RT info:eu-repo/semantics/article
T1 Quantitative assessment of energy and resource recovery in wastewater treatment plants based on plant-wide simulations
A1 Fernández Arévalo, Tamara
A1 Lizarralde, Izaro
A1 Fernández-Polanco Fernández de Moreda, Fernando
A1 Pérez Elvira, Sara Isabel
A1 Garrido, Juan Manuel
A1 Puig, Sebastiá
A1 Poch Espallargas, Manuel
A1 Grau, P.
A1 Ayesa, Eduardo
K1 Aguas residuales
AB The growing development of technologies and processes for resource treatment and recovery is offering endless possibilities for creating new plant-wide configurations or modifying existing ones. However, the configurations’ complexity, the interrelation between technologies and the influent characteristics turn decision-making into a complex or unobvious process. In this frame, the Plant-Wide Modelling (PWM) library presented in this paper allows a thorough, comprehensive and refined analysis of different plant configurations that are basic aspects in decision-making from an energy and resource recovery perspective. In order to demonstrate the potential of the library and the need to run simulation analyses, this paper carries out a comparative analysis of WWTPs, from a techno-economic point of view. The selected layouts were (1) a conventional WWTP based on a modified version of the Benchmark Simulation Model No. 2, (2) an upgraded or retrofitted WWTP, and (3) a new Wastewater Resource Recovery Facilities (WRRF) concept denominated as C/N/P decoupling WWTP. The study was based on a preliminary analysis of the organic matter and nutrient energy use and recovery options, a comprehensive mass and energy flux distribution analysis in each configuration in order to compare and identify areas for improvement, and a cost analysis of each plant for different influent COD/TN/TP ratios. Analysing the plants from a standpoint of resources and energy utilization, a low utilization of the energy content of the components could be observed in all configurations. In the conventional plant, the COD used to produce biogas was around 29%, the upgraded plant was around 36%, and 34% in the C/N/P decoupling WWTP. With regard to the self-sufficiency of plants, achieving self-sufficiency was not possible in the conventional plant, in the upgraded plant it depended on the influent C/N ratio, and in the C/N/P decoupling WWTP layout self-sufficiency was feasible for almost all influents, especially at high COD concentrations. The plant layouts proposed in this paper are just a sample of the possibilities offered by current technologies. Even so, the library presented here is generic and can be used to construct any other plant layout, provided that a model is available
PB Elsevier
YR 2017
FD 2017
LK http://uvadoc.uva.es/handle/10324/26426
UL http://uvadoc.uva.es/handle/10324/26426
LA eng
NO Water Research, 2017, Volume 118, p.  272-288
NO Producción Científica
DS UVaDOC
RD 24-abr-2024