Litcius/Paper detail

Enhancing sludge dewaterability and phosphate removal through a novel chemical dosing strategy using ferric chloride and hydrogen peroxide

Vahid Ghodsi, Siva Sarathy, John R. Walton, Ian C. Watson, Elsayed Elbeshbishy, Domenico Santoro

2020Water Environment Research11 citationsDOI

Abstract

Abstract In this study, we replicated full‐scale centrifuge dewatering utilized in water resource recovery facilities (WRRFs) by using the Higgins modified centrifuge technique and demonstrated that analogous cake solid content and centrate suspended solids were attainable while applying a lower polymer dosage. Furthermore, we demonstrated a dramatic reduction in the concentration of phosphate (P) in anaerobically digested sludge (ADS) under various reaction conditions. H 2 O 2 was employed to convert embedded iron in ADS, in the form of FeS, to Fe (II) and Fe (III), which subsequently reacted to precipitate phosphate compounds, dropping the in situ P concentration by nearly 50%. Adding ferric chloride (220 mg/L) in ADS enhanced the P‐removal to more than 80%. Finally, simultaneous dosing of Fe and H 2 O 2 boosted P‐removal efficiency to higher than 90%. The role of Fe in strengthening the flocs and increasing the dewaterability was also substantiated by demonstrating a 2% growth in the cake solid content when ADS was conditioned with Fe + H 2 O 2 preceding polymer treatment. The outcome of this work confirms that a deeper understanding of centrifuge operational parameters and physico‐chemical properties of wastewater sludge would result in improved performance of municipal WRRFs. Practitioner points Dosing hydrogen peroxide effectively converted iron embedded in sludge from Fe (II) to Fe (III). Simultaneous dosing of iron and hydrogen peroxide boosted P removal efficiency. The role of iron in strengthening flocs and enhancing dewaterability was observed, as it increased cake solid content in centrifuged sludge. An advanced bench‐scale test protocol was employed to optimize polymer dose, simultaneously reducing polymer consumption while maximizing cake solid content and centrate quality.

Topics & Concepts

Hydrogen peroxideFerricChemistryDewateringPhosphateAlumChlorideFlocculationNuclear chemistryWastewaterPulp and paper industryInorganic chemistryWaste managementOrganic chemistryEngineeringGeotechnical engineeringPhosphorus and nutrient managementCoagulation and Flocculation StudiesConstructed Wetlands for Wastewater Treatment