irrigation to optimize water for treated wastewater, clear regulations have helped ­use. A fideicomiso (trust) was created (Fideicomiso de to promote the use of all the resources in a safe and Infraestructura Ambiental de los Valles de Hidalgo) sustainable ­manner. to  enable proposals on integrated management of Stakeholder ­engagement. The farmers valued the water resources, advanced irrigation, and agricultural untreated wastewater and saw it as a right that they others. industrialization, among ­ ago. The access to had gained more than 50 years ­ The Atotonilco WWTP adds considerable social and untreated wastewater had allowed them to grow mar- financial value to its stakeholders through the intel- costs. Moreover, some ketable crops at low production ­ ligent resource recovery from ­ wastewater. Irrigation believed that the untreated wastewater and its nutri- with clean, treated wastewater will no longer pose ents led to higher than average ­ yields. Many are still a health risk to the farmers or consumers, and crop (as of 2017) unsure about the benefits of treated waste- diversity and agricultural profits can grow without water and fear that the utility will make them pay high restrictions. By including additional the need for crop ­ prices for the treated wastewater and that their crop elements such as energy generation and beneficial use of biosolids, the project maximized the ability to turn PROFILE resource. waste into a ­ NAME Atotonilco WWTP References Agua. ­ Acciona ­ Atotonilco.” Acciona ­ 2017. “EDAR ­ http://www.accio​ Agua. ­ LOCATION na-agua.com/es/areas-de-actividad/proyectos/dc-de-plantas-de-trata​ Atotonilco de Tula, Hidalgo (México) miento-de-agua/edar/atotonilco. SIZE J., ­ Bello, ­ ­. ­ C. Contreras, and J 2016. “Atotonilco Wastewater Rodriguez. ­ Nominal average treatment capacity of 35 m3/second and a Plant—Mexico.” Graduate School of Design, Harvard Treatment ­ maximum treatment capacity of 50 m3/second ­ (approx. 10 ­University. ­http://research.gsd.harvard.edu/zofnass/files/2016/08/05​ million people equivalent) _­Atotonilco_EN_FinalDocument.pdf. MAIN INNOVATIONS Agua). ­ CONAGUA (Comisión Nacional del ­ 2010. “Planta de Tratamiento Atotonilco.” CONAGUA, Mexico ­ de Aguas Residuales ­ http://www​ City. ­ Wastewater reuse for irrigation: 80,000 hectares of land .conagua.gob.mx/CONAGUA07/Publicaciones/Publicaciones/SGAPDS​ will be irrigated using treated effluent -19-11.pdf. Energy efficiency: biogas is used to generate thermal energy J., ­ Kenny, ­ J. ­ R. Lavanchy, and ­ 2012. “Emerging Partnerships: Kjorstad. ­ and electricity for self-supply (combined heat and power) Top 40 Public-Private Partnerships (PPPs) in Emerging ­Markets.” Working Multi-quality recycled water DC. ­ Paper 75838, World Bank, Washington, ­ http://documents.worldbank​ Transferred value to stakeholders .org/curated/en/735231468162282764/pdf/758380WP0Emerg00Box​ 374351​B00​PUBLIC0.pdf. TECHNOLOGY ­ evelopment). ­ OECD (Organisation for Economic Co-operation and D 2015. Co-generation Mexico.” OECD, “Estudios Territoriales de la OCDE—Valle de México, ­ Anaerobic digesters Mexico ­City. ­https://www.gob.mx/cms/uploads/attachment/file/56213​ /­valle-de-mexico-OCDE.pdf. Wastewater: From Waste to Resource 5 ­ ank. Some rights ­ © 2018 International Bank for Reconstruction and Development / The World B reserved. The find- ings, interpretations, and conclusions expressed in this work do not necessarily reflect the views of The World Bank, represent. The World Bank does not guarantee the accuracy its Board of Executive Directors, or the governments they ­ work. This work is subject to a CC BY ­ of the data included in this ­ (https://creativecommons.org/licenses​ 3.0 IGO license ­ by/3.0/igo). The World Bank does not necessarily own each component of the ­ /­ content. It is your responsibility to ­ wner. 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