Preparation of a composite coagulant: Polymeric aluminum ferric sulfate (PAFS) for wastewater treatment

A new composite coagulant polymeric aluminum ferric was synthesized and parameters affecting the coagulant performance such as reaction temperature and time, and OH/Fe, P/Fe and Al/Fe molar ratios in this study, were examined. In addition, to obtain the optimum synthetic conditions resulting in the...

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Bibliographic Details
Published in:Desalination 2012-01, Vol.285 (31), p.315-323
Main Authors: Zhu, Guocheng, Zheng, Huaili, Chen, Wenyuan, Fan, Wei, Zhang, Peng, Tshukudu, Tiroyaone
Format: Article
Language:English
Subjects:
Adsorption
agitation
Aluminum
Applied sciences
Chemical engineering
chemical oxygen demand
Coagulants
Coagulation
Coagulation–flocculation process
colloids
Composite coagulant
desalination
Exact sciences and technology
ferric sulfate
General purification processes
Iron
Iron-based coagulant
neutralization
Optimization
Oxygen demand
Pollution
Polymeric aluminum ferric sulfate
response surface methodology
temperature
Turbidity
Waste water
wastewater
wastewater treatment
Wastewaters
Water purification
Water treatment and pollution
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Summary:A new composite coagulant polymeric aluminum ferric was synthesized and parameters affecting the coagulant performance such as reaction temperature and time, and OH/Fe, P/Fe and Al/Fe molar ratios in this study, were examined. In addition, to obtain the optimum synthetic conditions resulting in the maximum turbidity removal efficiency, response surface methodology (RSM) was used to assess their interactive effects on coagulation–flocculation performance. The results showed that reaction temperature (60–80 °C) and time (30–50 min), and OH/Fe (0.1–0.3), P/Fe (0.2–0.3) and Al/Fe (1:9–1:10) molar ratios were favorable to the preparation process. The optimum synthesis conditions were reaction temperature and time, and OH/Fe, P/Fe and Al/Fe molar ratios of 80 °C, 40 min, 0.1, 0.25 and 1:10, respectively. Evaluation of the coagulation–flocculation process showed that COD (chemical oxygen demand) and turbidity removal efficiency of 82.8% and 98.2%, respectively, were achieved at coagulant dosage of 45 mg/L, wastewater initial pH of 8.5, and rapid agitation speed of 250 rpm. In addition, charge neutralization and adsorption/bridging coagulation–flocculation mechanisms played an important role in reducing the surface charge of colloids. ► Polymeric aluminum ferric sulfate was a non-stoichiometric basic iron sulfate salt. ► Reaction temperature and time, and Al/Fe, OH/Fe and P/Fe molar ratio, were examined. ► Coagulant dosage, agitation speed and wastewater initial pH were experimentally tested. ► Charge neutralization and adsorption/bridging were the flocculation mechanisms.
ISSN:0011-9164
1873-4464
DOI:10.1016/j.desal.2011.10.019