The feasibility of AOPs and an SBR for treating wastewater from polyurethane manufacturing

• Autorzy: Li A. , He M. , Dong N. , Xu W. , Pan T.
• Języki publikacji: EN

Abstrakty

EN

We studied the feasibility of two advanced oxidation processes (AOPs), including the Fenton and ozonation processes, and a conventional sequence batch reactor (SBR) for treating wastewater from polyurethane manufacturing. The results showed that the SBR achieved a COD removal rate of 93.3% when the influent COD concentration was 1,600 mg·L-1, which was 22.1 and 522.1% higher than the best results by the Fenton (H2O2/COD = 0.0623 mM·g-1 and Fe2+/COD = 0.0102 mM·g-1) and ozonation (1 g·L-1, 45 min) processes. A COD removal rate of 90.6% for SBR was achieved after an aeration time of 12 h, and the COD degradation rate was similar to that of a zero-order reaction. A study of the SBR drivers suggested that air stripping and self-volatilization contributed to the higher COD removal rates obtained in this process. This study shows that a single SBR is practical for treating small amounts of polyurethane manufacturing wastewater, and that it had a higher ability to remove COD and resist feeding load shock than the other methods tested. But the potential risks of volatile organic compounds (VOCs) stripping out during the aeration process should be of concern.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2014
• Tom: 23
• Numer: 4
• Opis fizyczny: p.1219-1225,fig.,ref.

Twórcy

autor

Li A.

• Beijing Municipal Research Institute of Environmental Protection, State Environmental Protection Engineering (Beijing) Center for Industrial Wastewater Pollution Control, No. 59, Beiyingfang Zhongjie, Xicheng District, Beijing, 100037 P.R. China

autor

He M.

• Beijing Municipal Research Institute of Environmental Protection, State Environmental Protection Engineering (Beijing) Center for Industrial Wastewater Pollution Control, No. 59, Beiyingfang Zhongjie, Xicheng District, Beijing, 100037 P.R. China

autor

Dong N.

• Beijing Municipal Research Institute of Environmental Protection, State Environmental Protection Engineering (Beijing) Center for Industrial Wastewater Pollution Control, No. 59, Beiyingfang Zhongjie, Xicheng District, Beijing, 100037 P.R. China

autor

Xu W.

• Beijing Municipal Research Institute of Environmental Protection, State Environmental Protection Engineering (Beijing) Center for Industrial Wastewater Pollution Control, No. 59, Beiyingfang Zhongjie, Xicheng District, Beijing, 100037 P.R. China

autor

Pan T.

• Beijing Municipal Research Institute of Environmental Protection, State Environmental Protection Engineering (Beijing) Center for Industrial Wastewater Pollution Control, No. 59, Beiyingfang Zhongjie, Xicheng District, Beijing, 100037 P.R. China

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