پژوهش های کاربردی مهندسی شیمی - پلیمر
فصلنامه علمی - پژوهشی

بررسی عملکرد غشاهای زمینه‌مخلوط‌ مغناطیسی پلی سولفون ذرات نئودیمیم به منظور جداسازی O2/N2

نوع مقاله : پژوهشی اصیل

نویسندگان

صبا روشیان 1
جواد کریمی ثابت 2
سید سعید حسینی 1

1 دانشگاه تربیت مدرس

2 پژوهشگاه علوم و فنون هسته ای

چکیده
در سال­های اخیر، به­دلیل هزینه بالا و مصرف زیاد انرژی در روش­های تقطیر برودتی و جذب سطحی، تلاش­های بسیاری در راستای بهبود عملکرد غشاهای پلیمری در جداسازی اکسیژن- نیتروژن صورت گرفته است. همچنان افزایش عملکرد این دسته از غشاها برای کاربردهای صنعتی ضروری است.

در این پژوهش، غشاهای زمینه‌مخلوط‌ مغناطیسی جدید با استفاده از پلی­سولفون به­عنوان زمینه اصلی غشا و ذرات مغناطیسی نئودیمیم برای جداسازی اکسیژن- نیتروژن ساخته شدند. غشاهای زمینه‌مخلوط‌ مغناطیسی در حضور میدان مغناطیسی به­منظور جلوگیری از ته­نشینی ذرات و پراکندگی مناسب ذرات در زمینه پلیمر ساخته شدند. اثر مقادیر مختلف ذرات نئودیمیم بر ساختار غشاها، خواص مغناطیسی و پایداری حرارتی غشاها با آزمون­های میکروسکوپی الکترونی پویشی، مغناطیس­سنجی نمونه ارتعاشی و گرماوزن­سنجی مورد ارزیابی قرار گرفت. همچنین برای بررسی عملکرد غشاهای ساخته شده در حضور میدان­های مغناطیسی مختلف، ماژول جداسازی مغناطیسی جدیدی طراحی و ساخته شد.

نتایج به­دست­آمده نشان دادند که تراوایی گازهای اکسیژن و نیتروژن با افزودن ذرات مغناطیسی نئودیمیم صرف­نظر از میزان مقدار میدان مغناطیسی اعمالی حین فرایند جداسازی به­دلیل برهم­خوردن تراکم زنجیرهای پلیمر و ازدیاد حجم آزاد پلیمر، روند افزایشی داشته است. تراوایی گازهای اکسیژن و نیتروژن در غشاهای زمینه‌مخلوط‌ حاوی 5 درصد وزنی نئودیمیم در غیاب میدان مغناطیسی به­ترتیب 182% و 443% نسبت به غشاهای خالص پلی­سولفون افزایش یافت. همچنین، تراوایی و گزینش­پذیری جفت­های گازی مذکور مورد مطالعه با اعمال میدان مغناطیسی طی فرایند جداسازی، افزایش یافت. با افزایش میدان مغناطیسی از 0 به 570 میلی تسلا، گزینش­پذیری غشاهای زمینه‌مخلوط‌ حاوی 5 درصد وزنی نئودیمیم از 73/2 به 77/3 افزایش یافت. براساس نتایج، افزودن ذرات نئودیمیم و همچنین استفاده از میدان مغناطیسی در طول فرایند ساخت و بررسی عملکرد غشا می­تواند روشی مؤثر برای بهبود عملکرد غشا محسوب شود.

کلیدواژه‌ها

: جداسازی اکسیژن- نیتروژن
پلی‌سولفون
نئودیمیم
غشاهای شبکه آمیخته مغناطیسی
ماژول جداسازی مغناطیسی

موضوعات

عنوان مقاله English

Investigation the performance of Polysulfone/Neodymium Magnetic Mixed-Matrix Membranes for O2/N2 Separation

نویسندگان English

Saba Raveshiyan 1
Javad Karimi-Sabet 2
Seyed Saeid Hosseini 1
1 Tarbiat Modares University
2 Nuclear Science and Technology Research Institute
چکیده English

Abstract

Research subject: In recent years, many efforts have been made to improve the performance of polymer membranes in oxygen-nitrogen separation due to the high cost and energy consumption of cryogenic distillation and adsorption methods. Increasing the performance of these types of membranes is still needed for industrial applications.

Research approach: In this research, novel magnetic mixed matrix membranes (MMMs) were prepared using polysulfone (PSf) as the main matrix, and also neodymium (Nd) as the magnetic particles for O2/N2 separation. To avoid the particle sedimentation and proper dispersion of particles across the membrane thickness, magnetic particle dispersion in the PSf was controlled by applying an external magnetic field (MF). The effect of Nd magnetic particle content on the microstructure, magnetic properties and thermal stability of the prepared MMMs were investigated using scanning electron microscopy, vibrating sample magnetometer and thermo-gravimetric analysis. In this reseach, a novel magnetic module was designed and constructed to investigate the performance of prepared membranes in the presence of various MFs.

Main Results: The obtained results indicated that the permeability of O2 and N2 gases was improved by adding Nd magnetic particles into PSf matrix regardless of the amount of MF due to the chain packing of polymers disruption and free volume enhancement. The permeability of O2 and N2 in the MMMs containing 5 wt.% Nd in the absence of MF was about 182 % and 443%, respectively, higher than those of neat PSf membranes. Furthermore, the permeability and selectivity of PSf and PSf-Nd membranes were considerably improved by applying the MF during the permeation experiments. In the MMMs containing 5 wt.% Nd, O2/N2 selectivity was increased from 2.73 to 3.77 upon an increase in the intensity of MF from 0 to 570 mT. Considering the findings, the application of Nd particles and MF during the membrane preparation and separation processes can be facile methods for enhancement of membrane performance.



Keywords: Oxygen/nitrogen separation; Polysulfone; Neodymium; Magnetic mixed-matrix membranes; Magnetic separation module

کلیدواژه‌ها English

Oxygen/nitrogen separation
Polysulfone
Neodymium
Magnetic mixed matrix membranes
Magnetic separation module
[1] Hassanajili S, Khademi M, Keshavarz P, Influence of Various Types of Silica Nanoparticles on Permeation Properties of Polyurethane/Silica Mixed Matrix Membranes, Journal of Membrane Science, 453,369-383, 2014.
[2] Kiadehi AD, Rahimpour A, Jahanshahi M, Novel Carbon Nano-Fibers (CNF)/Polysulfone (PSf) Mixed Matrix Membranes for Gas Separation, Journal of Industrial and Engineering Chemistry, 22,199-207, 2015.
[3] Hosseini SS, Najari S, Kundu PK, Simulation and Sensitivity Analysis of Transport in Asymmetric Hollow Fiber Membrane Permeators for Air Separation, RSC Advances, 5,86359-86370, 2015.
[4] Hosseini SS, Dehkordi JA, Kundu PK, Gas permeation and Separation in Asymmetric Hollow Fiber Membrane Permeators, Mathematical Modeling, Sensitivity Analysis and Optimization, Korean Journal of Chemical Engineering, 33,3085-3101, 2016.
[5] Castarlenas S, Téllez C, Coronas J, Gas Separation with Mixed Matrix Membranes Obtained from MOF UiO-66-Graphite Oxide Hybrids, Journal of Membrane Science, 526,205-211, 2017.
[6] Heidari M, Hosseini SS, Omidkhah M, Synthesis and Fabrication of Adsorptive Carbon Nanoparticles (ACNs)/PDMS Mixed Matrix Membranes for Efficient CO2/CH4 and C3H8/CH4 Separation, Separation and Purification Technology, 209,503-515, 2019.
[7] Castro-Domínguez B, Leelachaikul P, Takagaki A, Perfluorocarbon-Based Supported Liquid Membranes for O2/N2 Separation, Separation and Purification Technology, 116,19-24, 2013.
[8] Vinson DR, Air Separation Control Technology,Computers & Chemical Engineering, 30,1436-1446, 2006.
[9] Campo M, Magalhães F, Mendes A, Separation of Nitrogen from Air by Carbon Molecular Sieve Membranes, Journal of Membrane Science, 350,139-147, 2010.
[10] Murali RS, Sankarshana T, Sridhar S, Air Separation by Polymer-Based Membrane Technology, Separation & Purification Reviews, 42,130-186, 2013.
[11] Kansha Y, Kishimoto A, Nakagawa T, A Novel Cryogenic Air Separation Process Based on Self-Heat Recuperation, Separation and Purification Technology, 77,389-396, 2011.
[12] Rodrigues MA, de Souza Ribeiro J, de Souza Costa E, Nanostructured Membranes Containing UiO-66 (Zr) and MIL-101 (Cr) for O2/N2 and CO2/N2 Separation, Separation and Purification Technology, 192,491-500, 2018.
[14] Aneke M, Wang M, Potential for Improving the Energy Efficiency of Cryogenic Air Separation Unit (ASU) Using Binary Heat Recovery Cycles, Applied Thermal Engineering, 81,223-231, 2015.
[14] Hosseini S.S, Shafiei K, Study and Investigation on the Performance of Membranes
Developed Based on Polysulfone for Air Separation Process, Farayand No, 10, 126-148, 2015.
[15] Emrani A, Saber M, A Decision Tree for Technology Selection of Nitrogen Production Plants, Journal of Chemical and Petroleum Engineering, 45,1-11, 2011.
[16] Robeson LM, Correlation of Separation Factor Versus Permeability for Polymeric Membranes, Journal of membrane science, 62,165-185, 1991.
[17] Robeson LM, The Upper Bound Revisited, Journal of Membrane Science, 320,390-400, 2008.
[18] Aghaei Z, Naji L, Asl VH, The Influence of Fumed Silica Content and Particle Size in Poly (Amide 6-b-Ethylene Oxide) Mixed Matrix Membranes for Gas Separation, Separation and Purification Technology, 199,47-56, 2018.
[19] Soleimany A, Karimi-Sabet J, Hosseini SS, Experimental and Modeling Investigations Towards Tailoring Cellulose Triacetate Membranes for High Performance Helium Separation, Chemical Engineering Research Design, 137,194-212, 2018.
[21] Soleimany A, Hosseini SS, Gallucci F, Recent Progress in Developments of Membrane Materials and Modification Techniques for High Performance Helium Separation and Recovery, A review, Chemical Engineering and Processing, Process Intensification,122, 296-318, 2017.
[21] Wu X, Tian Z, Wang S, Mixed Matrix Membranes Comprising Polymers of Intrinsic Microporosity and Covalent Organic Framework for Gas Separation, Journal of Membrane Science, 528,273-283, 2017.
[22] Perez EV, Balkus KJ, Ferraris JP, Mixed-Matrix Membranes Containing MOF-5 for Gas Separations, Journal of Membrane Science, 328,165-173, 2009.
[23] Jusoh N, Yeong YF, Lau KK, Enhanced Gas Separation Performance Using Mixed Matrix Membranes Containing Zeolite T and 6FDA-Durene Polyimide, Journal of Membrane Science, 525,175-186, 2017.
[24] Rybak A, Grzywna ZJ, Sysel P, Mixed Matrix Membranes Composed of Various Polymer Matrices and Magnetic Powder for Air Separation, Separation and Purification Technology, 118,424-431, 2013.
[25] Rybak A, Rybak A, Kaszuwara W, Characterization of Selected Parameters of Organic-Inorganic Hybrid Membranes Based on Various Polymers and Nd-Fe-B Fillers, Arch. Metall. Mater 61,1825-1832, 2016.
[26] Rybak A, Strzelewicz A, Krasowska M, Influence of Various Parameters on the Air Separation Process by Magnetic Membranes, Separation Science Technology, 47,1395-1404, 2012.
[27] Rybak A, Rybak A, Kaszuwara W, The Magnetic Inorganic-Organic Hybrid Membranes Based on Polyimide Matrices for Gas Separation, Composites Part B, Engineering 110,161-170, 2017.
[28] Rybak A, Dudek G, Krasowska M , Magnetic Mixed Matrix Membranes Consisting of PPO Matrix and Magnetic Filler in Gas Separation, Separation Science Technology, 49,1729-1735, 2014.
[29] Rybak A, Kaszuwara W, Magnetic Properties of the Magnetic Hybrid Membranes Based on Various Polymer Matrices and Inorganic Fillers, Journal of Alloys and Compounds, 648,205-214, 2015.
[30] Rybak A, Grzywna ZJ, Kaszuwara W, On the Air Enrichment by Polymer Magnetic Membranes, Journal of Membrane Science, 336,79-85, 2009.
[31] Rybak A, Rybak A, Kaszuwara W, Poly (2, 6-Dimethyl-1, 4-Phenylene Oxide) Hybrid Membranes Filled with Magnetically Aligned Iron-Encapsulated Carbon Nanotubes (Fe@ MWCNTs) for Enhanced Air Separation, Diamond Relat Mater, 83,21-29, 2018.
[32] Dudek G, Turczyn R, Strzelewicz A, Preparation and Characterization of Iron Oxides–Polymer Composite Membranes, Separation Science Technology, 47,1390-1394, 2012.
[33] Rybak A, Rybak A, Kaszuwara W, The Rheological and Mechanical Properties of Magnetic Hybrid Membranes for Gas Mixtures Separation, Materer Letter, 183,170-174, 2016.
[34] Madaeni S, Enayati E, Vatanpour V, Separation of Nitrogen and Oxygen Gases by Polymeric Membrane Embedded with Magnetic Nano‐Particle, Polymers for Advanced Technologies, 22,2556-2563, 2011.
[35] Cai J, Wang L, Wu P, Study on Oxygen Enrichment from Air by Application of the Gradient Magnetic Field, Journal of Magnetism and Magnetic Materials, 320,171-181, 2008.
[36] Krasowska M, Rybak A, Dudek G, Structure Morphology Problems in the Air Separation by Polymer Membranes with Magnetic Particles, Journal of Membrane Science, 415,864-870, 2012.
[37] Rybak A, Krasowska M, Strzelewicz A, " Smoluchowski type" Equations for Modelling of Air Separation by Membranes with Various Structure, Acta Phys Pol, B 40,1447, 2009.
[38] Krasowska M, Strzelewicz A, Rybak A , Structure and Transport Properties of Ethylcellulose Membranes with Different Types and Granulation of Magnetic Powder, Physica A, Statistical Mechanics and its Applications, 452,241-250, 2016.
[39] Rybak A, Rybak A, Kaszuwara W, The Studies on Novel Magnetic Polyimide Inorganic-Organic Hybrid Membranes for Air Separation, Material Letter, 208,14-18, 2017.
[40] Kiadehi AD, Jahanshahi M, Rahimpour A, Fabrication and Evaluation of Functionalized Nano-titanium Dioxide (F-NanoTiO2)/polysulfone (PSf) Nanocomposite Membranes for Gas Separation, Iranian Journal of Chemical Engineering, 11,41-49, 2014.
[41] Kapantaidakis G, Kaldis S, Dabou X, Gas Permeation through PSF-PI Miscible Blend Membranes, Journal of membrane science, 110,239-247, 1996.
[42] Momeni S, Pakizeh M, Preparation, Characterization and Gas Permeation Study of PSf/MgO Nanocomposite Membrane, Brazilian Journal of Chemical Engineering, 30,589-597, 2013.
[43] Hosseini SS, Li Y, Chung T-S, Enhanced Gas Separation Performance of Nanocomposite Membranes Using MgO Nanoparticles, Journal of Membrane Science, 302,207-217, 2007.
[44] Ahn J, Chung W-J, Pinnau I, Polysulfone/Silica Nanoparticle Mixed-Matrix Membranes for Gas Separation, Journal of Membrane Science, 314,123-133, 2008.
[45] Pallapa M, Yeow J, A Review of the Hybrid Techniques for the Fabrication of Hard Magnetic Microactuators Based on Bonded Magnetic Powders, Smart Materials and Structures, 24,1-12, 2014.
[46] Ismail AF, Rahim N, Mustafa A, Gas Separation Performance of Polyethersulfone/Multi-Walled Carbon Nanotubes Mixed Matrix Membranes, Separation and Purification Technology, 80,20-31, 2011.
[47] Azizi N, Mohammadi T, Behbahani RM, Comparison of Permeability Performance of PEBAX-1074/TiO2, PEBAX-1074/SiO2 and PEBAX-1074/Al2O3 Nanocomposite Membranes for CO2/CH4 Separation, Chemical Engineering Research and Design, 117,177-189, 2017.
[48] Moghadam F, Omidkhah M, Vasheghani-Farahani E, The Effect of TiO2 Nanoparticles on Gas Transport Properties of Matrimid5218-Based Mixed Matrix Membranes, Separation and Purification Technology, 77,128-136, 2011.
[49] Zhu W, Qin Y, Wang Z, Zhang J, Guo R and Li X, Incorporating the Magnetic Alignment of GO Composites into Pebax Matrix for Gas Separation, Journal of Energy Chemistry, 31, 1-10, 2019.

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