Impact of operational strategies on a sidestream enhanced biological phosphorus removal (S2EBPR) reactor in a carbon limited wastewater plant

Fabrizio Sabba*, McKenna Farmer, Zhen Jia, Francesco Di Capua, Patrick Dunlap, James Barnard, Cindy Dongqi Qin, Joseph A. Kozak, George Wells, Leon Downing

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

14 Scopus citations

Abstract

Water resource recovery facilities are faced with stringent effluent phosphorus limits to reduce nutrient pollution. Enhanced biological phosphorus removal (EBPR) is the most common biological route to remove phosphorus; however, many facilities struggle to achieve consistent performance due to limited carbon availability in the influent wastewater. A promising process to improve carbon availability is through return activated sludge (RAS) fermentation via sidestream EBPR (S2EBPR). In this study, a full-scale S2EBPR pilot was operated with a sidestream plus carbon configuration (SSRC) at a carbon-limited facility. A model based on the pilot test was developed and calibrated in the SUMO platform and used to explore routes for improving orthophosphate (OP) effluent compliance. Modeling results showed that RAS diversion by itself was not sufficient to drive OP removal to permit limits of 1 mg L−1, therefore, other strategies were evaluated. Supplemental carbon addition of MicroC® at 1.90 L min−1 and controlling the phosphorus concentration below 3.5 mgP L−1 in the primary effluent (PE) proved to be valid supplemental strategies to achieve OP removal below 1 mg L−1 most of the time. In particular, the proposed supplemental carbon flow rate would result in an improvement of the rbCOD:P ratio from 17:1 to 26:1. The synergistic approach of RAS diversion and supplemental carbon addition increased the polyphosphate accumulating organisms (PAO) population while minimizing the supplemental carbon needed to achieve consistent phosphorus removal. Overall, this pilot and modeling study shows that joint strategies, including RAS diversion, carbon addition and PE control, can be effective to achieve optimal control of OP effluent.

Original languageEnglish (US)
Article number159280
JournalScience of the Total Environment
Volume857
DOIs
StatePublished - Jan 20 2023

Funding

The authors would like to thank Calumet Water Reclamation Plant operations and the Metropolitan Water Reclamation District of Greater Chicago for onsite testing facilities and assistance. McKenna Farmer and Dr. George Wells were supported in part by the Israel-U.S. Collaborative Water-Energy Research Center (CoWERC), via the Binational Industrial Research and Development Foundation (BIRD) Energy Center grant EC-15. The authors would like to thank Calumet Water Reclamation Plant operations and the Metropolitan Water Reclamation District of Greater Chicago for onsite testing facilities and assistance. McKenna Farmer and Dr. George Wells were supported in part by the Israel-U.S. Collaborative Water-Energy Research Center (CoWERC), via the Binational Industrial Research and Development Foundation (BIRD) Energy Center grant EC-15.

Keywords

  • GAO
  • Microbial ecology
  • PAO
  • Phosphorus
  • RAS fermentation
  • S2EBPR

ASJC Scopus subject areas

  • Pollution
  • Waste Management and Disposal
  • Environmental Engineering
  • Environmental Chemistry

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