Optimizing Textile Wastewater Treatment  Using Electrocoagulation and Multimedia  Filtration Strategies for Enhanced Efficiency

Islam, Labeba; Lusaba, Tasfiah Kowser

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dc.contributor.author	Islam, Labeba
dc.contributor.author	Lusaba, Tasfiah Kowser
dc.date.accessioned	2025-02-24T07:07:19Z
dc.date.available	2025-02-24T07:07:19Z
dc.date.issued	2024-06-10
dc.identifier.citation	• Amitesh, Dohare, D., Jyoti, G., Rekhete, C., Dubey, S., & Prajapati, A. K. (2023). Optimization of Electrocoagulation Process for the Removal of Chromium from Simulated Water Using the Response Surface Methodology. Journal of Water Chemistry and Technology, 45(5), 429-439 • Ammar, M., Yousef, E., Mahmoud, M. A., Ashraf, S., & Baltrusaitis, J. (2023). A Comprehensive Review of the Developments in Electrocoagulation for the Removal of Contaminants from Wastewater. Separations, 10(6), 337. • Bani-Melhem, K., Al-Kilani, M. R., & Tawalbeh, M. (2023). Evaluation of scrap metallic waste electrode materials for the application in electrocoagulation treatment of wastewater. Chemosphere, 310, 136668. • Choi, A. E. S., & Ortenero, J. R. (2023). Fuzzy optimization for the remediation of saline oily wastewater through electrocoagulation: a multi-objective case analysis. Clean Technologies and Environmental Policy, 1-10. • Ebba, M., Asaithambi, P., & Alemayehu, E. (2022). Development of electrocoagulation process for wastewater treatment: optimization by response surface methodology. Heliyon, 8(5). • Holt, P. K., Barton, G. W., & Mitchell, C. A. (2005). The future for electrocoagulation as a localised water treatment technology. Chemosphere, 59(3), 355-367. • Martins, J. E. C. A., Abdala Neto, E. F., Ribeiro, J. P., Lima, A. C. A. D., de Souza, F. W., de Oliveira, A. G., ... & do Nascimento, R. F. (2023). Evaluation of the toxicity of textile effluent treated by electrocoagulation. Water Practice and Technology, 18(4), 930-946. • Mollah, M. Y., Morkovsky, P., Gomes, J. A., Kesmez, M., Parga, J., & Cocke, D. L. (2004). Fundamentals, present and future perspectives of electrocoagulation. Journal of hazardous materials, 114(1-3), 199-210. Page 45 of 51 • Mollah, M. Y. A., Schennach, R., Parga, J. R., & Cocke, D. L. (2001). Electrocoagulation (EC)—science and applications. Journal of hazardous materials, 84(1), 29-41. • Moussa, D. T., El-Naas, M. H., Nasser, M., & Al-Marri, M. J. (2017). A comprehensive review of electrocoagulation for water treatment: Potentials and challenges. Journal of environmental management, 186, 24-41. • Rakhmania, Kamyab, H., Yuzir, M. A., Abdullah, N., Quan, L. M., Riyadi, F. A., & Marzouki, R. (2022). Recent applications of the electrocoagulation process on agro-based industrial wastewater: a review. Sustainability, 14(4), 1985.	en_US
dc.identifier.uri	http://hdl.handle.net/123456789/2285
dc.description	Supervised by Dr. Amimul Ahsan, Associate Professor, Department of Civil and Environmental Engineering(CEE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh. This thesis is submitted in partial fulfillment of the requirements for the degree of Bachelor of Civil and Environmental Engineering, 2024	en_US
dc.description.abstract	Textile production has a significant environmental impact, mainly because untreated wastewater, packed with harmful substances like dyes, heavy metals, and chemicals, finds its way into water bodies. This pollution spells trouble for aquatic life, human health, and biodiversity, causing water contamination, habitat degradation, and putting communities relying on clean water at risk. That's why it's crucial to optimize textile wastewater treatment. Electrocoagulation and multimedia filtration offer a smart solution to tackle these issues. Electrocoagulation works by using an electric current to destabilize and remove pollutants, while multimedia filtration employs various media like sand and activated carbon to filter out suspended solids and dissolved contaminants. Combining these methods boosts treatment efficiency, with electrocoagulation targeting initial contaminant removal and multimedia filtration adding a finishing touch for high-quality treated water. In this thesis, the collected effluent samples underwent rigorous parameter testing, followed by electrocoagulation using Aluminum anode and Zinc cathode, succeeded by sedimentation and multimedia filtration. This process was conducted multiple times for durations of 30, 45, and 60 minutes, with meticulous data collection after each iteration. Remarkably, the maximum removal efficiencies achieved for Turbidity, Total Suspended Solids, COD, and Color were an impressive 99.46%, 99.27%, 91.304%, and 93.98%, respectively. Following parameter testing, achieving high removal efficiency of turbidity, total suspended solids (TSS), COD, and color stands as a beacon of progress. This milestone ensures compliance with stringent regulatory standards, significantly reducing environmental pollution and safeguarding delicate aquatic ecosystems. Moreover, it elevates the quality of discharged water, mitigating adverse impacts on biodiversity and public health. This remarkable feat not only underscores a commitment to sustainable textile production practices but also aligns with corporate social responsibility and regulatory mandates. However, certain parameters such as pH, Total Dissolved Solids, Dissolved Oxygen, Salinity, and EC exhibited increased values, warranting further investigation and study.	en_US
dc.language.iso	en	en_US
dc.publisher	Department of Civil and Environmental Engineering(CEE), Islamic University of Technology(IUT), Board Bazar, Gazipur-1704, Bangladesh	en_US
dc.title	Optimizing Textile Wastewater Treatment Using Electrocoagulation and Multimedia Filtration Strategies for Enhanced Efficiency	en_US
dc.type	Thesis	en_US