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International experiences in waswater treatment and reuseIng. Gustavo Heredia9/23/2021
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1. Aquapolo (Brasil)2. Mapocho (Chile)3. Lake Managua (Nicargua)4. Lake Patzcuaro (México)5. Aguatuya (Bolivia)
Cases+
International experiences in wastewater treatment and reuse9-23-2021
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Aquapolo (Brasil)
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+ Metropolitan area of Sao Paulo (Brazil)
+ Year: 2012
+ Challenge: Wastewater treatment for industrial use
Background
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+ Establishment of Aquapolo Ambiental S.A. (Specific-purpose company whose
shareholders are SABESP and GS Inima Brazil)
+ Contract with Braskem signed in 2009 for 43 years and extendable +10 years
+ Investment: 23 M USD (75% BNDES and 25% shareholders)
+ Minimum demand: 300 litres/second
+ Capacity: 1,000 litters/second
The project
Treatment system for industrial reuse (Aquapolo, Brazil)
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Treatment and reuse system
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+ Current demand 650 litres/second
+ Proportional reduction in drinking water production
+ Client companies have reduced their water tariff by 33% in addition to reducing the use of chemicals
+ Companies stopped relying on water from the
Tamanduateí River
+ Stable supply (less dependent on weather conditions)
Impact / bennefits
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+ http://www.aquapolo.com.br/historia/
+ https://www.ecodebate.com.br/2019/04/25/sp-projeto-aquapolo-projeto-de-producao-de-agua-de-reuso-transforma-esgoto-tratado-em-agua-industrial-por-paulo-afonso-da-mata-machado/
+ https://climatesmartwater.org/wp-content/uploads/sites/2/2018/09/AIDIS-Uso_seguro_del_agua_26_sep.pdf (p.243)
+ http://site.sabesp.com.br/site/uploads/File/contratos_transparencia/aquapolo_plano_negocios.pdf
Reference
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Mapocho (Chile)
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+ Challenge: Polluted water in Rio Mapocho
(and others) causing diseases
+ Cholera outbreak in 1991
+ WW treatment program for Greater Santiago (2001-2012)
+ WWTPs: El Trebal (2001), La Farfana (2003)
and Mapocho (2012)
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Background
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+Owner: Aguas Andinas (An Agbar Group Suez subsidiary)
+Capacity: 380,000 m3/day
+Investment: 150 M USD
+Government subsidizes fees for low-income users. Tariffs areupdated every 5 year
The project
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Sistema de tratamiento / Reúso
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+Health risks were virtually eliminated
+Area under irrigation with safe water: 130,000 hectares
+High investment costs, carbon footprint of treatment processes
Impact / bennefits
+ https://www.researchgate.net/publication/321623748_Reutilizacion_de_aguas_para_agricultura_en_America_Latina_y_el_Caribe_Estado_principios_y_necesidades/link/5cd2bee7299bf14d957eaee5/download
+ https://www.suez-america-latina.com/es/ofertasoluciones/historias-de-exito/nuestras-referencias/la-farfana-en-chile
+ https://www.revistaei.cl/2012/04/19/planta-mapocho-recuperando-energia-a-partir-de-su-proceso-productivo/#
+ https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.464.4554&rep=rep1&type=pdf
Reference
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Lake Managua (Nicaragua)
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+ City of Managua (Nicaragua)
+ Year: 2009
+ Challenge: To protect Lake Managua (Xolotlan) from domestic and industrial wastewater pollution
Background
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+ Establishment of an environmental protection and rehabilitation programme
+ Objective: Municipal wastewater treatment
+ Treatment capacity: 297,000 m3/day (1.1 M e.g.)
+ Reuse: Indirect for water source, fishing, recreation
+ Reuse: Agriculture
The project
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+ Owner/Operator: Empresa Nicaragüense de Acueductos y Alcantarillados Sanitario (ENACAL)
+ Financing: German Development Bank (KfW)
+ Investment cost: 25 M €
El proyecto
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Sistema de tratamiento y reúso ENACAL (Managua)
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Tren de tratamiento
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Sludge treatment system
+ Greenhouse-type solar dryer in 1,310 m2
(11.3m x 116m) with forced ventilation
+ Mechanized turning
+ Drying time: 30 days
+ Final product: 87% dry matter
+ Energy consumption: 20 kWh vs. 800-1,000
kWh industrial dryers.
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+ Concentrations of DBO and OSH in the lake
reduced compared to levels before plant
+ Clearer water
+ Dissolved oxygen and phosphorus remain high
+ Pollution by industrial wastewater, solid
waste and nutrients from agriculture continues
Impact and challenges
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+ https://www.kfw.de/stories/environment/natural-resources/wastewater-treatment-managua/
+ https://www.fwt.fichtner.de/userfiles/fileadmin-fwt/201001_solarsludgedrying_managua.pdf
+ https://www.holcim.com.ni/comunicacion/de-nuestros-clientes/planta-de-tratamiento-de-aguas-residuales-de-managua
+ https://www.gwp.org/globalassets/global/gwp-cam_files/srh_nicaragua_2016.pdf
Reference
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Lake Patzcuaro (México)
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+ Micoacán State (Mexico)
+ Lake Patzcuaro basin in a tourist and recreational region including 4 municipalities and 120,000 inhabitants
+ State program for the recovery of the lake (2003):
+ Rio Arronte Foundation+ National Water Commission+ National Forestry Commission+ Mexican Institute of Water Technology (IMTA)
Background
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+ Low-cost technologies to avoid lake pollution
+ 6 municipal treatment systems
+ Capacity 43-432 m3/day
+ Reuse: Agricultural irrigation, fish farming, macrophyte production for handicrafts
Treatment systems
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Treatment train
Stabilization ponds Horizontal and vertical flow constructed wetlandsBar screen andgrit chamber
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Treatment efficiency
Parameter Santa Fé de la laguna CucuchuchoCOD reduction 91-93%BOD reduction 97% 94-98%TSS reducción 93-97%Total N reduction 87% 56-88%P reduction 65%
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+Between 2013 and 2016 operation and maintenance problems
+Wetland rehabilitation carried out
+O&M manuals were developed and operators were trained
Challenges
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+ https://publications.iadb.org/publications/spanish/document/Innovaciones-en-el-desarrollo-e-
implementacion-de-humedales-construidos-para-el-tratamiento-de-aguas-residuales-domesticas-en-Latinoamerica-y-El-Caribe.pdf
+ https://www.gob.mx/imta/videos/manejo-y-control-de-malezas-acuaticas-y-recuperacion-de-especies-emblematicas-del-lago-de-patzcuaro
+ https://sswm.info/sites/default/files/reference_attachments/SEGURA%20et%20al%202018.%20Seg
uimiento%20y%20rehabilitaci%C3%B3n%20de%20humedal.pdf
Reference
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Aguatuya (Bolivia)
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+ Small towns (5,000 – 30,000
inhabitants) polluted water basin
+ Existing agricultural activity in the region
+ Water source for irrigation rain and deep boreholes
Background
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Project area (3 municipal urban centres)
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+ Financing: Swedish cooperation (SIDA) in Bolivia in partnership with municipalities
+ Implementation agency: Aguatuya Foundation (engineering + management)
+ Reuse approach for agricultural irrigation
The project
Municipal WWT plant
Capacity [m3/day] Area [m2] Investment cost[USD]
Cliza 568 8.000 500.000
Tolata 326 2.930 258.000
Punata 2.530 50.000 1.200.000
www.aguatuyua.org
www.aguatuyua.org
www.aguatuyua.org
www.aguatuyua.org
Surface under irrigation with treated wastewater
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Treatment train
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Treatment efficiency
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Linear approach to WW treatment
Well
Well
City
Crops
River
Fert.
Drinking water
Drinking water
Untreated WW
Rain
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Well Ciudad
Crops
RiverWWTP Treated WWWastewaterDrinking water
Rain
RainFood
Treated WWwith nutrients
Aquifer recharge
Circular economy approach to wastewater treatment and reuse
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Impact of treatment and reuse
Parameter Linear economy
Circular economy
Change∆ ∆ %
Organic load discharged to the river[Kg BOD/year]
241.000 6.000 -235.000 -97%
Suspended solids discharged to the river[Kg TSS/year]
167.000 6.000 -161.000 -97%
Nutrients (N) discharged to the river [Kg/year]
37.000 14.000 -23.000 -62%
Nutrients (P) discharged to the river [Kg/year]
5.000 2000 -3.000 -57%
Underground water extraction[m3/year]
296.000 0 -296.000
Import or fertilizers (N and P) [Kg/year]
12.000 0 -12.000
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+ The level of treatment depends on the type of reuse intended
+ Depending on the local needs, you can opt for large, centralized systems or smaller distributed/ decentralized systems
+ Only a combination of distinct and complementary systems can solve the wastewater problem
+ Reuse in agricultural irrigation offers a triple benefit: Water conservation, nutrient recovery,
eutrophication prevention
+ Reuse generates opportunities for circular economy. Waste is turned into resources
Conclusions
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Let us develop a Compendiumof Sanitation Systems and Technologies for the Wider Caribbean Region
• BORDA is active in the Latin American and Caribbean region since 2010• First projects initiated in 2012 in Mexico and Nicaragua• Activities then spread to Haiti and Cuba • Regional office in Mexico City + country office in Managua 2015
Call for Action by a new project partnership between &
• Regionally contextualized and application-oriented• Different components of the sanitation service chain at your fingertips• Guidance on the selection of appropriate wastewater treatment solutions
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The session materials:
• Presentation • Recording
Can be found in the CReW+ Academy website
Link: https://academy.gefcrew.org/en/resources
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Thank you
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International experiences in wastewater treatment and reuse9-23-2021
Financiado por Co-implementado por Co-ejecutado por
