Improving bio-treatability of alkoxylate wastewater treatment - a feasibility study
This study focuses on investigating the utilization of MBR-UF for alkoxylate wastewater treatment, with a specific emphasis on enhancing biodegradability and overall treatment efficiency. A new approach, such as the incorporation of ammonium acetate as co-substrate within the MBR system, was exp...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2023
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| Online Access: | https://hdl.handle.net/10356/172790 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This study focuses on investigating the utilization of MBR-UF for alkoxylate wastewater treatment, with a
specific emphasis on enhancing biodegradability and overall treatment efficiency. A new approach, such
as the incorporation of ammonium acetate as co-substrate within the MBR system, was explored to enhance
the biodegradability of this wastewater.
The research findings underscore the effectiveness of utilizing MBR-UF for the treatment of alkoxylate
industrial wastewater, enriched with nutrients. While specific data on the removal of individual alkoxylate
compounds are not provided in this study, there is a substantial collective reduction in these water quality
parameters (BOD5, COD, TOC, TDS, and Conductivity), which collectively represent the removal of
alkoxylates and other contaminants in the wastewater. Notably, the system exhibited exceptional overall
reductions in all the key water quality parameters. In the experiment conducted without co-substrate, COD
reductions of up to 97.38% were achieved, while the introduction of co-substrate pushed this reduction to
99.36%. Additionally, overall TOC reductions of 99.67% were observed without co-substrate, and 99.57%
with co-substrate, lastly, a significant BOD5 reduction reaching up to 98.89% without co-substrate and
99.32% with co-substrate was achieved. While both experiment settings demonstrated exceptional overall
removal efficiency, the experimental setting that incorporates the co-substrate displays superior removal
efficiency for all the parameters tested, with the exception of TOC, which exhibits similar removal
efficiency.
The outcomes of this study will contribute to the field of biological treatment improvement, offering
valuable insights that can influence the approach of wastewater engineers in controlling membrane fouling,
as well as enhancing microbial activity to effectively degrade organic matters in wastewater treatment
processes. |
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