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Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması

Year 2020, Volume: 15 Issue: 1, 9 - 19, 18.01.2020

Abstract

     Endüstriyel atık
sulardan uçucu organik bileşenlerin giderilmesi çevre kirliliğinin önlenmesi
için oldukça önemlidir. Bu çalışmada polivinil klorür/perlit nanokompozit
filmler hazırlanarak uçucu organik bileşen metanolün pervaporasyon prosesi ile
sudan giderilmesi incelenmiştir. Hazırlanan polivinil klorür/perlit
nanokompozit filmler FTIR, TGA ve SEM ile karakterize edilmiştir. Polivinil klorür
film içindeki perlit konsantrasyonu, operasyon sıcaklığı, beslemedeki metanol
konsantrasyonu gibi parametrelerin pervaporasyon prosesi ile sudan metanolü
uzaklaştırmada etkisi incelenmiştir. Polivinil klorür/perlit nanokompozit
filmlerdeki perlit miktarı arttıkça ayırma faktörünün arttığı, geçiş hızının
ise azaldığı görülmüştür. Sıcaklık ve besleme konsantrasyonundaki artış ise
geçiş hızının artması ve ayırma faktörünün azalması ile sonuçlanmıştır.
Ağırlıkça %2 metanol besleme konsantrasyonunda, 30oC'de, %8 perlit
konsantrasyonunda 0.16kg/m2.sa akı ve 87 ayırma faktörü değeri elde
edilmiştir. Elde edilen bu değerler literatürdeki çalışmalarla kıyaslandığında
sulu çözeltilerden metanolün gideriminde PVC/perlit nanokompozit filmlerin
oldukça başarılı bir ayırma performansı sergilediğini göstermiştir.

References

  • [1] Zhao, W. and Shi, B.,(2009). Removal of Volatile Organic Compounds from Water by Pervaporation Using Polyetherimide-Polyethersulfone Blend Hollow Fiber Membranes, Separation Science and Technology, 44:1737–1752.
  • [2] Kujawa, J.,Cerneaux, S., and Kujawski, W.,(2015). Highly Hydrophobic Ceramic Membranes Applied to the Removal of Volatile Organic Compounds in Pervaporation. Chemical Engineering Journal, 260:43–54.
  • [3] Tancharernrat, T., Rempel, G.L., and Prasassarakich, P., (2014). Preparation of Styrene Butadiene Copolymer-Silica Nanocomposites Via Differential Microemulsion Polymerization and NR/SBR-SiO2 Membranes for Pervaporation of Water Ethanol Mixtures. Chemical Engineering Journal, 258:290–300.
  • [4] Al-Dawery, S., (2013). Methanol Removal from Methanol-Water Mixture Using Municipal Activated Sludge. Journal of Engineering Science and Technology, 8:578–587.
  • [5] Hsu, L.J. and Lin, C.C.,(2011). Removal of Methanol and 1-Butanol from Binary Mixtures by Absorption in Rotating Packed Beds with Blade Packings. Chemical Engineering Journal, 168:190–200.
  • [6] Toth, A.J. and Mizsey, P., (2015). Methanol Removal from Aqueous Mixture with Organophilic Pervaporation: Experiments and Modelling, Chemical Engineering Research and Design, 98:123–135.
  • [7] Aliabadi, M., Aroujalian, A., and Raisi, A.,(2012). Removal of Styrene from Petrochemical Wastewater Using Pervaporation Process. Desalination, 284:116–121.
  • [8] Basile, A., Figoli, A., and Khayet, M., (2015). Pervaporation, Vapour Permeation and Membrane Distillation: Principles and Applications, 1st ed., Woodhead Publishing, UK,.
  • [9] Drioli, E. and Giorno, L., (2010). Comprehensive Membrane Science and Engineering Volume 1 Basic Aspects of Membrane Science and Engineering, Elsevier, United Kingdom.
  • [10] Wu, X.M., Zhang, Q.G., Soyekwo, F., Liu, Q.L., and Zhu, A.M.,(2016). Pervaporation Removal of Volatile Organic Compounds from Aqueous Solutions Using the Highly Permeable PIM-1 Membrane, AIChE Journal, 62:842–851.
  • [11] Hu, K., Nie, J., Liu, J., and Zheng, J., (2013). Separation of Methanol from Methanol/water Mixtures with Pervaporation Hybrid Membranes, Journal of Applied Polymer Science, 128:1469–1475.
  • [12] Yang, C.J. and Jackson, R.B.,(2012). China's Growing Methanol Economy and its Implications for Energy and the Environment. Energy Policy, 41:878-884.
  • [13] Goellner, J., Kuehn, N., Shah, V., White, C., and Woods, M.,(2014). Baseline Analysis of Crude Methanol Production from Coal and Natural Gas, National Energy Technology Laboratory, Available at: https://www.netl.doe.gov/energy-analysis/details?id=720 [Erişim 28.02.19].
  • [14] Yang, C.J. and Shale, U.S., (2015). Gas Versus China’s Coal as Chemical Feedstock, Environmental Science & Technology, 49:9501–9502.
  • [15] Wen, Z., Meng, F., Di, J., and Tan, Q., (2016). Technological Approaches and Policy Analysis of Integrated Water Pollution Prevention and Control for the Coal-To-Methanol Industry Based on Best Available Technology, Journal of Cleaner Production, 113:231–240.
  • [16] Babbitt, C.W., Pacheco, A., and Lindner, A.S.,(2009). Methanol Removal Efficiency and Bacterial Diversity of an Activated Carbon Biofilter. Bioresource Technology, 100:6207–6216.
  • [17] Kujawski, W., (2000). Pervaporative Removal of Organics from Water Using Hydrophobic Membranes. Binary Mixtures, Separation Science and Technology, 35:89–108.
  • [18] Osorio-Galindo, M., Iborra-Clar, A., Alcaina-Miranda, I., and Ribes-Greus, A.,(2001) Characterization of poly(dimethylsiloxane)-poly(methyl hydrogen siloxane) Composite Membranes for Organic Water Pervaporation Separation. Journal of Applied Polymer Science, 81:546–556.
  • [19] Unlu, D., (2019). Fabrication and Application of Silicotungstic Acid/Polyvinyl Alcohol and Phosphomolybdic Acid/Polyvinyl Alcohol Hybrid Membrane for Pervaporative Dehydration of Isopropanol Solution, Macromolecular Research, Vol:27, pp: 998–1008.
  • [20] Ramesh, S., Leen, K.H., Kumutha, K., and Arof, A.K., (2007). FTIR Studies of PVC/PMMA Blend Based Polymer Electrolytes, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 66:1237–1242.
  • [21] Kolvari, E., Koukabi, N., and Hosseini, M.M.,(2015). Perlite: A Cheap Natural Support for Immobilization of Sulfonic Acid As a Heterogeneous Solid Acid Catalyst for the Heterocyclic Multicomponent Reaction, Journal of Molecular Catalysis A: Chemical, 397:68–75.
  • [22] Yi, S., Su, Y., and Wan, Y., (2010). Preparation and Characterization of Vinyltriethoxysilane (VTES) Modified Silicalite-1/PDMS Hybrid Pervaporation Membrane and its Application in Ethanol Separation from Dilute Aqueous Solution, Journal of Membrane Science, 360:341–351.
  • [23] Bakhshi, A., Mohammadi, T., Nik, O.G., and Aroujalian, A., (2006). Effect of Operating Conditions on Pervaporation of Methanol-water Mixtures: Part 2, Membrane Technology, pp:7–11.
Year 2020, Volume: 15 Issue: 1, 9 - 19, 18.01.2020

Abstract

References

  • [1] Zhao, W. and Shi, B.,(2009). Removal of Volatile Organic Compounds from Water by Pervaporation Using Polyetherimide-Polyethersulfone Blend Hollow Fiber Membranes, Separation Science and Technology, 44:1737–1752.
  • [2] Kujawa, J.,Cerneaux, S., and Kujawski, W.,(2015). Highly Hydrophobic Ceramic Membranes Applied to the Removal of Volatile Organic Compounds in Pervaporation. Chemical Engineering Journal, 260:43–54.
  • [3] Tancharernrat, T., Rempel, G.L., and Prasassarakich, P., (2014). Preparation of Styrene Butadiene Copolymer-Silica Nanocomposites Via Differential Microemulsion Polymerization and NR/SBR-SiO2 Membranes for Pervaporation of Water Ethanol Mixtures. Chemical Engineering Journal, 258:290–300.
  • [4] Al-Dawery, S., (2013). Methanol Removal from Methanol-Water Mixture Using Municipal Activated Sludge. Journal of Engineering Science and Technology, 8:578–587.
  • [5] Hsu, L.J. and Lin, C.C.,(2011). Removal of Methanol and 1-Butanol from Binary Mixtures by Absorption in Rotating Packed Beds with Blade Packings. Chemical Engineering Journal, 168:190–200.
  • [6] Toth, A.J. and Mizsey, P., (2015). Methanol Removal from Aqueous Mixture with Organophilic Pervaporation: Experiments and Modelling, Chemical Engineering Research and Design, 98:123–135.
  • [7] Aliabadi, M., Aroujalian, A., and Raisi, A.,(2012). Removal of Styrene from Petrochemical Wastewater Using Pervaporation Process. Desalination, 284:116–121.
  • [8] Basile, A., Figoli, A., and Khayet, M., (2015). Pervaporation, Vapour Permeation and Membrane Distillation: Principles and Applications, 1st ed., Woodhead Publishing, UK,.
  • [9] Drioli, E. and Giorno, L., (2010). Comprehensive Membrane Science and Engineering Volume 1 Basic Aspects of Membrane Science and Engineering, Elsevier, United Kingdom.
  • [10] Wu, X.M., Zhang, Q.G., Soyekwo, F., Liu, Q.L., and Zhu, A.M.,(2016). Pervaporation Removal of Volatile Organic Compounds from Aqueous Solutions Using the Highly Permeable PIM-1 Membrane, AIChE Journal, 62:842–851.
  • [11] Hu, K., Nie, J., Liu, J., and Zheng, J., (2013). Separation of Methanol from Methanol/water Mixtures with Pervaporation Hybrid Membranes, Journal of Applied Polymer Science, 128:1469–1475.
  • [12] Yang, C.J. and Jackson, R.B.,(2012). China's Growing Methanol Economy and its Implications for Energy and the Environment. Energy Policy, 41:878-884.
  • [13] Goellner, J., Kuehn, N., Shah, V., White, C., and Woods, M.,(2014). Baseline Analysis of Crude Methanol Production from Coal and Natural Gas, National Energy Technology Laboratory, Available at: https://www.netl.doe.gov/energy-analysis/details?id=720 [Erişim 28.02.19].
  • [14] Yang, C.J. and Shale, U.S., (2015). Gas Versus China’s Coal as Chemical Feedstock, Environmental Science & Technology, 49:9501–9502.
  • [15] Wen, Z., Meng, F., Di, J., and Tan, Q., (2016). Technological Approaches and Policy Analysis of Integrated Water Pollution Prevention and Control for the Coal-To-Methanol Industry Based on Best Available Technology, Journal of Cleaner Production, 113:231–240.
  • [16] Babbitt, C.W., Pacheco, A., and Lindner, A.S.,(2009). Methanol Removal Efficiency and Bacterial Diversity of an Activated Carbon Biofilter. Bioresource Technology, 100:6207–6216.
  • [17] Kujawski, W., (2000). Pervaporative Removal of Organics from Water Using Hydrophobic Membranes. Binary Mixtures, Separation Science and Technology, 35:89–108.
  • [18] Osorio-Galindo, M., Iborra-Clar, A., Alcaina-Miranda, I., and Ribes-Greus, A.,(2001) Characterization of poly(dimethylsiloxane)-poly(methyl hydrogen siloxane) Composite Membranes for Organic Water Pervaporation Separation. Journal of Applied Polymer Science, 81:546–556.
  • [19] Unlu, D., (2019). Fabrication and Application of Silicotungstic Acid/Polyvinyl Alcohol and Phosphomolybdic Acid/Polyvinyl Alcohol Hybrid Membrane for Pervaporative Dehydration of Isopropanol Solution, Macromolecular Research, Vol:27, pp: 998–1008.
  • [20] Ramesh, S., Leen, K.H., Kumutha, K., and Arof, A.K., (2007). FTIR Studies of PVC/PMMA Blend Based Polymer Electrolytes, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 66:1237–1242.
  • [21] Kolvari, E., Koukabi, N., and Hosseini, M.M.,(2015). Perlite: A Cheap Natural Support for Immobilization of Sulfonic Acid As a Heterogeneous Solid Acid Catalyst for the Heterocyclic Multicomponent Reaction, Journal of Molecular Catalysis A: Chemical, 397:68–75.
  • [22] Yi, S., Su, Y., and Wan, Y., (2010). Preparation and Characterization of Vinyltriethoxysilane (VTES) Modified Silicalite-1/PDMS Hybrid Pervaporation Membrane and its Application in Ethanol Separation from Dilute Aqueous Solution, Journal of Membrane Science, 360:341–351.
  • [23] Bakhshi, A., Mohammadi, T., Nik, O.G., and Aroujalian, A., (2006). Effect of Operating Conditions on Pervaporation of Methanol-water Mixtures: Part 2, Membrane Technology, pp:7–11.
There are 23 citations in total.

Details

Primary Language Turkish
Subjects Engineering
Journal Section Articles
Authors

Derya Ünlü 0000-0001-5240-5876

Publication Date January 18, 2020
Published in Issue Year 2020 Volume: 15 Issue: 1

Cite

APA Ünlü, D. (2020). Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması. Physical Sciences, 15(1), 9-19.
AMA Ünlü D. Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması. Physical Sciences. January 2020;15(1):9-19.
Chicago Ünlü, Derya. “Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması Ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması”. Physical Sciences 15, no. 1 (January 2020): 9-19.
EndNote Ünlü D (January 1, 2020) Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması. Physical Sciences 15 1 9–19.
IEEE D. Ünlü, “Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması”, Physical Sciences, vol. 15, no. 1, pp. 9–19, 2020.
ISNAD Ünlü, Derya. “Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması Ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması”. Physical Sciences 15/1 (January 2020), 9-19.
JAMA Ünlü D. Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması. Physical Sciences. 2020;15:9–19.
MLA Ünlü, Derya. “Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması Ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması”. Physical Sciences, vol. 15, no. 1, 2020, pp. 9-19.
Vancouver Ünlü D. Polivinil Klorür/Perlit Nanokompozit Filmlerin Hazırlanması ve Uçucu Organik Bileşen Metanolün Pervaporasyon İle Sudan Giderilmesinde Kullanılması. Physical Sciences. 2020;15(1):9-19.