Journal
PROCESS SAFETY AND ENVIRONMENTAL PROTECTION
Volume 158, Issue -, Pages 486-494Publisher
ELSEVIER
DOI: 10.1016/j.psep.2021.12.035
Keywords
Alum sludge; Treatment wetlands; Emerging pollutants; Upgrading treatment; Phosphorus removal; Pathogens removal
Categories
Funding
- Generalitat Valenciana-IVACE (Valencian Institute of Business Competitiveness)
- European Regional Development Fund
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The study focuses on utilizing DWTS as a substrate for constructed wetlands to improve urban wastewater treatment, with emphasis on nutrient and organic matter removal, as well as the removal of emerging contaminants and pathogens.
Drinking water treatment sludge (DWTS) is the main waste produced in drinking water treatment plants (DWTPs). Its valorisation as substrate for constructed wetlands (CWs) aimed at upgrading treated urban wastewater is presented. Keeping a holistic approach in mind, this study looks for nutrient and organic matter removal but also contaminants of emerging concern (CECs) and pathogens. Three pilot subsurface flow CWs (1 m2) were installed under outdoor conditions in real WWTPs. Different operation modes (sequential: S-CW and continuous saturated flow: C-CW, CC-CW), different nutrient influent concentrations (SCW and C-CW: 0.6 mg TP/l, 12.7 mg TN/l; CC-CW: 6.5 mg TP/l, 48 mg TN/l) and high hydraulic loading rates (HLRs, 0.9-5.1 m3/m2/d) were tested. C-CW presented higher removal efficiencies than S-CW for TP (C-CW: 56-86%; S-CW: 32-66%), total nitrogen (C-CW: 23-38%; S-CW: -3 to 6%) and E. coli (C-CW: 94%; S-CW: 84%), while S-CW performed better for ammonium (C-CW: 29-45%; S-CW: 72-86%) and CECs removal. Among fifteen CECs monitored, most pharmaceuticals, four were significantly reduced in C-CW and nine in S-CW, which had more aerobic conditions. CC-CW reduced nutrients and organic matter by 62% (TP), 8% (TN), 23% and 40% (chemical and biochemical oxygen demands, respectively). The potential release of aluminium was negligible. Novel values for the first-order reaction coefficient of P-k-C* model are provided for the TP removal process using DWTS (0.6-1.0 h-1). The main conclusion is that DWTS is a suitable substrate to significantly upgrade WWTP effluents, even at high HLRs. A hybrid system combining sequential and continuous flow modes could optimize the upgrading treatment. A proposal for the full valorisation of the sludge produced in one DWTP is presented. (c) 2021 Institution of Chemical Engineers. Published by Elsevier B.V. All rights reserved.
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