Search results for "Biological nutrient removal"

showing 4 items of 4 documents

Integrated Fixed Film Activated Sludge (IFAS) membrane BioReactor: The influence of the operational parameters

2020

Abstract The present paper investigated an Integrated Fixed Film Activated Sludge (IFAS) Membrane BioReactor (MBR) system monitored for 340 days. In particular, the short-term effects of some operational parameters variation was evaluated. Results showed a decrease of the removal rates under low C/N values. Respirometry results highlighted that activated sludge was more active in the organic carbon removal. Conversely, biofilm has a key role during nitrification. The major fouling mechanism was represented by the cake deposition (irreversible).

0106 biological sciencesMembrane foulingEnvironmental EngineeringBiological nutrient removalBioengineering010501 environmental sciencesMembrane bioreactor01 natural sciencesRespirometryBioreactors010608 biotechnologyDeposition (phase transition)Waste Management and Disposal0105 earth and related environmental sciencesFoulingSewageSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleRenewable Energy Sustainability and the EnvironmentChemistryMembrane foulingMembranes ArtificialGeneral MedicineRespirometryPulp and paper industryIFASNitrificationActivated sludgeBiofilmsMembrane bioreactorNitrification
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Application of the General Model "Biological Nutrient Removal Model No.1" to upgrade two full-scale WWTPs

2012

In this paper, two practical case studies for upgrading two wastewater treatment plants (WWTPs) using the general model BNRM1 (Biological Nutrient Removal Model No. 1) are presented. In the first case study, the Tarragona WWTP was upgraded by reducing the phosphorus load to the anaerobic digester in order to minimize the precipitation problems. Phosphorus load reduction was accomplished by mixing the primary sludge and the secondary sludge and by elutriating the mixed sludge. In the second case study, the Alcantarilla WWTP, the nutrient removal was enhanced by maintaining a relatively low dissolved oxygen concentration in Stage A to maintain the acidogenic bacteria activity. The VFA produce…

AcidogenesisBiological nutrient removalWATER TREATMENT PLANTSAerobic bacteriachemistry.chemical_elementActivated sludge modelPhosphatesWater PurificationWASTE-WATERBNRM1Environmental ChemistryAnaerobiosisOrganic ChemicalsWaste Management and DisposalTECNOLOGIA DEL MEDIO AMBIENTEWater Science and TechnologyCALIBRATIONSewagePhosphorusEnvironmental engineeringGeneral MedicineModels TheoreticalASM2DAerobiosisACTIVATED-SLUDGE MODELActivated sludge modelsEnhanced biological phosphorus removalWastewaterchemistrySIMULATIONPlant-wide mathematical modellingEnvironmental scienceSewage treatmentWater treatmentSanitary EngineeringWWTP upgrading
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Bacterial Community Structure of an IFAS-MBRs Wastewater Treatment Plant

2017

TIn this work, the bacterial community putatively involved in BNR events of a UCT-MBMBR pilot plant was elucidated by both culture-dependent and metagenomics DNA analyses. The presence of bacterial isolates belonging to Bacillus (in the anoxic compartment) and to Acinetobacter, Stenotrophomonas, Rhodococcus, Escherichia and Aeromonas (in the aerobic compartment) is in agreement with the nitrification/denitrification processes observed in the plant. Moreover, the study of bacterial community structure by NGS revealed a microbial diversity suggesting a biochemical complexity which can be further explored and exploited to improve UCT-MBMBR plant performance.

Bacterial communities NGS Biological nutrient removal Wastewater treatment plant Membrane bioreactors MBBR Enhanced biological phosphorus removal IFAS-MBRDenitrificationbiologySettore ICAR/03 - Ingegneria Sanitaria-AmbientaleWastewater treatment plantIFAS-MBRfungiMembrane Bioreactorfood and beveragesAcinetobacterbiology.organism_classificationSettore BIO/19 - Microbiologia GeneraleAnoxic watersBiological Nutrient RemovalMicrobiologyAeromonasMetagenomicsNGSMBBREnhanced biological phosphorus removalNitrificationStenotrophomonasRhodococcusBacterial Communitie
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Solids and Hydraulic Retention Time Effect on N2O Emission from Moving-Bed Membrane Bioreactors

2018

Biological nutrient removal was operated at different solids (SRT) and hydraulic retention times (HRT) in order to assess their influence on nitrous oxide (N2O) emission from a hybrid moving-bed membrane bioreactor. The observed results show that the N2O production decreased when the SRT/HRT was decreased. The maximum N2O gaseous concentration was measured in the aerobic reactor at the end of phase I, and it decreased through phases II and III. From mass balances over the reactors of the system, the aerated (aerobic and membrane) reactors were the largest producers of N2O, showing that the greater part of N2O was produced during the nitrification process.

Petroleum engineeringHydraulic retention timeBiological nutrient removalSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleChemistryGeneral Chemical Engineering0208 environmental biotechnologyN2OChemistry (all)02 engineering and technologyGeneral Chemistry010501 environmental sciences01 natural sciencesIndustrial and Manufacturing Engineering020801 environmental engineeringMembraneSolids retention timeBioreactorIntegrated fixed-film activated-sludge membrane bioreactorChemical Engineering (all)Moving bedHydraulic retention time0105 earth and related environmental sciences
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