Abstract
Wastewater from fertilizer industries is rich in ammoniacal nitrogen and orthophosphates. The present study demonstrates the recovery of nutrients from fertilizer industry effluent in the form of microalgal biomass to produce various bioproducts. The study demonstrates the integration of pilot-scale struvite production from fertilizer industrial wastewater in air-agitated reactor to phycoremediation of residual wastewater. The parameters required for the production of high yield and better quality of struvite were optimized. The microalgal consortium was isolated from anaerobic plant digestate and adapted to tolerate 1000 mg L−1 of NH4-N using synthetic wastewater rich in NH4-N. Pilot-scale struvite production was carried out in the air-agitated reactor (1 m3 capacity) in batch mode and phycoremediation of residual effluent was carried out in tubular photobioreactor (200 L capacity) in fed batch mode. Pilot-scale struvite crystallization produced 60 kg of struvite from 1 m3 of effluent. During struvite precipitation, 2.96% of COD, 68.29% of NH4-N, and 96.38% of PO4-P were recovered. The residual effluent was further phycoremediated by the microalgal consortium. During phycoremediation, 62.68% of COD, 59.21% of NH4-N, and 68.57% of PO4-P were recovered in terms of microalgal biomass. Due to integration, 64.58% of COD, 87.31% of NH4-N, 89.0% of TKN, and 98.79% of PO4-P are recovered. The observed yield (g m−3 effluent) of biomass, lipids, ω-3 fatty acid, and biogas (L m−3 effluent) was 290, 56, 11.2, and 80 L, respectively. In brief, the integration of struvite production and microalgae cultivation can be used as an effective treatment system for fertilizer industry wastewater.
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Acknowledgments
The authors would like to thank BITS Pilani, Centre of Research Excellence for providing the funds to carry out this research under the theme Wastewater and Energy. The authors would also like to thank Ms. Megha Shinge (Karnataka University, Dharwad) and Ms. Jyoti Singh (Indian Institute of Technology, Roorkee) for helping us in FTIR, Raman spectroscopy, and FAME analysis. The authors would also like to thank Dr. Lalita Baragi for helping us with statistical analysis of data.
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Conception and design of study: Srikanth Mutnuri and Ram Chavan
Acquisition of data: Ram Chavan and Srikanth Mutnuri
Analysis and interpretation of data: Srikanth Mutnuri and Ram Chavan
Writing and Revision of manuscript: Ram Chavan and Srikanth Mutnuri
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Chavan, R., Mutnuri, S. Demonstration of pilot-scale integrative treatment of nitrogenous industrial effluent for struvite and algal biomass production. J Appl Phycol 32, 1215–1229 (2020). https://doi.org/10.1007/s10811-019-01978-4
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DOI: https://doi.org/10.1007/s10811-019-01978-4