The Treatment of Hospital Wastewater Using Electrocoagulation Process – Analysis by Response Surface Methodology

Salah Al-Shati, Ahmed; Alabboodi, Khalid O.; Shamkhi, Hassan A.; Abd, Zahraa N.; Emeen, Sara I. Mohammed

doi:10.12911/22998993/156129

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The Treatment of Hospital Wastewater Using Electrocoagulation Process – Analysis by Response Surface Methodology

Autorzy

Salah Al-Shati Ahmed , Alabboodi Khalid O. , Shamkhi Hassan A. , Abd Zahraa N. , Emeen Sara I. Mohammed

Treść / Zawartość

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26_al_shati_the_treatment_jee_1_2023.pdf

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Identyfikatory

DOI

10.12911/22998993/156129

Warianty tytułu

Języki publikacji

Abstrakty

Electrocoagulation (EC) can be defined a method utilized to remove pollutants from wastewater by applying an electric current to sacrificial electrodes. Many experimental variables like NaCl content (0–4 g/l), current density (5–25 mA/cm²), time (30–90 mins), and pH (4–10) that influence the removal efficiency regarding COD were considered. In the presented research, three distinct configurations related to electrodes, i.e. Al-Al, Fe-Al, and Fe-Fe, have been utilized to determine which was the most effective. RSM depending on BBD was utilized for optimizing various operational parameters with regard to HWW by use of EC. Maximum COD removal (97.9%) was reached at Fe-Al electrodes, NaCl (3.2 g/l), current density (24.7 mA/cm²), time (81.7 mins), and pH (7.4). COD removal (91.3%) was achieved at the Al-Al electrodes, NaCl (3.8 g/l), current density(23.5 mA/cm²), time-86.3 min, and Ph (7.7). At the Fe-Fe electrodes, the removal of COD (89.5%) was obtained at NaCl (2.3 g/l), current density (24.6 mA/cm²), pH 8.5, and time (86.9 min). This indicates that EC could remove pollutants from different types of wastewaters under many operating parameters and with arrangements of electrodes.

Słowa kluczowe

electrocoagulation RSM response surface methodology COD removal

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 1

Strony

260--276

Opis fizyczny

Bibliogr. 57 poz., rys., tab.

Twórcy

autor

Salah Al-Shati Ahmed

ahmed.salah@mustaqbal-college.edu.iq

Chemical Engineering and Petroleum Industries Department, Al-Mustaqbal University College, 51001 Hilla, Babylon, Iraq

https://orcid.org/0000-0001-5423-2884

autor

Alabboodi Khalid O.

Chemical Engineering and Petroleum Industries Department, Al-Mustaqbal University College, 51001 Hilla, Babylon, Iraq

autor

Shamkhi Hassan A.

Chemical Engineering and Petroleum Industries Department, Al-Mustaqbal University College, 51001 Hilla, Babylon, Iraq

autor

Abd Zahraa N.

Chemical Engineering and Petroleum Industries Department, Al-Mustaqbal University College, 51001 Hilla, Babylon, Iraq

autor

Emeen Sara I. Mohammed

Chemical Engineering and Petroleum Industries Department, Al-Mustaqbal University College, 51001 Hilla, Babylon, Iraq

Bibliografia

1. Abbasi, S., Mirghorayshi, M., Zinadini, S., Zinatizadeh, A.A. 2020. A Novel Single Continuous Electrocoagulation Process for Treatment of Licorice Processing Wastewater: Optimization of Operating Factors Using RSM. Process Safety and Environmental Protection, 134, 323–32.
2. Abbasi, S., Zinatizadeh, A.A., Mirghorayshi, M., Zinadini, S., McKay, T. 2022. Electrocoagulation Technique for Continuous Industrial Licorice Processing Wastewater Treatment in a Single Reactor Employing Fe-Rod Electrodes: Process Modeling and Optimization and Operating Cost Analysis. Journal of Environmental Chemical Engineering, 10(2), 106686.
3. Abdel-Shafy, Hussein, I., Mohamed-Mansour, M.S. 2013. Issue of Pharmaceutical Compounds in Water and Wastewater: Sources, Impact and Elimination. Egyptian Journal of Chemistry, 56(5), 449–471.
4. Abdel-Shafy, H.I., Aiai Hewehy, M., Razek, T., Hamid, M., Morsy, R.M.M. 2019. Treatment of Industrial Electroplating Wastewater by Electrochemical Coagulation Using Carbon and Aluminum Electrodes. Egyptian Journal of Chemistry 62 (Special Issue (Part 1) Innovation in Chemistry, 383–392.
5. Al Jaberi, F.Y., Ahmed, S.A., Makki, H.F. 2020. Electrocoagulation Treatment of High Saline Oily Wastewater: Evaluation and Optimization. Heliyon 6(6), e03988.
6. Alkurdi, S.S., Abbar, A.H. 2020. Removal of COD from Petroleum Refinery Wastewater by Electro- Coagulation Process Using SS/Al Electrodes. In IOP Conference Series: Materials Science and Engineering, IOP Publishing, 870, 12052.
7. Anderson, M.J., Whitcomb, P.J. 2016. RSM Simplified: Optimizing Processes Using Response Surface Methods for Design of Experiments. Productivity press.
8. Asaithambi, P., Govindarajan, R. 2021. Hybrid Sono-Electrocoagulation Process for the Treatment of Landfill Leachate Wastewater: Optimization through a Central Composite Design Approach. Environmental Processes, 8(2), 793–816.
9. Bajpai, M., Katoch, S.S. 2020a. Techno-Economical Optimization Using Box-Behnken (BB) Design for COD and Chloride Reduction from Hospital Wastewater by Electro-Coagulation. Water Environ Res Wer, 1387.
10. Bajpai, M., Katoch, S.S. 2020b. Techno‐economical Optimization Using Box–Behnken (BB) Design for Chemical Oxygen Demand and Chloride Reduction from Hospital Wastewater by Electro‐coagulation. Water Environment Research, 92(12), 2140–2154.
11. Beier, S., Cramer, C., Köster, S., Mauer, C., Palmowski, L., Schröder, H.F., Pinnekamp, J. 2011. Full Scale Membrane Bioreactor Treatment of Hospital Wastewater as Forerunner for Hot-Spot Wastewater Treatment Solutions in High Density Urban Areas. Water Science and Technology, 63(1), 66–71.
12. Bener, S., Bulca, Ö., Burcu, Palas, B., Tekin, G., Atalay, S., Ersöz, G. 2019. Electrocoagulation Process for the Treatment of Real Textile Wastewater: Effect of Operative Conditions on the Organic Carbon Removal and Kinetic Study. Process Safety and Environmental Protection, 129, 47–54.
13. Bezerra, M.A., Santelli, R.E., Oliveira, E.P., Villar, L.S., Escaleira, L.A. 2008. Response Surface Methodology (RSM) as a Tool for Optimization in Analytical Chemistry. Talanta, 76(5), 965–977.
14. Camcioglu, Sule, Baran Ozyurt, Hapoglu, H. 2017. Effect of Process Control on Optimization of Pulp and Paper Mill Wastewater Treatment by Electrocoagulation. Process Safety and Environmental Protection, 111, 300–319.
15. Can, O.T., Gengec, E., Kobya, M. 2019. TOC and COD Removal from Instant Coffee and Coffee Products Production Wastewater by Chemical Coagulation Assisted Electrooxidation. Journal of Water Process Engineering, 28, 28–35.
16. Chen, Y.M., Jiang W.M., Liu, Y., Kang, Y. 2020. Quantitative Contribution Study and Comparison between Electrocoagulation, Anode-Electrocoagulation and Chemical Coagulation Using Polymer- Flooding Sewage. Chemosphere, 250, 126128.
17. Dalvand, A., Gholami, M., Joneidi, A., Mahmoodi, N.M. 2011. Dye Removal, Energy Consumption and Operating Cost of Electrocoagulation of Textile Wastewater as a Clean Process. Clean–Soil, Air, Water, 39(7), 665–72.
18. Davarnejad, R., Mohammadi, M., Ismail, A.F. 2014. Petrochemical Wastewater Treatment by Electro-Fenton Process Using Aluminum and Iron Electrodes: Statistical Comparison. Journal of Water Process Engineering, 3, 18–25.
19. Dean, A., Voss, D., Draguljić, D. 2017. Response Surface Methodology. In Design and Analysis of Experiments, Springer, 565–614.
20. Deveci, E.Ü., Akarsu, C., Gönen, C., Özay, Y. 2019. Enhancing Treatability of Tannery Wastewater by Integrated Process of Electrocoagulation and Fungal via Using RSM in an Economic Perspective. Process Biochemistry, 84, 124–33.
21. Dimoglo, A., Sevim-Elibol, P., Dinç, Ö., Gökmen, K., Erdoğan, H. 2019. Electrocoagulation/Electroflotation as a Combined Process for the Laundry Wastewater Purification and Reuse. Journal of Water Process Engineering, 31, 100877.
22. Ebba, M., Asaithambi, P., Alemayehu, E. 2021. Investigation on Operating Parameters and Cost Using an Electrocoagulation Process for Wastewater Treatment. Applied Water Science, 11(11), 1–9.
23. Ebba, Million & Asaithambi, P. & Alemayehu, Esayas. 2022. Development of Electrocoagulation Process for Wastewater Treatment: Optimization by Response Surface Methodology. Heliyon, 8(5), e09383.
24. Ekawati, D., Nadira, R. 2018. Application of Response Surface Methodology (RSM) for Wastewater of Hospital by Using Electrocoagulation. In IOP Conference Series: Materials Science and Engineering. IOP Publishing, 345, 12011.
25. El-Khateeb, M., Nashy, E.S.H., Ghany, N.A., Awad, A.M. 2017. Environmental Impact Elimination of Chrome Tanning Effluent Using Electrocoagulation Process Assisted by Chemical Oxidation. Desalination and Water Treatment, 65, 147–152.
26. Elazzouzi, M., Haboubi, K,, Elyoubi, M.S. 2019. Enhancement of Electrocoagulation-Flotation Process for Urban Wastewater Treatment Using Al and Fe Electrodes: Techno-Economic Study. Materials Today: Proceedings,13, 549–555.
27. Fahim, A.S., Abbar, A.H. 2020. Treatment of Petroleum Refinery Wastewater by Electro-Fenton Process Using Porous Graphite Electrodes. Egyptian Journal of Chemistry, 63(12), 4805–4819.
28. Fathy, M.T.H., Hafez, A.I., Abou-Elmagd, W., Abdel-Samad, H.S. 2020. A Comparative Study of Electro and Chemical Coagulation for Efficient Removal of Lignin and Some Other Pollutants from Industrial Wastewater. Egyptian Journal of Chemistry, 63(10), 4083–4093.
29. Ghafari, S., Aziz H.A., Isa, M.H., Zinatizadeh, A.A. 2009. Application of Response Surface Methodology (RSM) to Optimize Coagulation–Flocculation Treatment of Leachate Using Poly-Aluminum Chloride (PAC) and Alum. Journal of Hazardous Materials, 163(2–3), 650–656.
30. Ghanbari, F., Yaghoot-Nezhad, A., Wacławek, S., Lin K.Y.A., Rodríguez-Chueca J., Mehdipour, F. 2021. Comparative Investigation of Acetaminophen Degradation in Aqueous Solution by UV/Chlorine and UV/H2O2 Processes: Kinetics and Toxicity Assessment, Process Feasibility and Products Identification. Chemosphere, 285, 131455.
31. Gökkuş, Ö., Yıldız, Y.S. 2015. Application of Electrocoagulation for Treatment of Medical Waste Sterilization Plant Wastewater and Optimization of the Experimental Conditions. Clean Technologies and Environmental Policy, 17(6), 1717–1725.
32. Hill, W.J., Hunter, W.G. 1966. A Review of Response Surface Methodology: A Literature Survey. Technometrics, 8(4), 571–590.
33. Jack, F., Bostock, J., Tito, D., Harrison, B., Brosnan, J. 2014. Electrocoagulation for the Removal of Copper from Distillery Waste Streams. Journal of the Institute of Brewing, 120(1), 60–64.
34. Kermet-Said, H., Moulai-Mostefa, N. 2015. Optimization of Turbidity and COD Removal from Pharmaceutical Wastewater by Electrocoagulation. Isotherm Modeling and Cost Analysis. Polish Journal of Environmental Studies, 24(3).
35. Khan, S.U., Islam, D.T., Farooqi, I.H., Ayub, S., Basheer, F. 2019. Hexavalent Chromium Removal in an Electrocoagulation Column Reactor: Process Optimization Using CCD, Adsorption Kinetics and PH Modulated Sludge Formation. Process Safety and Environmental Protection, 122, 118–130.
36. Kumar, A., Singh, H., Kumar, V. 2018. Study the Parametric Effect of Abrasive Water Jet Machining on Surface Roughness of Inconel 718 Using RSM-BBD Techniques. Materials and Manufacturing Processes, 33(13), 1483–1490.
37. Liu, F., Zhang, Z., Wang, Z., Li, X., Dai, X., Wang, L., Wang, X., Yuan, Z., Zhang, J., Chen, M. 2019. Experimental Study on Treatment of Tertiary Oil Recovery Wastewater by Electrocoagulation. Chemical Engineering and Processing-Process Intensification, 144, 107640.
38. López-Maldonado, E.A., Oropeza-Guzman, M.T., Jurado-Baizaval, J.L., Ochoa-Terãn, A. 2014. Coagulation–Flocculation Mechanisms in Wastewater Treatment Plants through Zeta Potential Measurements. Journal of Hazardous Materials, 279, 1–10.
39. Mahajan, R., Khandegar, V., Saroha, A.K. 2013. Treatment of Hospital Operation Theatre Effluent by Electrocoagulation. International Journal, 4(2).
40. Martínez, F., Molina, R., Rodríguez, I., Pariente, M.I., Segura, Y., Melero, J.A. 2018. Techno-Economical Assessment of Coupling Fenton/Biological Processes for the Treatment of a Pharmaceutical Wastewater. Journal of Environmental Chemical Engineering, 6(1), 485–494.
41. Mohammed, B.B., Hsini, A., Abdellaoui, Y., Oualid, H.A., Laabd, M., Ouardi M.E., Ait Addi, A.A., Yamni, K., Tijani, N. 2020. Fe-ZSM-5 Zeolite for Efficient Removal of Basic Fuchsin Dye from Aqueous Solutions: Synthesis, Characterization and Adsorption Process Optimization Using BBD-RSM Modeling. Journal of Environmental Chemical Engineering, 8(5), 104419.
42. Mosayebi, A. 2021. Methanol Steam Reforming over Co‐Cu‐Zn/Γ‐Al2O3 Catalyst: Kinetic and RSM‐BBD Modeling Approaches. International Journal of Energy Research, 45(2), 3288–3304.
43. Najeeb, R.G., Abbar, A. 2022. Optimization of COD Removal from Pharmaceutical Wastewater by Electrocoagulation Process Using Response Surface Methodology (RSM). Egyptian Journal of Chemistry, 65(1), 1–2.
44. Nidheesh, P.V., Kumar, A., Babu, D.S., Scaria, J., Kumar, M.S. 2020. Treatment of Mixed Industrial Wastewater by Electrocoagulation and Indirect Electrochemical Oxidation. Chemosphere, 251, 126437.
45. Ramcharan, T., Bissessur, A. 2017. Treatment of Laundry Wastewater by Biological and Electrocoagulation Methods. Water Science and Technology, 75(1), 84–93.
46. Şengil, İ.A.. 2006. Treatment of Dairy Wastewaters by Electrocoagulation Using Mild Steel Electrodes. Journal of Hazardous Materials, 137(2), 1197–1205.
47. Shahedi, A., Darban, A.K., Taghipour, F., Jamshidi-Zanjani, A. 2020. A Review on Industrial Wastewater Treatment via Electrocoagulation Processes. Current Opinion in Electrochemistry, 22, 154–169.
48. Sheng, C., Agwu Nnanna, A.G., Liu, Y., Vargo J.D. 2016. Removal of Trace Pharmaceuticals from Water Using Coagulation and Powdered Activated Carbon as Pretreatment to Ultrafiltration Membrane System. Science of the Total Environment, 550, 1075–1083.
49. Shivayogimath, C.B., Jahagirdar, R. 2013. Treatment of Sugar Industry Wastewater Using Electrocoagulation Technique. Int J Res Eng Technol, 1(5), 262–265.
50. Shokoohi, R., Nematollahi, D., Samarghandi, M.R., Azarian, G., Latifi, Z. 2020. Optimization of Three-Dimensional Electrochemical Process for Degradation of Methylene Blue from Aqueous Environments Using Central Composite Design. Environmental Technology & Innovation, 18, 100711.
51. Tahreen, A., Jami, M.S., Ali, F. 2020. Role of Electrocoagulation in Wastewater Treatment: A Developmental Review. Journal of Water Process Engineering, 37, 101440.
52. Tak, B., Tak B.S., Kim Y.J., Park Y.J., Yoon, Y.H., Min, G.H. 2015. Optimization of Color and COD Removal from Livestock Wastewater by Electrocoagulation Process: Application of Box–Behnken Design (BBD). Journal of Industrial and Engineering Chemistry, 28, 307–315.
53. Tekin, H., Bilkay, O., Ataberk, S.S., Balta, T.H., Ceribasi, I.H., Dilek Sanin, F., Dilek, F.B., Yetis, U. 2006. Use of Fenton Oxidation to Improve the Biodegradability of a Pharmaceutical Wastewater. Journal of Hazardous Materials, 136(2), 258–265.
54. Un, U.T., Koparal, A.S., Ogutveren, U.B. 2009. Electrocoagulation of Vegetable Oil Refinery Wastewater Using Aluminum Electrodes. Journal of Environmental Management, 90(1), 428–433.
55. Yan, L., Wang, Y., Li, J., Ma, H., Liu, H., Li, T., Zhang, Y. 2014. Comparative Study of Different Electrochemical Methods for Petroleum Refinery Wastewater Treatment. Desalination, 341, 87–93.
56. Yánes, A., Pinedo-Hernández, J., Marrugo-Negrete, J. 2021. Continuous Flow Electrocoagulation as a Hospital Wastewater Treatment. Portugaliae Electrochimica Acta, 39(6), 403–413.
57. Yavuz, Y., Ögütveren, Ü.B. 2018. Treatment of Industrial Estate Wastewater by the Application of Electrocoagulation Process Using Iron Electrodes. Journal of Environmental Management, 207, 151–158.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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