Abstract
Performances of biological treatment processes of saline wastewater are usually low because of adverse effects of salt on microbial flora. High salt concentrations in wastewater cause plasmolysis and loss of activity of cells resulting in low COD removal efficiencies. In order to improve biological treatment performance of saline wastewater, a halophilic organism Halobacter halobium was used along with activated sludge culture.
A synthetic wastewater composed of diluted molasses, urea, KH2PO4 and various concentrations of salt (1%–5% NaCl) was treated in an aerobic-biological reactor by fed-batch operation. Activated sludge culture with and without Halobacter were used as seed cultures. Variations of COD removal rate and efficiency with salt concentration were determined for both cultures and results were compared. Inclusion of Halobacter into activated sludge culture resulted in significant improvements in COD removal efficiency. A rate expression including salt inhibition effect was proposed and kinetic constants were determined by using experimental data.
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This study was supported by the Technical and Scientific Research Council of Turkey.
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Kargi, F., Dinçer, A.R. Enhancement of biological treatment performance of saline wastewater by halophilic bacteria. Bioprocess Engineering 15, 51–58 (1996). https://doi.org/10.1007/BF00435529
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DOI: https://doi.org/10.1007/BF00435529