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This research aimed to find the best-operating conditions for incorporating the GO material into PES/GO membranes for the NF applications. Organic dye molecules may foul GO-NP/PES membranes. The improved model aimed to reduce the energy lost while maintaining a high system discharge throughout the treatment process in order to face the technical problems that the membranes are exposed to. To create a particular amount of flux above the intended values, an optimization approach was used to find the optimal values for several important parameters in the process. To enhance the process effectiveness on a broader scale, mathematical and statistical studies, such as response surface methodology and statistical analysis of the parameters (ANOVA), were applied. The impact of operational factors, like the pH values of the dye feeding (3–11), GO weight content (0–2 wt.%), dye concentration (10–100 ppm) of AB-210, and the interfaces for these factors with the PES/GO membrane permeability was examined. The PES membrane had the best performance, with a result of 131.2338 L·m-2·h-1·bar-1. The pH did not influence the AB-210 dye reaction, and the Pareto chart of the standardized effects on dye permeation flux using statistical comparison at the 5% significance level supports these findings.
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Tom
Strony
115--127
Opis fizyczny
Bibliogr. 40 poz., rys., tab.
Twórcy
autor
- Civil Engineering Department, University of Technology, Alsinaa Str. 52, 10066, Baghdad, Iraq
autor
- Civil Engineering Department, University of Technology, Alsinaa Str. 52, 10066, Baghdad, Iraq
autor
- Civil Engineering Department, University of Technology, Alsinaa Str. 52, 10066, Baghdad, Iraq
autor
- Membrane Technology Research Unit, Chemical Engineering Department, University of Technology, Alsinaa Str. 52, 10066, Baghdad, Iraq
autor
- Al-Mustaqbal University College, 51001, Babylon, Iraq
Bibliografia
- 1. Abdel-Karim, A., Sebastian, L., Monica, A., Aravind, V., Xiaolei, F., Stuart, H.M., Eglal, S.R., Mohamed B.I., Patricia G. 2018. High flux and fouling resistant flat sheet polyethersulfone membranes incorporated with graphene oxide for ultrafiltration applications. Chemical Engineering Journal, 334, 789–799.
- 2. Akbari, M., Shariaty-Niassar M., Matsuura T., Ismail A.F. 2018. Janus graphene oxide nanosheet: A promising additive for enhancement of polymeric membranes performance prepared via phase inversion. J Colloid Interface Sci, 527, 10–24.
- 3. Al-Ani, F.H., Alsalhy, Q.F., Raheem, R.S., Rashid, K.T., Figoli, A. 2020. Experimental Investigation of the Effect of Implanting TiO2-NPs on PVC for Long-Term UF Membrane Performance to Treat Refinery Wastewater. Membranes (Basel), 10(4.
- 4. Al-Sultan, A.A., Al-Wakel, S.F., Al-Taie, A.S. 2019. Experimental Study of Heavy Metal Dispersion through Cohesionless Soil: a Case Study of Cd+. International Review of Civil Engineering, 16(6).
- 5. Alsalhy, Q.F.,. Ibrahim, S.S., Khaleel, S.R. 2017. Performance of vacuum poly(propylene) membrane distillation (VMD) for saline water desalination. Chemical Engineering and Processing - Process Intensification, 120, 68–80.
- 6. Alyarnezhad, S., Marino, T., Parsa, J.B., Galiano F., Ursino C., Garcia H., Puche M., Figoli A. 2020. Polyvinylidene Fluoride-Graphene Oxide Membranes for Dye Removal under Visible Light Irradiation. Polymers (Basel), 12(7).
- 7. De Gisi, S., Lofrano G., Grassi M., Notarnicola M. 2016. Characteristics and adsorption capacities of low-cost sorbents for wastewater treatment: A review. Sustainable Materials and Technologies, 9, 10–40.
- 8. Eleiwi, F., Laleg-Kirati, T.M. 2014. Dynamic modeling and optimization in membrane distillation system. 19th World Congress The International Federation of Automatic Control Cape Town, South Africa. August, 24–29.
- 9. Fauzi, I.A., Matsuura, T. 2016. Membrane Technology for Water and Wastewater Treatment, Energy and Environmentby London, UK, CRC Press, Taylor & Francis Group.
- 10. Geim, A.K. 2009. Graphene: Status and Prospects. Science, 324.
- 11. Geim, A.K., Novoselov, K.S. 2007. The rise of graphene. Nature Materials, 6.
- 12. Gerken, M., Moran, M.D., Mercier, H.P., Pointner, B.E., Schrobilgen, G.J., Hoge, B., Christe, K.O., Boatz, J.A. 2009. On the XeF+/H2O System: Synthesis and Characterization of the Xenon (II) Oxide Fluoride Cation, FXeOXeFXeF+. Journal of the American Chemical Society, 131.
- 13. Gholami, N., Mahdavi, H. 2018. Nanofiltration composite membranes of polyethersulfone and graphene oxide and sulfonated graphene oxide. Advance in Polymer Technology, 37. (8)
- 14. Ismael, A.E. 2017. Nano Submerged Membrane Bioreactor for Hospital Wastewater Treatment, University of Technology.
- 15. Jin, F., Lv W., C. Zhang, Z. Li, R. Su, W. Qi, Q. Yang and Z. He (2013). High-performance ultrafiltration membranes based on polyethersulfone–graphene oxide composites. RSC Advances, 3(44)
- 16. Judd, S., Judd, C. 2011. Principles and Applications of Membrane Bioreactors for Water and Wastewater Treatment, Elsevier.
- 17. Junaidi, N.F.D., Khalil N.A., Jahari A.F., Shaari N.Z.K., Shahruddin M.Z., Alias N.H., Othman N.H. 2018. Effect of Graphene Oxide (GO) on the Surface Morphology & Hydrophilicity of Polyethersulfone (PES). IOP Conference Series: Materials Science and Engineering, 358.
- 18. Kadhim, R.J., Al-Ani, F.H., Al-Shaeli, M., Alsalhy, Q.F., Figoli A. 2020. Removal of Dyes Using Graphene Oxide (GO) Mixed Matrix Membranes. Membranes (Basel), 10(12)
- 19. Kadhim R.J., Al-Ani F.H., Alsalhy Q.F., Figoli A. 2021. Optimization of MCM-41 Mesoporous Material Mixed Matrix Polyethersulfone Membrane for Dye Removal. Membranes (Basel), 11(6)
- 20. Koyuncu, I. 2002. Reactive dye removal in dye/salt mixtures by nanofiltration membranes containing vinylsulphone dyes: Effects of feed concentration and cross flow velocity. Desalination, 143, 243–253.
- 21. Kumar, M., McGlade, D., Ulbricht, M., Lawler, J. 2015. Quaternized polysulfone and graphene oxide nanosheet derived low fouling novel positively charged hybrid ultrafiltration membranes for protein separation. RSC Advances, 5(63), 51208–51219.
- 22. Lin, J., Ye, W., Baltaru, M.C., Tang, Y.P., Bernstein, N.J., Gao, P., Balta, S., Vlad, M., Volodin, A., Sotto, A., Luis, P., Zydney, A.L., Van der Bruggen, B. 2016. Tight ultrafiltration membranes for enhanced separation of dyes and Na2SO4 during textile wastewater treatment. Journal of Membrane Science, 514, 217–228.
- 23. Luque-Alled, J., Abdel-Karim A., Alberto, M.A,. Sebastian L., Maria, P., Kun, H., Aravind, V., El-Kalliny, A.S., Holmes, S.M., Patricia, G. 2020. Polyethersulfone membranes: From ultrafiltration to nanofiltration via the incorporation of APTS functionalized-graphene oxide. Separation and Purification Technology, 230.
- 24. Mahmoodi, N.M., Ghezelbash, M., Shabanian, M., Aryanasab, F., Saeb, M.R. 2017. Efficient removal of cationic dyes from colored wastewaters by dithiocarbamate-functionalized graphene oxide nanosheets: From synthesis to detailed kinetics studies. Journal of the Taiwan Institute of Chemical Engineers, 81, 239–246.
- 25. Mahmoud, K.A., Mansoor, B., Mansour, A., Khraisheh M. 2015. Functional graphene nanosheets: The next generation membranes for water desalination. Desalination, 356, 208-225.
- 26. Majewska-Nowak, K. 2009. Ultrafiltration of Dye Solutions in the Presence of Cationic and Anionic Surfactants. Environment Protection Engineering, 35.
- 27. Makhetha, T.A., Moutloali, R.M. 2018. Antifouling properties of Cu(tpa)@GO/PES composite membranes and selective dye rejection. Journal of Membrane Science, 554, 195–210.
- 28. Moussavi, G., Mahmoudi, M. 2009. Removal of azo and anthraquinone reactive dyes from industrial wastewaters using MgO nanoparticles. Journal of Hazardous Materials, 168(2–3): 806-812.
- 29. Obiad, A.J., Al-Sultan, A.A. 2020. CWWQI on the Evaluation of Effluent Wastewater from Al-Dora Refinery WWTP. IOP Conference Series: Materials Science and Engineering.
- 30. Park, H., Chang, I., Lee, K. 2015. Principles of Membrane Bioreactors for Wastewater Treatment, CRC Press, Taylor & Francis Group.
- 31. Pendergast, M.M., Hoek E.M.V. 2011. A review of water treatment membrane nanotechnologies. Energy & Environmental Science, 4(6)
- 32. Sadiq, A.J., Shabeeb, K.M., Khalil, B.I., Alsalhy, Q.F. 2020. Effect of embedding MWCNT-g-GO with PVC on the performance of PVC membranes for oily wastewater treatment. Chemical Engineering Communications, 207(6)
- 33. Sarbatly, R. 2020. Membrane Technology for Water and Wastewater Treatment in Rural Regions. Hershey PA, USA, IGI Global.
- 34. Van der Bruggen, B., Daems, B., Wilms, D., Vandecasteele, C. 2001. Mechanisms of retention and flux decline for the nanofiltration of dye baths from the textile industry. Separation and Purification Technology, 22, 519–528.
- 35. Vatanpour, V., Madaeni S.S., Moradian R., Zinadini S., Astinchap B. 2011. Fabrication and characterization of novel antifouling nanofiltration membrane prepared from oxidized multiwalled carbon nanotube/polyethersulfone nanocomposite. Journal of Membrane Science, 375(1–2), 284–294.
- 36. Wang, X., Feng, M., Liu, Y., Deng, H., Lu, J. 2019. Fabrication of graphene oxide blended polyethersulfone membranes via phase inversion assisted by electric field for improved separation and antifouling performance. Journal of Membrane Science, 577, 41–50.
- 37. Yahya, A. A., K. T. Rashid, M. Y. Ghadhban, N. E. Mousa, H. S. Majdi, I. K. Salih and Q. F. Alsalhy (2021). “Removal of 4-Nitrophenol from Aqueous Solution by Using Polyphenylsulfone-Based Blend Membranes: Characterization and Performance.” Membranes (Basel) 11(3).
- 38. Yaseen, D. A. and M. Scholz (2018). “Textile dye wastewater characteristics and constituents of synthetic effluents: a critical review.” International Journal of Environmental Science and Technology 16(2): 1193–1226.
- 39. Zhao, C., X. Xu, J. Chen, G. Wang and F. Yang (2014). “Highly effective antifouling performance of PVDF/graphene oxide composite membrane in membrane bioreactor (MBR) system.” Desalination 340: 59–66.
- 40. Zinadini, S., A. A. Zinatizadeh, M. Rahimi, V. Vatanpour and H. Zangeneh (2014). “Preparation of a novel antifouling mixed matrix PES membrane by embedding graphene oxide nanoplates.” Journal of Membrane Science 453: 292–301.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-95f243a3-0d9f-4dbc-90a2-81c7c8cc0299