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Polymer Science, Series D
Erschienen in: Polymer Science, Series D 4/2022

01.12.2022

Membrane Purification of Depleted Emulsions by Polymer Membranes (Brief Literature Review)

verfasst von: V. O. Dryakhlov, I. G. Shaykhiev, T. R. Deberdeev, S. V. Sverguzova

Erschienen in: Polymer Science, Series D | Ausgabe 4/2022

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Abstract

Literature sources regarding membrane purification of emulsified wastewaters containing hydrocarbons have been reviewed. A traditional means of preliminary purification of the disperse phase in order to reduce clogging of membranes has been presented. As an alternative promising option, the possibility has been considered of modification of membranes by chemical reagents in order to give them hydrophobic, amphiphilic, and hydrophilic properties for separation of direct and reverse emulsions. The main patterns of change in membrane properties and characteristics were considered, including changing of moistening, chemical composition, porosity, and roughness, which promote an increase in the performance and selectivity of the process under consideration. A method to recuperate the concentrate of membrane separation of emulsion as an inhibitor of corrosion has been proposed. The issues of membrane regeneration have been briefly covered.
Vorheriger Artikel The Research of the Influence of the Parameters of 3D Printing on the Strength Characteristics of Plastic Products
Nächster Artikel Carbon Plastics in the Design of Space-Technology Products (Review)

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Literatur
1.
X. Yue, Z. Li., T. Zhang, D. Yang, et al., “Design and fabrication of superwetting fiber-based membranes for oil/water separation applications,” Chem. Eng. J. 364, 292–309 (2019).CrossRef
2.
N. H. Ismail, W. N. W. Salleh, et al., “Hydrophilic polymer-based membrane for oily wastewater treatment: A review,” Separation and Purification Tech. 233, 18 (2020).CrossRef
3.
Y. Chen and Q. Liu Q, “Progress and prospects in membrane technology for oil/water separation.” ACS Symp. Ser. 1348, 73–87 (2020).CrossRef
4.
R. Su, S. Li, W. Wu, et al., “Recent progress in electrospun nanofibrous membranes for oil/water separation,” Separation and Purification Techn. 256, 22 (2021).CrossRef
5.
J. Zhang, L. Liu, Y. Si Y, et al., “Electrospun nanofibrous membranes: An effective arsenal for the purification of emulsified oily wastewater,” Adv. Funct. Mater. 30, 25 (2020).
6.
N. Ali, M. Bilal, A. Khan, et al., “Design, engineering and analytical perspectives of membrane materials with smart surfaces for efficient oil/water separation,” Trends in Anal. Chem. 12725, (2020).
7.
J. Luo, Z. Huang, L. Liu, et al., “Recent advances in separation applications of polymerized high internal phase emulsions,” J. Separation Sci. 44, 169–187 (2021).CrossRef
8.
Y. Yang, N. Ali, M. Bilal, et al., “Robust membranes with tunable functionalities for sustainable oil/water separation,” J. Molec. Liquids 321, 25 (2021).CrossRef
9.
E. Tummons, Q. Han, H. J. Tanudjaja, et al., “Membrane fouling by emulsified oil: A review,” Separation and Purification Technol. 248, 22 (2020).CrossRef
10.
Yu. R. Abdrakhimov, G. M. Sharafutdinova, R. I. Khangildin, et al., “Analysis of chemical production water systems of oil processing and petrochemical plants,” Neftegazovoe Delo, No. 6, 222–260 (2011).
11.
N. I. Posvyatenko, Yu. E. Demidova, and T. V. Mel’nik, “Physicochemical methods for purification of waste waters from oil products,” Vestn. Nats. Transp. Univ., No. 29, 250–258 (2014).
12.
A. I. Guslavskii and Z. A. Kanarskaya, “Advanced technologies for purification of water and soil from oil and oil products,” Vestn. Kazanskogo Tekhnol. Univ., No. 20, 191–199 (2011).
13.
M. M. Pendergast and E. M. V. Hoek, “A review of water treatment membrane nanotechnologies,” Energy Environ. Sci. 6, 1946–1971 (2011).CrossRef
14.
X. Zeng, L. Qian, X. Yuan, et al., “Inspired by Stenocara beetles: From water collection to high-efficiency water-in-oil emulsion separation,” ACS Nano 1, 760–769 (2017).CrossRef
15.
C. Zhou, J. Cheng, K. Hou, et al., “Superhydrophilic and underwater superoleophobic titania nanowires surface for oil repellency and oil/water separation,” Chem. Eng. J. 301, 249–256 (2016).CrossRef
16.
O. G. Degtyareva, T. I. Safronova, and G. V. Degtyarev, “Techniques and engineering means for protection of environment against spills of oil products,” Politematicheskii Setevoi Elektronnyi Nauch. Zh. Kubanskogo Gos. Agrar. Univ. 9, 64–83 (2005).
17.
V. V. Varnakov, I. A. Bysugin, and E. A. Shkalilov, “De-emulsification of oil products as a purification technique,” Alleya Nauki 2, 897–901 (2018).
18.
S. E. Plokhova, E. D. Sattarova, and A. A. Elpidinskii, “Study of the effect of anionic and cationic surface-active agents on the de-emulsifying efficiency of non-ionic surface-active agents,” Vestn. Kazanskogo Tekhnol. Univ. 15, 39–40 (2012).
19.
S. E. Plokhova, E. D. Sattarova, and A. A. Elpidinskii, “On the comparability of surface properties of de-emulsifiers and their de-emulsifying activity,” Vestn. Kazanskogo Tekhnol. Univ. 17, 274–276 (2014).
20.
C. Chen, D. Weng, A. Mahmood, et al., “Separation mechanism and construction of surfaces with special wettability for oil/water separation,” ACS Appl. Mater. Interfaces 11, 11006–11027 (2019).CrossRef
21.
Yu. K. Rubanov and Yu. E. Tokach, “Method of purification of sewage waters from emulsified oil products,” Vestn. Tekhnol. Univ. 18, 246–249 (2015).
22.
D. D. Fazullin, G. V. Mavrin, A. V. Savelyeva, et al., “Sewage treatment from heavy metal ions by the method of deposition, using sulfur-alkaline wastewater as a reagent,” Int. J. Green Pharmacy, Nos. 10–12, 831–835 (2017).
23.
O. G. Dubrovskaya, V. V. Evstigneev, and V. A. Kulagin, “Problems in sewage treatment of waste waters containing emulsified oil products in recirculating systems of closed-loop cycles of water utilization and the methods for their resolution,” J. Siberian Federal Univ. Eng. Technol., No. 6, 680–688 (2013).
24.
M. Mulder, Basic Principles of Membrane Technology (Springer, 1996; Moscow, 1999).
25.
M.-L. Pellegrin, S. Arabi, J. Aguinaldo, et al., “Membrane processes,” Water Environ. Res. 89, 1066–1135 (2017).CrossRef
26.
M. Johnson, G. Greg Liddiard, M. Eddings, et al., “Bubble inclusion and removal using PDMS membrane-based gas permeation for applications in pumping, valving and mixing in microfluidic devices,” J. Micromech. Microeng., No. 19, 1–9 (2009).
27.
V. P. Gavrilyuk and A. I. Konoplya, “Protein spectrum of erythrocyte membranes in the conditions of experimental acute pancreatitis and cholangitis,” Usp. Sovrem. Estestvozn., No. 10, 43–43 (2005).
28.
L. E. Ermakova, I. A. Savina. And M. P. Sidorova. “Structural and electric surface characteristics if anisotropic ultra-filtering membranes,” Vestn. St. Petersburg Gos. Univ., No. 1, 55–68 (2012).
29.
I. Sh. Abdullin, E. S. Nefedyev, R. G. Ibragimov, et al., “Application of membrane technology for purification of waste waters of leather and footwear plants,” Vestn. Kazanskogo Tekhnol. Univ., No. 3, 21–26 (2012).
30.
M. Masuelli, J. Marchese, and N. A. Ochoa, “SPC/ PVDF membranes for emulsified oily wastewater treatment,” J. Membr. Sci. 326, 688—693 (2009).CrossRef
31.
X. S. Yi, S. L. Yu, W. X. Shi, et al., “The influence of important factors on ultrafiltration of oil/water emulsion using PVDF membrane modified by nano-sized TiO2/Al2O3,” Desalination 281, 179–184 (2011).CrossRef
32.
M. P. Kozlov, V. B. Bochkarev, and V. P. Dubyaga, Ultra-filtration Purification of Water Mixtures from Emulsified Oils (Nauch.-Issled. Inst. Tekh.-Ekomom. Issled. v Khim. Komplekse, Moscow, 1985) [in Russian].
33.
A. A. Svitsov, Introduction to Membrane Technology (Izd. Ross. Khim.-Tekh. Univ., Moscow, 2007) [in Russian].
34.
L. E. Kopylova, A. O. Kashirin, and A. A. Svitsov, “Hybrid technology for separation of water-oil emulsions combining coalescence, filtration, and microfiltration,” Membr. Membr. Tekhnol 3, 277–282 (2013).
35.
W. Baker, Membrane Technology and Applications (Membrane Technology and Research, Newark, CA, 2012), 3rd ed.CrossRef
36.
C. Yang, N. Han, C. Han, et al., “Design of a Janus F‑TiO2 PPS porous membrane with asymmetric wettability for switchable oil/water separation.” ACS Appl. Mater. Interfaces 11, 22408–22418 (2019).CrossRef
37.
C. Yang, N. Han, W. Wang, et al., “Fabrication of a PPS microporous membrane for efficient water-in-oil emulsion separation,” Langmuir 34, 10580–10590 (2018).CrossRef
38.
N. Han, C. Yang, Z. Zhang, et al., “Electrostatic assembly of a titanium dioxide hydrophilic poly(phenylene sulfide) porous membrane with enhanced wetting selectivity for separation of strongly corrosive oil–water emulsions,” ACS Appl. Mater. Interfaces 38, 35479–35487 (2019).CrossRef
39.
C. F. Medina-Sandoval, J. A. Valencia-Davila, M. Y. Combariza, et al., “Separation of asphaltene-stabilized water in oil emulsions and immiscible oil/ water mixtures using a hydrophobic cellulosic membrane,” Fuel 231, 297–306 (2018).CrossRef
40.
J. Gu, P. Xiao, J. Chen, et al., “Robust preparation of superhydrophobic polymer/carbon nanotube hybrid membranes for highly effective removal of oils and separation of water in-oil emulsions,” J. Mater. Chem. A 37, 15268–15272 (2014).CrossRef
41.
L. Zhao, R. Li., R. Xu, et al., “Antifouling slippery liquid-infused membrane for separation of water-in-oil emulsions,” J. Membr. Sci. 611, 1–10 (2020).CrossRef
42.
J. Zhang and S. Seeger, “Polyester materials with superwetting silicone nanofilaments for oil/water separation and selective oil absorption,” Adv. Funct. Mater. 21, 4699–4704 (2011).CrossRef
43.
W. Zhang, Z. Shi, F. Zhang, et al., “Superhydrophobic and superoleophilic PVDF membranes for effective separation of water-in-oil emulsions with high flux,” Adv. Mater. 14, 2071–2076 (2013).CrossRef
44.
N. P. Tirmizi, B. Raghuraman, and J. Wiencek, “Demulsification of water/oil/solid emulsions by hollow-fiber membranes,” AIChE J. 42, 1263–1276 (1996).CrossRef
45.
X. Zhang, C. Liu, J. Yang, et al., “Wettability switchable membranes for separating both oil-in-water and water-in-oil emulsions,” J. Membrane Sci. 624, 1–26 (2021).CrossRef
46.
M. Tao, L. Xue, F. Liu, et al., “An intelligent superwetting PVDF membrane showing switchable transport performance for oil/water separation,” Adv. Mater. 18, 2943–2948 (2014).CrossRef
47.
W. Fang, L. Liu, and G. Guo, “Tunable wettability of electrospun polyurethane/silica composite membranes for effective separation of water-in-oil and oil-in-water emulsions,” Chem.–A Eur. J. 47, 11253–11260 (2017).CrossRef
48.
P. Srijaroonrat, E. Julien, and Y. Aurelle, “Unstable secondary oil/water emulsion treatment using ultrafiltration: Fouling control by backflushing,” J. Membr. Sci. 159, 11—20 (1999).CrossRef
49.
N. A. Ochoa, M. Masuelli, and J. Marchese, “Effect of hydrophilicity on fouling of an emulsified oil wastewater with PVDF/PMMA membranes,” J. Membr. Sci. 226, 203–211 (2003).CrossRef
50.
R. S. Faibish and Y. Cohen, “Fouling and rejection behavior of ceramic and polymer-modified ceramic membranes for ultrafiltration of oil-in-water emulsions and microemulsions,” Colloids and Surf. A 191, 27–40 (2001).CrossRef
51.
R. S. Faibish and Y. Cohen, “Fouling-resistant ceramic-supported polymer membranes for ultrafiltration of oil-in-water microemulsions,” J. Membr. Sci. 185, 129–143 (2001).CrossRef
52.
Zhang S., Jiang G., Gao S. et al., “Cupric phosphate nanosheets-wrapped inorganic membranes with superhydrophilic and outstanding anticrude oil-fouling property for oil/water separation,” ACS Nano 12, 795—803 (2018).CrossRef
53.
T. Yuan, J. Meng, T. Hao, et al., “A scalable method toward superhydrophilic and underwater superoleophobic PVDF membranes for effective oil/water emulsion separation,” ACS Appl. Mater. Interfaces. 27, 14896–14904 (2015).CrossRef
54.
A. Salahi, T. Mohammadi, R. M. Behbahani, et al., “Asymmetric polyethersulfone ultrafiltration membranes for oily wastewater treatment: Synthesis, characterization, ANFIS modeling, and performance,” J. Environ. Chem. Eng. 1, 170–178 (2015).CrossRef
55.
H. Zhan, N. Peng, X. Lei, et al., “UV-induced self-cleanable TiO2/nanocellulose membrane for selective separation of oil/water emulsion,” Carbohydrate Polym. 201, 464–470 (2018).CrossRef
56.
J. Lv., G. Zhang, H. Zhang, et al., “Improvement of antifouling performances for modified PVDF ultrafiltration membrane with hydrophilic cellulose nanocrystal,” Appl. Surf. Sci. 440, 1091–1100 (2018).CrossRef
57.
Y. Yang, A. Raza, F. Banat, et al., “The separation of oil in water (O/W) emulsions using polyether sulfone and nitrocellulose microfiltration membranes,” J. Water Process Eng. 25, 113–117 (2018).CrossRef
58.
Y. Xiong, C. Wang, H. Wang, et al., “Nano-cellulose hydrogel coated flexible titanate-bismuth oxide membrane for trinity synergistic treatment of super-intricate anion/cation/oily-water,” Chem. Eng. J. 337, 143–151 (2018).CrossRef
59.
Y. Zhang, X. Shan, Z. Jin Z, et al., “Synthesis of sulfated Y-doped zirconia particles and effect on properties of polysulfone membranes for treatment of wastewater containing oil,” J. Hazard. Mater. 192, 559–567 (2011).CrossRef
60.
P. Mitta, S. Jana, and K. Mohanty, “Synthesis of low-cost hydrophilic ceramic–polymeric composite membrane for treatment of oily wastewater,” Desalination 282, 54—62 (2011).CrossRef
61.
D. Vasanth, G. Pugazhenthi, and R. Uppaluri, “Cross-flow microfiltration of oil-in-water emulsions using low cost ceramic membranes,” Desalination 320, 86–95 (2013).CrossRef
62.
S. Emani, R. Uppaluri, and M. K. Purkait, “Cross flow microfiltration of oil–water emulsions using kaolin based low cost ceramic membranes,” Desalination 341, 61–71 (2014).CrossRef
63.
C. N. Matindi, M. Hu, S. Kadanyo, et al., “Tailoring the morphology of polyethersulfone/sulfonated polysulfone ultrafiltration membranes for highly efficient separation of oil-in-water emulsions using TiO2 nanoparticles,” J. Membr. Sci. 620, 1–15 (2021).CrossRef
64.
J. M. Benito, A. Conesa, F. Rubio, et al., “Preparation and characterization of tubular ceramic membranes for treatment of oil emulsions,” J. Eur. Ceramic Soc. 25, 1895–1903 (2005).CrossRef
65.
B. Jiang, K. Cheng, N. Zhang, et al., “One-step modification of PVDF membrane with tannin-inspired highly hydrophilic and underwater superoleophobic coating for effective oil-in-water emulsion separation,” Separation and Purification Tech. 255, 1–10 (2021).CrossRef
66.
Y. Zhu, J. Wang, F. Zhang, et al., “Zwitterionic nanohydrogel grafted PVDF membranes with comprehensive antifouling property and superior cycle stability for oil-in-water emulsion separation,” Adv. Funct. Mater. 28, 1–10 (2018).CrossRef
67.
X. Hong, X.-J. Huang, Q.-L. Gao, et al., “Microstructure–performance relationships of hollow-fiber membranes with highly efficient separation of oil-in-water emulsions,” J. Appl. Polymer Sci. 23, 1–10 (2019).
68.
K. Muthukumar, N. J. Kaleekkal, D. S. Lakshmi, et al., “Tuning the morphology of PVDF membranes using inorganic clusters for oil/water separation,” J. Appl. Polymer Sci. 24, 1–10 (2019).
69.
D. D. Fazullin and G. V. Mavrin, “Dynamic membrane with a polystyrene surface layer for ultrafiltration of spent coolant lubricant,” Chem. Petrol. Eng. 56, 215–222 (2020).CrossRef
70.
D. D. Fazullin, G. V. Mavrin, I. G. Shaikhiev, et al., “Ultrafiltration of oil-in-water emulsions with a dynamic nylon-polystyrene membrane,” Petrol. Chem. 58, 145–151 (2018).CrossRef
71.
A. B. Gilman and V. K. Potapov, “Plasmochemical modification of the surface of polymers,” Priklad. Fiz., Nos. 3–4, 18 (1995).
72.
L. I. Kravets, S. N. Dmitriev, and A. B. Gilman, “Modification of properties of polymer membranes by low-temperature plasma treatment,” High Energy Chem. 43, 227–234 (2009).CrossRef
73.
L. I. Kravets, A. B. Gilman, and G. Dinesku, “Low-temperature plasma for modification of properties of polymer membranes,” Ross. Khim. Zh. 57, 83–98 (2013).
74.
V. R. Mkrtychan and S. N. Zubakha, “Development of methods to enhance efficiency of separating membranes,” Zap. Gorn. Inst. 158, 66–68 (2004).
75.
I. Sadeghi, A. Aroujalian, A. Raisi, et al., “Surface modification of polyethersulfone ultrafiltration membranes by corona air plasma for separation of oil/water emulsions,” J. Membr. Sci. 430, 24–36 (2013).CrossRef
76.
I. G. Shaikhiev, V. O. Dryakhlov, M. F. Galikhanov, et al., “Separation of oil emulsion using polyacrylonitrile membranes, modified by corona discharge,” Inorg. Mater.: Appl. Res. 11, 1160–1164 (2020).CrossRef
77.
V. O. Dryakhlov, I. G. Shaikhiev, M. F. Galikhanov, et al., “Modification of polymeric membranes by corona discharge,” Membr. Membr. Technol. 2, 195–202 (2020).CrossRef
78.
V. P. Ivanov and V. A. Dronchenko, “Utilization of sewage waters with oil-containing wastes by emulsification and combustion, “Vestn. Belorusskoi Gos. Selskohoz. Akad., No. 4, 141–146 (2015).
79.
D. D. Fazullin, G. V. Mavrin, and I. G. Shaikhiev, “Investigation of the properties and composition of a concentrate of spent Inkam-1 emulsion as a corrosion inhibitor,” Petrol. Chem. 57, 728–733 (2017).CrossRef
80.
I. G. Shaikhiev, V. O. Dryakhlov, and D. D. Fazullin, “Membrane treatment of water containing spent cooling fluids,” Chernye Metally 1063, 46–50 (2020).
Metadaten
Titel
Membrane Purification of Depleted Emulsions by Polymer Membranes (Brief Literature Review)
verfasst von
V. O. Dryakhlov
I. G. Shaykhiev
T. R. Deberdeev
S. V. Sverguzova
Publikationsdatum
01.12.2022
Verlag
Pleiades Publishing
Erschienen in
Polymer Science, Series D / Ausgabe 4/2022
Print ISSN: 1995-4212
Elektronische ISSN: 1995-4220
DOI
https://doi.org/10.1134/S1995421222040074

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