پیوندهای مفید
اخبار و اعلانات
آمار
| تعداد نشریات | 158 |
| تعداد شمارهها | 6,226 |
| تعداد مقالات | 67,694 |
| تعداد مشاهده مقاله | 115,005,721 |
| تعداد دریافت فایل اصل مقاله | 89,686,567 |
Promising Potential of Electro-Coagulation Process for Effective Treatment of Biotreated Palm Oil Mill Effluents | ||
| Pollution | ||
| مقاله 9، دوره 7، شماره 3، مهر 2021، صفحه 617-632 اصل مقاله (1.03 M) | ||
| نوع مقاله: Original Research Paper | ||
| شناسه دیجیتال (DOI): 10.22059/poll.2021.320645.1034 | ||
| نویسندگان | ||
| Amina Tahreen1؛ Mohammed Saedi Jami* 1؛ Fathilah Ali1؛ Nik Mohd Farid Mat Yasin2؛ Mohammed Ngabura3 | ||
| 1Department of Biotechnology Engineering, Faculty of Engineering, International Islamic University Malaysia, P.O Box 10, 50728 Kuala Lumpur, Malaysia | ||
| 2Processing & Engineering, Sime Darby Plantation Research Sdn Bhd, 42960 Selangor, Malaysia | ||
| 3Department of Chemical and Environmental Engineering, Faculty of Engineering, University Putra Malaysia, 43400 Serdang, Selangor, Malaysia | ||
| چکیده | ||
| The critical parameters namely initial pH, time and current density largely impact the process efficiency of electrocoagulation (EC). Few works have been done on observing the interaction of these critical parameters and the possible combined effect on the overall pollutant removal efficiency. Therefore, the knowledge of the combined effect of critical parameter interaction would enhance the optimization of EC parameters to attain maximum efficiency with limited resources. Using aluminium electrodes with interelectrode distance of 10 mm on synthetic wastewater, representing biotreated palm oil mill effluent (BPOME), with a set range of initial pH, current density, and time of 3-8, 40-160 mA/cm2 and 15 to 60 minutes, respectively, the effect of the three critical variables was investigated. The optimum Chemical Oxygen Demand (COD) removal of 71.5% was determined at pH 6, current density of 160 mA/cm2 (with current 1.75 A) at EC time of 15 minutes. The experiment was validated with real BPOME, resulting in the removal efficiency of 60.7 % COD, 99.91 % turbidity, 100 % total suspended solids (TSS) and 95.7 % colour. Removal of a large quantity of pollutants in a time span of 15 minutes with optimized parameters in EC is notable for a wastewater treatment alternative that requires no extensive use of chemicals. The interaction of parameters observed in this study indicated a synergistic contribution of initial pH and current density in removing maximum wastewater COD in 15 minutes of EC. | ||
| کلیدواژهها | ||
| Wastewater treatment؛ Industrial effluent؛ Optimization؛ Parameter interaction | ||
| مراجع | ||
|
Abdulazeez, Q. M., Jami, M. S. and Alam, M. Z. (2018). Feasibility of using kaolin suspension as synthetic sludge sample. J. Adv. Res. Fluid Mech. Therm. Sci., 48; 25–39. Akarsu, C., Ozay, Y., Dizge, N., Gulsen, H. E., Ates, H., Gozmen, B. and Turabik, M. (2016). Electrocoagulation and nanofiltration integrated process application in purification of bilge water using response surface methodology. Water Sci. Technol., 74(3); 564–579. Akhtar, A., Aslam, Z., Asghar, A., Bello, M. M. and Raman, A. A. A. (2020). Electrocoagulation of Congo Red dye-containing wastewater: Optimization of operational parameters and process mechanism. J. Environ. Chem. Eng., 8(5); 104055. Amosa, M. K., Jami, M. S., Alkhatib, M. F. R. and Majozi, T. (2016). Studies on pore blocking mechanism and technical feasibility of a hybrid PAC-MF process for reclamation of irrigation water from biotreated POME. Sep. Sci. Technol., 51(12); 2047–2061. APHA, American Public Health Association (2002). American Water Works Association, Water Environment Federation; Stand. Methods Exam. Water Wastewater. Aslan, A. K. H. N., Ali, M. D. M., Morad, N. A. and Tamunaidu, P. (2016). Polyhydroxyalkanoates production from waste biomass. IOP Conf. Ser.: Earth Environ. Sci.,36(1); 012040. Aswathy, P., Gandhimathi, R., Ramesh, S. T. and Nidheesh, P. V. (2016). Removal of organics from bilge water by batch electrocoagulation process. Sep. Purif. Technol., 159; 108–115. Bahadur, N. and Bhargava, N. (2019). Novel pilot scale photocatalytic treatment of textile & dyeing industry wastewater to achieve process water quality and enabling zero liquid discharge. J. Water Process Eng., 32; 100934. Bannari, R., Hilali, Y., Essadki, A. and Bannari, A. (2019). Computational fluid dynamic for improving design and performance of an external loop airlift reactor used in electrochemical wastewater treatment. SN Appl. Sci., 1(11); 1–17. Bashir, M. J., Lim, J. H., Abu Amr, S. S., Wong, L. P. and Sim, Y. L. (2019). Post treatment of palm oil mill effluent using electro-coagulation-peroxidation (ECP) technique. J. Clean. Prod., 208; 716–727. Boczkaj, G. and Fernandes, A. (2017). Wastewater treatment by means of advanced oxidation processes at basic pH conditions: A review. Chem. Eng. J., 320; 608–633. Chavalparit, O. and Ongwandee, M. (2009). Optimizing electrocoagulation process for the treatment of biodiesel wastewater using response surface methodology. J. Environ. Sci., 21(11); 1491–1496. Deveci, E. Ü., Akarsu, C., Gönen, Ç. and Özay, Y. (2019). Enhancing treatability of tannery wastewater by integrated process of electrocoagulation and fungal via using RSM in an economic perspective. Process Biochem., 84; 124–133. Dimoglo, A., Sevim-Elibol, P., Dinç, Gökmen, K. and Erdoğan, H. (2019). Electrocoagulation/electroflotation as a combined process for the laundry wastewater purification and reuse. J. Water Process Eng., 31;100877. El-Ashtoukhy, E. S. Z., Amin, N. K. and Abdelwahab, O. (2008). Removal of lead (II) and copper (II) from aqueous solution using pomegranate peel as a new adsorbent. Desalin., 223; 162–173. Foudhaili, T., Lefebvre, O., Coudert, L. and Neculita, C. M. (2020). Sulfate removal from mine drainage by electrocoagulation as a stand-alone treatment or polishing step. Miner. Eng., 152; 106337. Fukui, Y. and Yuu, S. (1985). Removal of colloidal particles in electroflotation. AIChE J., 31(2); 201–208. Garcia-Segura, S., Eiband, M. M. S. G., de Melo, J. V. and Martínez-Huitle, C. A. (2017). Electrocoagulation and advanced electrocoagulation processes: A general review about the fundamentals, emerging applications and its association with other technologies. J. Electroanal. Chem., 801; 267–299. Ghernaout, D., Ghernaout, B., Boucherit, A., Naceur, M. W., Khelifa, A. and Kellil, A. (2009). Study on mechanism of electrocoagulation with iron electrodes in idealised conditions and electrocoagulation of humic acids solution in batch using aluminium electrodes. Desalin. Water Treat., 8(1–3); 91–99. Ghernaout, Djamel, Al-Ghonamy, A. I., Ait Messaoudene, N., Aichouni, M., Naceur, M. W., Benchelighem, F. Z. and Boucherit, A. (2015). Electrocoagulation of Direct Brown 2 (DB) and BF Cibacete Blue (CB) using aluminum electrodes. Sep. Sci. Technol., 50(9); 1413–1420. Hashim, K. S., Jasim, N., Shaw, A., Phipps, D., Kot, P., Alattabi, A. W., Abdulredha, M. and Alawsh, R. (2019). Electrocoagulation as a green technology for phosphate removal from river water. Sep. Purif. Technol., 210; 135–144. Holt, P. K., Barton, G. W., Wark, M. and Mitchell, C. A. (2002). A quantitative comparison between chemical dosing and electrocoagulation. Colloids Surfaces A Physicochem. Eng. Asp., 211(2–3); 233–248. Hussin, F., Abnisa, F., Issabayeva, G., & Aroua, M. K. (2017). Removal of lead by solar-photovoltaic electrocoagulation using novel perforated zinc electrode. J. Clean. Prod., 147; 206–216. Ilyas, A., Mertens, M., Oyaert, S. and Vankelecom, I. F. J. (2020). Synthesis of patterned PVDF ultrafiltration membranes: Spray-modified non-solvent induced phase separation. J. Memb. Sci., 612; 118383. Iskandar, M. J., Baharum, A., Anuar, F. H. and Othaman, R. (2018). Palm oil industry in South East Asia and the effluent treatment technology—A review. Environ. Technol. Innov., 9; 169–185. Jawad, A. H., Rashid, R. A., Ishak, M. A. M. and Wilson, L. D. (2016). Adsorption of methylene blue onto activated carbon developed from biomass waste by H2SO4 activation: kinetic, equilibrium and thermodynamic studies. Desalin. Water Treat., 57(52); 25194–25206. Jayakaran, P., Nirmala, G. S. and Govindarajan, L. (2019). Qualitative and quantitative analysis of graphene-gased adsorbents in wastewater treatment. Int. J. Chem. Eng., 2019. Khosravi, R., Hossini, H., Heidari, M., Fazlzadeh, M., Biglari, H., Taghizadeh, A. and Barikbin, B. (2017). Electrochemical decolorization of reactive dye from synthetic wastewater by mono-polar aluminum electrodes system. Int. J. Electrochem. Sci., 12(6); 4745–4755. Kobya, M., Hiz, H., Senturk, E., Aydiner, C. and Demirbas, E. (2006). Treatment of potato chips manufacturing wastewater by electrocoagulation. Desalin., 190(1–3); 201–211. Lekhlif, B., Oudrhiri, L., Zidane, F., Drogui, P. and Blais, J. F. (2014). Study of the electrocoagulation of electroplating industry wastewaters charged by nickel (II) and chromium (VI). J. Mater. Environ. Sci., 5(1); 111–120. Loukanov, A., El Allaoui, N., Omor, A., Elmadani, F. Z., Bouayad, K. and Seiichiro, N. (2020). Large-scale removal of colloidal contaminants from artisanal wastewater by bipolar electrocoagulation with aluminum sacrificial electrodes. J. Neurol. Sci., 2; 100038. Manilal, A. M., Soloman, P. A., & Basha, C. A. (2020). Removal of Oil and Grease from Produced Water Using Electrocoagulation. J. Hazardous, Toxic, Radioact. Waste, 24(1). McBeath, S. T., Nouri-Khorasani, A., Mohseni, M., & Wilkinson, D. P. (2020). In-situ determination of current density distribution and fluid modeling of an electrocoagulation process and its effects on natural organic matter removal for drinking water treatment. Water Res., 171. Mohd-Nor, D., Ramli, N., Sharuddin, S. S., Hassan, M. A., Mustapha, N. A., Ariffin, H., Sakai, K., Tashiro, Y., Shirai, Y., & Maeda, T. (2019). Dynamics of microbial populations responsible for biodegradation during the full-scale treatment of palm oil mill effluent. Microbes Environ., 34(2); 121–128. Moussa, D. T., El-Naas, M. H., Nasser, M. and Al-Marri, M. J. (2017). A comprehensive review of electrocoagulation for water treatment: Potentials and challenges. J. Environ. Manage., 186; 24–41. Naje, A. S., Chelliapan, S., Zakaria, Z., Ajeel, M. A. and Alaba, P. A. (2017). A review of electrocoagulation technology for the treatment of textile wastewater. Rev. Chem. Eng., 33(3); 263–292. Nasrullah, M., Singh, L., Krishnan, S., Sakinah, M., Mahapatra, D. M. and Zularisam, A. W. (2020). Electrocoagulation treatment of raw palm oil mill effluent: Effect of operating parameters on floc growth and structure. J. Water Process Eng., 33; 101114. Nasrullah, M., Singh, L., Mohamad, Z., Norsita, S., Krishnan, S., Wahida, N. and Zularisam, A. W. (2017). Treatment of palm oil mill effluent by electrocoagulation with presence of hydrogen peroxide as oxidizing agent and polialuminum chloride as coagulant-aid. Water Resour. Ind., 17; 7–10. Nopens, I., Capalozza, C. and Vanrolleghem, P. A. (2001) Stability analysis of a synthetic municipal wastewater. Dissertation, Ghent University. Reilly, M., Cooley, A. P., Tito, D., Tassou, S. A. and Theodorou, M. K. (2019). Electrocoagulation treatment of dairy processing and slaughterhouse wastewaters. Energy Procedia, 161; 343–351. Rusdianasari, Taqwa, A., Jaksen and Syakdani, A. (2017). Treatment optimization of electrocoagulation (EC) in purifying palm oil mill effluents (POMEs). J. Eng. Technol. Sci., 49(5); 604–617. Sandoval, M. A., Fuentes, R., Thiam, A., & Salazar, R. (2021). Arsenic and fluoride removal by electrocoagulation process: A general review. Sci. Total Environ., 753; 142108. Sardari, K., Fyfe, P., Lincicome, D. and Wickramasinghe, S. R. (2018). Aluminum electrocoagulation followed by forward osmosis for treating hydraulic fracturing produced waters. Desalin., 428; 172–181. Sediqi, S., Bazargan, A., & Mirbagheri, S. A. (2021). Consuming the least amount of energy and resources in landfill leachate electrocoagulation. Environ. Technol. Innov., 22; 101454. Sekar, M., Sakthi, V. and Rengaraj, S. (2004). Kinetics and equilibrium adsorption study of lead(II) onto activated carbon prepared from coconut shell. J. Colloid Interface Sci., 279(2); 307–313. Shankar, R., Singh, L., Mondal, P. and Chand, S. (2014). Removal of COD, TOC, and color from pulp and paper industry wastewater through electrocoagulation. Desalin. Water Treat., 52(40–42); 7711–7722. Sharma, S., Aygun, A. and Simsek, H. (2020). Electrochemical treatment of sunflower oil refinery wastewater and optimization of the parameters using response surface methodology. Chemosphere, 249; 126511. Sher, F., Hanif, K., Zafar, S. and Imran, M. (2020). Implications of advanced wastewater treatment : Electrocoagulation and electroflocculation of effluent discharged from a wastewater treatment plant. J. Water Process Eng., 33. Tahreen, A. and Jami, M. S. (2021). Advances in antifouling strategies in membrane ultrafiltration : A brief review. J. Adv. Res. Mater. Sci., 1(1); 10–16. Tahreen, A., Jami, M. S. and Ali, F. (2020). Role of electrocoagulation in wastewater treatment: A developmental review. J. Water Process Eng., 37; 101440. Thakur, L. S., Goyal, H. and Mondal, P. (2019). Simultaneous removal of arsenic and fluoride from synthetic solution through continuous electrocoagulation: Operating cost and sludge utilization. J. Environ. Chem. Eng., 7(1). UN. (2018). SDG 6 Synthesis Report 2018 on Water and Sanitation. Wagle, D., Lin, C., Nawaz, T. and Shipley, H. J. (2019). Evaluation and optimization of electrocoagulation for treating Kraft paper mill wastewater. Biochem. Pharmacol., 8(1); 103595. WEF. (2020). World Economic Forum. The Global Risks Report 2020 Insight Report, 15. Zaied, B. K., Rashid, M., Nasrullah, M., Zularisam, A. W., Pant, D., & Singh, L. (2020). A comprehensive review on contaminants removal from pharmaceutical wastewater by electrocoagulation process. Sci. Total Environ., 726; 138095. | ||
|
آمار تعداد مشاهده مقاله: 516 تعداد دریافت فایل اصل مقاله: 549 |
||