Page 45 - 《精细化工》2022年第3期
P. 45
第 3 期 蒋丽红,等: 凹凸棒石复合分离膜的研究进展 ·467·
深入的研究,不仅要满足复合膜的稳定性要求,还应 nanosheets in mixed matrix membranes for CO 2 separation[J].
Chemistry of Materials, 2020, 32(10): 4174-4184.
该注重复合膜的使用寿命及膜生产过程的“绿色化”。 [17] CHA-UMPONG W, HOSSEINI E, RAZMJOU A, et al. New
(2)ATP 复合分离膜的选择性是膜分离技术的 molecular understanding of hydrated ion trapping mechanism during
thermally-driven desalination by pervaporation using GO membrane[J].
关键因素之一,对于不同类型的混合物,还应该考 Journal of Membrane Science, 2020, 598: 117687.
虑通过不同改性方法改变 ATP 的孔径大小,提高分 [18] ESMAEILI-FARAJ S H, HASSANZADEH A, SHAKERIANKHOO
F, et al. Diesel fuel desulfurization by alumina/polymer nanocomposite
离效率。对于疏水性/亲水性/疏油性/亲油性的基膜 membrane: Experimental analysis and modeling by the response
材料,应确保膜材料表面微/纳米结构具有特殊官能 surface methodology[J]. Chemical Engineering and Processing:
Process Intensification, 2021, 164: 108396.
团和稳定的化学组成,以提高膜材料的选择性。 [19] ZHANG B B, YAN Q J, CHEN G, et al. Fabrication of mixed matrix
(3)ATP 复合分离膜展现出良好的 CO 2 分离能 membranes with zinc ion loaded titanium dioxide for improved CO 2
separation[J]. Separation and Purification Technology, 2021, 254: 117472.
力,可以尝试制备更多不同类型的 ATP 复合分离膜。 [20] ZHANG J G, XU Z W, SHAN M J, et al. Synergetic effects of
工业化带来严重的油水混合问题,也有望在 ATP 复 oxidized carbon nanotubes and graphene oxide on fouling control
and anti-fouling mechanism of polyvinylidene fluoride ultrafiltration
合分离膜上实现突破。 membranes[J]. Journal of Membrane Science, 2013, 448: 81-92.
[21] MOHAMMAD A W, TEOW Y H, ANG W L, et al. Nanofiltration
参考文献 membranes review: Recent advances and future prospects[J].
Desalination, 2015, 356: 226-254.
[1] AZEEZ A A, RHEE K Y, PARK S J, et al. Epoxy clay nanocomposites- [22] YAO Y J, ZHANG P X, JIANG C, et al. High performance polyester
processing, properties and applications: A review[J]. Composites Part reverse osmosis desalination membrane with chlorine resistance[J].
B: Engineering, 2013, 45(1): 308-320.
Nature Sustainability, 2021, 4(2): 138-146.
[2] ZHANG Y, WANG W B, ZHANG J P, et al. A comparative study [23] LI S Y, GAO B Y, WANG Y, et al. Antibacterial thin film nanocomposite
about adsorption of natural palygorskite for methylene blue[J]. reverse osmosis membrane by doping silver phosphate loaded
Chemical Engineering Journal, 2015, 262: 390-398.
[3] BRADLEY W F. The structural scheme of attapulgite[J]. American graphene oxide quantum dots in polyamide layer[J]. Desalination,
2019, 464: 94-104.
Mineralogist: Journal of Earth and Planetary Materials, 1940, 25(6): [24] WANG C Y, ZENG W J, JIANG T T, et al. Incorporating attapulgite
405-410.
[4] HADEN W L, SCHWINT I A. Attapulgite: Its properties and nanorods into graphene oxide nanofiltration membranes for efficient
dyes wastewater treatment[J]. Separation and Purification Technology,
applications[J]. Industrial & Engineering Chemistry, 1967, 59(9): 2019, 214: 21-30.
58-69.
[5] BAILEY S W. Summary of recommendations of AIPEA nomenclature [25] ZHAO X T, SU Y L, LIU Y N, et al. Free-standing graphene oxide-
palygorskite nanohybrid membrane for oil/water separation[J]. ACS
committee[J]. Clay Minerals, 1980, 15(1): 85-93.
Applied Materials & Interfaces, 2016, 8(12): 8247-8256.
[6] CAO E H, BRYANT R, WILLIAMS D J A. Electrochemical properties [26] CAI Y H, CHEN D Y, LI N J, et al. A self-cleaning heterostructured
of Na-attapulgite[J]. Journal of Colloid & Interface Science, 1996, membrane for efficient oil-in-water emulsion separation with stable
179(1): 143-150.
flux[J]. Advanced Materials, 2020, 32(25): 2001265.
[7] WANG W, WANG A Q. Recent progress in dispersion of [27] KHANSARY M A, MARJANI A, SHIRAZIAN S. On the search of
palygorskite crystal bundles for nanocomposites[J]. Applied Clay rigorous thermo-kinetic model for wet phase inversion technique[J].
Science, 2016, 119: 18-30.
Journal of Membrane Science, 2017, 538: 18-33.
[8] HUI A P (惠爱平), YANG F F (杨芳芳), KANG Y R (康玉茹), et al. [28] WEI D Y, ZHOU S Y, LI M S, et al. PVDF/palygorskite composite
High pressure homogenization assisted fabrication of CTAB modified ultrafiltration membranes: Effects of nano-clay particles on membrane
plant essential oil/palygorskite antibacterial composites[J]. Fine structure and properties[J]. Applied Clay Science, 2019, 181: 105171.
Chemicals (精细化工), 2021, 38(10): 2019-2024, 2033.
[9] MIDDEA A, SPINELLI L S, SOUZA JR F G, et al. Preparation and [29] ZHANG Y L, ZHAO J, CHU H Q, et al. Effect of modified attapulgite
addition on the performance of a PVDF ultrafiltration membrane[J].
characterization of an organo-palygorskite-Fe 3O 4 nanomaterial for Desalination, 2014, 344(344): 71-78.
removal of anionic dyes from wastewater[J]. Applied Clay Science, [30] YANG W J, SHAO D D, ZHOU Z, et al. Carbon quantum dots
2017, 139: 45-53.
[10] YANG M, DAI J H, WANG L J, et al. First principles study of (CQDs) nanofiltration membranes towards efficient biogas slurry
valorization[J]. Chemical Engineering Journal, 2020, 385: 123993.
structural stability against the distribution of Mg and Al atoms and [31] WU M Y, MA T Y, SU Y L, et al. Fabrication of composite
adsorption behaviors of heavy metals of attapulgite[J]. Computational nanofiltration membrane by incorporating attapulgite nanorods
Materials Science, 2019, 169: 109106.
[11] WANG Y Q, FENG Y, JIANG J L, et al. Designing of recyclable during interfacial polymerization for high water flux and antifouling
property[J]. Journal of Membrane Science, 2017, 544: 79-87.
attapulgite for wastewater treatments: A review[J]. ACS Sustainable [32] ZHANG T, LI Z Q, WANG W B, et al. Enhanced antifouling and
Chemistry & Engineering, 2018, 7(2): 1855-1869.
[12] MA Q L, CHENG H, FANE A G, et al. Recent development of antimicrobial thin film nanocomposite membranes with incorporation
of palygorskite/titanium dioxide hybrid material[J]. Journal of
advanced materials with special wettability for selective oil/water Colloid and Interface Science, 2019, 537: 1-10.
separation[J]. Small, 2016, 12(16): 2186-2202.
[13] LIU Y P, WANG J W, WANG Y, et al. High-flux robust PSF-b-PEG [33] WANG B, SUN Z M, SUN Q, et al. The preparation of bifunctional
electrospun air filtration membranes by introducing attapulgite for
nanofiltration membrane for the precise separation of dyes and the efficient capturing of ultrafine PMs and hazardous heavy metal
salts[J]. Chemical Engineering Journal, 2021, 405: 127051.
ions[J]. Environmental Pollution, 2019, 249: 851-859.
[14] GUO C S, LI N, QIAN X M, et al. Ultra-thin double Janus nanofiltration [34] YANG X, ZHOU S Y, LI M S, et al. Purification of cellulase
2+
+
membrane for separation of Li and Mg : "Drag" effect from carboxyl- fermentation broth via low cost ceramic microfiltration membranes
containing negative interlayer[J]. Separation and Purification Technology, with nanofibers-like attapulgite separation layers[J]. Separation and
2020, 230: 115567.
Purification Technology, 2017, 175: 435-442.
[15] XU Z W, WU T F, SHI J, et al. Manipulating migration behavior of [35] WANG F, ZHANG B, LIU S S, et al. Investigation of the attapulgite
magnetic graphene oxide via magnetic field induced casting and hybrid carbon molecular sieving membranes for permanent gas
phase separation toward high-performance hybrid ultrafiltration separation[J]. Chemical Engineering Research and Design, 2019, 151:
membranes[J]. ACS Applied Materials & Interfaces, 2016, 8(28): 146-156.
18418-18429.
[16] DENG J, DAI Z D, HOU J W, et al. Morphologically tunable MOF [36] HUANG D J, WANG W B, XU J X, et al. Mechanical and water