基于RTIPS-NIPS法制备含辣素衍生结构防污超滤膜及其性能研究 |
作者:单超越,张丽丽,唐媛媛,王言建,徐丽,于良民 |
单位: 1 中国海洋大学 海洋化学理论与工程技术教育部重点实验室,青岛 266100;2 中国海洋大学海洋高等研究院,青岛 266100 |
关键词: 反相热诱导相分离法;非溶剂诱导相分离法;辣素衍生物;超滤膜;防污 |
DOI号: |
分类号: TQ326.55 |
出版年,卷(期):页码: 2020,40(3):37-46 |
摘要: |
研究采用原位聚合法,将含辣素衍生结构功能单体N-(2-羟基-3-甲基-6(甲硫基)苄基)丙烯酰胺(HMMBA)通过物理共混引入铸膜液中,并通过反相热诱导相分离法与非溶剂诱导相分离法联用(RTIPS-NIPS)进行高通量防污超滤膜的制备。系统考察了HMMBA含量对膜的结构形态、亲水性、分离性能和抑菌性能等的影响。结果表明,当HMMBA添加量达到2 wt%时,超滤膜的接触角由PSf膜的85°降低至62o;机械强度由29.46 N增加至31.71 N;以5 mg/L的腐殖酸为料液进行过滤实验时,改性超滤膜的稳定通量为420 L/(m2h),与未改性PSf膜[200 L/(m2h)]相比提高了110%;抑菌率达到了97%以上,且通量恢复率由67.59%提升至86.34%。因此,采用RTIPS-NIPS联用将HMMBA应用在超滤膜中可以既可以提高膜的亲水性、机械性能和分离性能,同时还能够有效抑制膜污染的产生。 |
The high flux antifouling PSf ultrafiltration membranes was prepared via the combination of Reversed thermally induced phase separation and Non-solvent induced phase separation process and N- [2-hydroxy-3-methyl-6 (methanyl) benzyl] acrylamide (HMMBA) was incorporated into the membranes by “in-situ polymerization-blending” method. The effect of HMMBA content on the membrane structure, hydrophilicity, separation performance and antifouling properties was systematically investigated in the work. The results showed that, compared with the pure PSf membrane, when the HMMBA reached 2 wt%, the contact Angle of the ultrafiltration membrane decreased from 85° to 62°; mechanical strength increased from 29.46 N to 31.71 N; the stable flux of the modified ultrafiltration membrane was 418.5 L/(m2h), 110% higher than that of the unmodified PSf membrane [201.3 L/(m2h)]. In addition, the inhibition rate was above 97%, and the flux recovery rate increased from 67.59% to 86.34%. Therefore, the application of HMMBA in ultrafiltration membrane with RTIPS-NIPS can not only improve the hydrophilicity, mechanical properties and separation properties of the membrane, but also effectively achieve a good effect in inhibiting the generation of membrane pollution. |
基金项目: |
国家自然科学基金-山东联合基金(批准号:U1706225)和山东省重点研发计划(批准号:2018JMRH0504) |
作者简介: |
作者简介:单超越,1994年,女,山东威海,硕士,主要从事含辣素衍生结构超滤膜改性研究。E-mail:1097517393@qq.com |
参考文献: |
[1] Imbrogno, Joseph, Williams, Matthew D, Belfort, Georges. A New Combinatorial Method for Synthesizing, Screening, and Discovering Antifouling Surface Chemistries[J]. Acs Appl Mater Interfaces, 2015, 7(4):2385-2392. [2] Yang L J, Tang B B, Wu P Y. UF membrane with highly improved flux by hydrophilic network between graphene oxide and brominated poly(2,6-dimethyl-1,4-phenylene oxide)[J]. Mater. Chem, 2014,2(43):18562-18573. [3] Jeong F Kim, Jihoon Kim, Young Moo Lee, et al. Thermally induced phase separation andelectrospinning methods for emerging membrane applications: a review[J]. AlChE J, 2016, 62(2): 461-490. [4] 许振良, 蒋福四, 魏永明, 等. 低临界共溶温度PSf-DMAc-PEG体系微孔膜及其性能表征[J].膜科学与技术, 2013(03):39-45. [5] Hamid Rajabi, Negin Ghaemi, Sayed S. Madaeni, et al. Nano-ZnO embedded mixed matrixpolyethersulfone (PES) membrane: Influence of nanofiller shape on characterization and fouling resistance[J]. Appl Surf Sci, 2015, 349: 66-77. [6] Liu M, Wei Y M, Xu Z L, et al. Preparation and characterization of polyethersulfone microporous membrane via thermally induced phase separation with low critical solutio-n temperature system[J]. J Membr Sci, 2013, 437(38):169-178. [7] Yu L Y, Shen H M, Xu Z L. PVDF-TiO2 composite hollow fiber ultrafiltration membranes prepared by TiO2 sol-gel method and blending method[J]. Appl Polym Sci, 2009, 113(3):1763-1772. [8] Jang Hanna, Song Du Hyun, Lee Hye Jin, et al. Preparation of dual-layer acetylated methyl cellulose hollow fiber membranes via co-extrusion using thermally induced phase separation and non-solvent induced phase separation methods[J]. J. Appl Polym Sci, 2015, 132(43). [9] Liu S H, Liu M, Xu Z L, et al. A novel PES-TiO2 hollow fiber hybrid membrane prepared via sol-gel process assisted reverse thermally induced phase separation (RTIPS) method[J]. J Membr Sci, 528:303-315. [10] Jang Hanna, Song Du Hyun, Lee Hye Jin, et al. Preparation of dual-layer acetylated methyl cellulose hollow fiber membranes via co-extrusion using thermally induced phase separation and non-solvent induced phase separation methods[J]. Polym. J, 2015, 132(43). [11] 王勇, 王鸿儒. 聚砜类分离膜材料及其改性研究进展[J]. 塑料工业, 2012(01):12-15. [12] Chen Ming Huang, Chiao Tza Chiang, Tseng Tsai Wie. Preparation of sulfonated polysulfone/polysulfone and aminated polysulfone/polysulfone blend membranes [J]. J Appl Polym Sci, 1996, 61(7): 1205-1209. [13] Takashi Hasegawa, Yasuhiko Iwasaki, Kazuhiko Ishihara. Preparation and performance of protein-adsorption-resistant asymmetric porous membrane composed of polysulfone/phospholipid polymer blend[J]. Biomaterials, 22(3):243-251. [14] Yanlei Su, Chao Li, Wei Zhao, et al. Modification of polyethersulfone ultrafiltration membranes with phosphorylcholine copolymer can remarkably improve the antifouling and permeation properties[J]. J Membr Sci, 322(1):171-177. [15] Sinha, M.K, Purkait, M.K. Preparation and characterization of stimuli-responsive hydrophilic polysulfone membrane modified with poly (N-vinylcaprolactam-co-acrylic acid)[J]. Desalination, 348:16-25. [16] Kwang-Ho Choo, Chung-Hak Lee. Membrane Fouling Mechanisms in the Membrane-Coupled Anaerobic Bioreactor[J]. Water Res, 1996, 30(8):1771-1780. [17] Fischer K J. Marine organism repellent covering for protection of underwater objects and method of applying same [P], U.S. Patent, 5226380. 1993-7-13. [18] 徐焕志, 于良民, 李昌诚, 等. 辣素衍生物的合成及其对新月菱形藻生长的抑制活性[J]. 应用化学, 2007(08):65-70. [19] 张晓春, 于良民, 姜晓辉. 含辣素衍生结构单体及其聚合物的合成、抑菌与抑藻性能[J]. 材料导报, 2018, 32(1):194-202. [20] 王璇, 姜晓辉, 于良民, 等. 具类辣素结构乙酰胺的合成及其抑菌、抑藻性能[J]. 精细化工, 36(03):179-185. [21] Zhang L L, Shan C Y, Jiang X H, High hydrophilic antifouling membrane modified with capsaicin-mimic moieties via microwave assistance (MWA) for efficient water purification[J]. Chem Eng J, 2018, 338, 688-699. [22] 黄星. 共混改性制备抗菌性耐污染聚醚砜超滤膜的研究[D]. 青岛: 中国海洋大学, 2014. |
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