6533b821fe1ef96bd127ba54
RESEARCH PRODUCT
Uncertainty and sensitivity analysis for reducing greenhouse gas emissions from wastewater treatment plants.
Alida CosenzaGiorgio ManninaTaise Ferreira Rebouçassubject
Environmental EngineeringNitrogen0208 environmental biotechnology02 engineering and technology010501 environmental sciencesWastewater01 natural sciencesWaste Disposal FluidGreenhouse gas emissionModellingGreenhouse GasesWaste WaterScenario analysisEffluentUncertainty analysis0105 earth and related environmental sciencesWater Science and TechnologyBiological Oxygen Demand AnalysisEnergy demandSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleChemical oxygen demandEnvironmental engineeringUncertainty020801 environmental engineeringWastewaterGreenhouse gasEnvironmental scienceNitrificationPlant-wide assessmentWaste disposaldescription
Abstract This paper presents the sensitivity and uncertainty analysis of a plant-wide mathematical model for wastewater treatment plants (WWTPs). The mathematical model assesses direct and indirect (due to the energy consumption) greenhouse gases (GHG) emissions from a WWTP employing a whole-plant approach. The model includes: i) the kinetic/mass-balance based model regarding nitrogen; ii) two-step nitrification process; iii) N2O formation both during nitrification and denitrification (as dissolved and off-gas concentration). Important model factors have been selected by using the Extended-Fourier Amplitude Sensitivity Testing (FAST) global sensitivity analysis method. A scenario analysis has been performed in order to evaluate the uncertainty related to all selected important model factors (scenario 1), important model factors related to the influent features (scenario 2) and important model factors related to the operational conditions (scenario 3). The main objective of this paper was to analyse the key factors and sources of uncertainty at a plant-wide scale influencing the most relevant model outputs: direct and indirect (DIR,CO2eq and IND,CO2eq, respectively), effluent quality index (EQI), chemical oxygen demand (COD) and total nitrogen (TN) effluent concentration (CODOUT and TNOUT, respectively). Sensitivity analysis shows that model factors related to the influent wastewater and primary effluent COD fractionation exhibit a significant impact on direct, indirect and EQI model factors. Uncertainty analysis reveals that outflow TNOUT has the highest uncertainty in terms of relative uncertainty band for scenario 1 and scenario 2. Therefore, uncertainty of influential model factors and influent fractionation factors has a relevant role on total nitrogen prediction. Results of the uncertainty analysis show that the uncertainty of model prediction decreases after fixing stoichiometric/kinetic model factors.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-05-15 | Water science and technology : a journal of the International Association on Water Pollution Research |