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Study of the Potential for Agricultural Reuse of Urban Wastewater with Membrane Bioreactor Technology in the Circular Economy Framework
The growing demand for water by the population and industry, as well as water scarcity due to climate change, has created a need to reuse treated water for agricultural purposes. In this context, the European Union, through its Regulation (EU) 2020/741, establishes minimum requirements for wastewate...
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| Published in: | Agronomy (Basel) 2022-08, Vol.12 (8), p.1877 |
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| cites | cdi_FETCH-LOGICAL-c418t-99101f3c59d6caffd4b36e8189098e8792e11b19709903b6f8dd4b84ee1948143 |
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| container_title | Agronomy (Basel) |
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| creator | Antiñolo Bermúdez, Laura Leyva Díaz, Juan Carlos Martín Pascual, Jaime Muñío Martínez, María del Mar Poyatos Capilla, José Manuel |
| description | The growing demand for water by the population and industry, as well as water scarcity due to climate change, has created a need to reuse treated water for agricultural purposes. In this context, the European Union, through its Regulation (EU) 2020/741, establishes minimum requirements for wastewater reuse, specifying that reuse for agricultural purposes can help to promote the circular economy and reduce the need for fertiliser use by setting high-quality standards. The aim of this article is to study whether the treated water from a pilot plant with membrane bioreactor technology operating with real urban wastewater from the city of Granada (Spain) satisfies the quality standards required for its reuse for agricultural purposes, as well as assessing the use of other resources produced during wastewater treatment, such as biogas and biostabilised sludge. This plant works in four cycles of operation at two different hydraulic retention times (6 and 12 h) and different concentrations of mixed liquor (2429–6696 mg/L). The pilot plant consists of a membrane bioreactor where there are four ultrafiltration membranes working in continuous operation and a sludge treatment line working in discontinuous mode. Subsequently, a tertiary treatment of advanced oxidation process was applied to the treated water for a time of 30 min, with different concentrations of oxidant. The results showed that the effluent has sufficient quality to be used in agriculture, complying with the characteristics established in the European legislation. Furthermore, the biostabilised sludge and biogas can be potentially reusable. |
| doi_str_mv | 10.3390/agronomy12081877 |
| format | article |
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| subjects | Agricultural wastes Agriculture Alternative energy sources Biogas Biomass energy Bioreactors Circular economy Climate change Climatic changes Consumption E coli Irrigation Laws, regulations and rules Legislation membrane bioreactor Membranes Nematodes Oxidants Oxidation Oxidation process Oxidizing agents Pathogens Pilot plants Purification Quality standards Raw materials Retention reuse Sewage Sludge Sludge treatment Tertiary treatment Treated water Ultrafiltration Urban agriculture Wastewater reuse Wastewater treatment Water demand Water reuse Water scarcity Water shortages Water treatment |
| title | Study of the Potential for Agricultural Reuse of Urban Wastewater with Membrane Bioreactor Technology in the Circular Economy Framework |
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