Evaluating the Effectiveness of Coagulation–Flocculation Treatment Using Aluminum Sulfate on a Polluted Surface Water Source: A Year-Long Study

Safeguarding drinking water is a major public health and environmental concern because it is essential to human life but may contain pollutants that can cause illness or harm the environment. Therefore, continuous research is necessary to improve water treatment methods and guarantee its quality. As...

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Published in:Water (Basel) 2024-01, Vol.16 (3), p.400
Main Authors: Tahraoui, Hichem, Toumi, Selma, Boudoukhani, Meriem, Touzout, Nabil, Sid, Asma Nour El Houda, Amrane, Abdeltif, Belhadj, Abd-Elmouneïm, Hadjadj, Mohamed, Laichi, Yacine, Aboumustapha, Mohamed, Kebir, Mohammed, Bouguettoucha, Abdellah, Chebli, Derradji, Assadi, Aymen Amin, Zhang, Jie
Format: Article
Language:English
Subjects:
Algeria
Aluminum
Aluminum sulfate
Aquatic resources
Chemical Sciences
Climate change
Drinking water
Efficiency
France
Heavy metals
Mathematical models
Nitrates
Performance evaluation
Pollutants
Pollution
Public health
Sedimentation & deposition
Support vector machines
Surface water
United Kingdom
Water quality
Water shortages
Water treatment
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Summary:Safeguarding drinking water is a major public health and environmental concern because it is essential to human life but may contain pollutants that can cause illness or harm the environment. Therefore, continuous research is necessary to improve water treatment methods and guarantee its quality. As part of this study, the effectiveness of coagulation–flocculation treatment using aluminum sulfate (Al2(SO4)3) was evaluated on a very polluted site. Samplings were taken almost every day for a month from the polluted site, and the samples were characterized by several physicochemical properties, such as hydrogen potential (pH), electrical conductivity, turbidity, organic matter, ammonium (NH+4), phosphate (PO43−), nitrate (NO3−), nitrite (NO2−), calcium (Ca2+), magnesium (Mg2+), total hardness (TH), chloride (Cl−), bicarbonate (HCO3−), sulfate (SO42−), iron (Fe3+), manganese (Mn2+), aluminum (Al3+), potassium (K+), sodium (Na+), complete alkalimetric titration (TAC), and dry residue (DR). Then, these samples were treated with Al2(SO4)3 using the jar test method, which is a common method to determine the optimal amount of coagulant to add to the water based on its physicochemical characteristics. A mathematical model had been previously created using the support vector machine method to predict the dose of coagulant according to the parameters of temperature, pH, TAC, conductivity, and turbidity. This Al2(SO4)3 treatment step was repeated at the end of each month for a year, and a second characterization of the physicochemical parameters was carried out in order to compare them with those of the raw water. The results showed a very effective elimination of the various pollutions, with a very high rate, thus demonstrating the effectiveness of the Al2(SO4)3. The physicochemical parameters measured after the treatment showed a significant reduction in the majority of the physicochemical parameters. These results demonstrated that the coagulation–flocculation treatment with Al2(SO4)3 was very effective in eliminating the various pollutions present in the raw water. They also stress the importance of continued research in the field of water treatment to improve the quality of drinking water and protect public health and the environment.
ISSN:2073-4441
2073-4441
DOI:10.3390/w16030400