Nanofiltration performance and mass transfer characteristics of PDMS/PVDF composite membranes filled with white carbon black

doi:10.11949/j.issn.0438-1157.20141691

CIESC Journal ›› 2015, Vol. 66 ›› Issue (7): 2555-2564.DOI: 10.11949/j.issn.0438-1157.20141691

Previous Articles Next Articles

Nanofiltration performance and mass transfer characteristics of PDMS/PVDF composite membranes filled with white carbon black

CAI Weibin, XIA Yang, WANG Yujun, LI Jiding, ZHU Shenlin

State Key Laboratory of Chemical Engineering, Department of Chemical Engineering, Tsinghua University, Beijing 100084, China

Received:2014-11-12 Revised:2015-04-02 Online:2015-07-05 Published:2015-07-05
Supported by:
supported by the National Natural Science Foundation of China (21176135), the Science Foundation of Tsinghua University (20131089399) and the Special Funds for Technological Development Research of Research Institutes from National Ministry of Science and Technology (2013EG111129).

白炭黑填充PDMS/PVDF复合膜的纳滤分离性能及传质特性

蔡卫滨, 夏阳, 王玉军, 李继定, 朱慎林

清华大学化学工程系, 化学工程联合国家重点实验室, 北京 100084

通讯作者: 李继定
基金资助:
国家自然科学基金项目(21176135);清华大学科学基金项目(20131089399);国家科技部科研院所技术开发研究专项资金项目(2013EG111129)。

Abstract

Abstract:

Nano white carbon black particles filled PDMS/PVDF composite membranes were prepared, and FT-IR, TGA and contact angle were used to characterize the physical and chemical characteristics of the composite membranes. By using soybean/hexane miscellas, the separation performance of the composite membranes was systematically investigated. The results indicated that by filling white carbon black to PDMS, the crosslinking density was promoted, and the hydrophobicity, thermal stability and solvent resistance were improved. The permeate flux was declined with increasing filling content of white carbon black, while the oil retention was risen from 96% to 98%. With the increase of oil concentration, both of the permeate flux and oil retention were declined. With increasing feed temperature, the permeate flux was risen while the oil retention was declined. Mass transfer characteristics of soybean oil and hexane through the membrane can be described by the solution-diffusion with imperfections model, and the experimental values of the micelle osmotic pressure were well in accordance with calculated values.

Key words: nanofiltration, membrane, mass transfer, solvent recovery, white carbon black, PDMS

摘要：

将纳米级白炭黑填充于PDMS制备了白炭黑填充PDMS/PVDF复合膜,采用红外(FT-IR)、热失重(TGA)和接触角(CA)等方法对填充复合膜进行了分析和表征,并采用纳滤的方法系统研究了复合膜对大豆油/己烷混合油的分离性能。结果表明,白炭黑填充能有效促进PDMS的交联,提高PDMS的疏水性、热失重温度以及对溶剂的稳定性;白炭黑填充量增加使复合膜渗透通量降低,但截留率从96%提高到98%;随溶液浓度增加,渗透通量和截留率同时降低;随温度的升高,渗透通量上升,截留率降低。大豆油和己烷在膜中的传质特性可用不完全的溶解-扩散模型描述,溶液渗透压实验值与计算值符合较好。

关键词: 纳滤, 膜, 传质, 溶剂回收, 白炭黑, PDMS

CLC Number:

TQ028.8

CAI Weibin, XIA Yang, WANG Yujun, LI Jiding, ZHU Shenlin. Nanofiltration performance and mass transfer characteristics of PDMS/PVDF composite membranes filled with white carbon black[J]. CIESC Journal, 2015, 66(7): 2555-2564.

蔡卫滨, 夏阳, 王玉军, 李继定, 朱慎林. 白炭黑填充PDMS/PVDF复合膜的纳滤分离性能及传质特性[J]. 化工学报, 2015, 66(7): 2555-2564.

References 20

[1]	Liu Mo'e (刘茉娥). Membrane Separation Technology (膜分离技术) [M]. Beijing: Chemical Industry Press, 2000: 1-5.
[2]	Ge Yiqiang (葛毅强), Sun Aidong (孙爱东), Cai Tongyi (蔡同一). Modern membrane technology and its application in the food industry [J]. Food and Fermentation Industries (食品与发酵工业), 1999, 24 (2): 57-61.
[3]	Koseoglu S S, Engelgau D E. Membrane applications and research in the edible oil industry: an assessment [J]. J. Am. Oil Chem. Soc., 1990, 67 (4): 239-249.
[4]	Mou Zhaoli (牟朝丽), Chen Jinping (陈锦屏). Membrane separation technology and application in oil industry [J]. Cereals & Oils (粮食与油脂), 2005, 3: 10-12.
[5]	Ana P B R, Juliana M L N, Lireny A G. Solvent recovery from soybean oil/hexane miscella by polymeric membranes [J]. J. Membr. Sci., 2006, 282: 328-336.
[6]	Liu Haixia (刘海霞), Zhu Juhua (朱菊华), Zhao Junting (赵俊廷), Li Dongguang (李冬光). The application of membrane separation technology in edible oil degumming and solvent recovery [J]. Cereals and Oil Processing (油脂工程), 2007, 9: 78-81.
[7]	Wu C S, Lee E. Ultrafiltration of soybean oil/hexane extracted by porous ceramic membranes [J]. J. Membr. Sci., 1999, 154: 251-259.
[8]	Koseoglu S S, Lawhon J T, Lusas E W. Membrane processing of crude vegetable oil: pilot plant scale removal of solvent from oil miscellas [J]. JAOCS, 1990, 67 (5): 315-322.
[9]	Fireman L R, Ochoa N A, Marchese J, Pagliero C L. Deacidification and solvent recovery of soybean oil by nanofiltration membranes [J]. J. Membr. Sci., 2013, 431: 187-196.
[10]	Cai Weibin, Sun Yanzhi, Piao Xianglan, Li Jiding, Zhu Shenlin. Solvent recovery from soybean oil/hexane miscella by PDMS composite membrane [J]. Chinese Journal of Chemical Engineering, 2011, 19 (4): 575-580.
[11]	Cai Weibin (蔡卫滨), Piao Xianglan (朴香兰), Li Jiding (李继定), Zhu Shenlin (朱慎林). Solvent recovery performance of PDMS/PVDF composite nanofiltration membranes cured with different cross-linking reagents [J]. CIESC Journal (化工学报), 2013, 64 (2): 581-589.
[12]	Stafie N, Stamatialis D F, Wessling M. Insight into the transport of hexane-solute systems through tailor-made composite membranes [J]. J. Membr. Sci., 2004, 228: 103-116.
[13]	Stafie N, Stamatialis D F, Wessling M. Effect of PDMS cross-linking degree on the permeation performance of PAN/PAMS composite nanofiltration membranes [J]. Sep. Purif. Technol., 2005, 45: 220-231.
[14]	Xing Songmin (幸松民), Wang Yilu (王一璐). Synthesis Technology and Application of Organic Silicon (有机硅合成工艺及产品应用)[M]. Beijing: Chemical Industry Press, 2000: 346.
[15]	Li L, Xiao Z, Tan S. Composite PDMS membrane with high flux for the separation of organics from water by pervaporation [J]. J. Membr. Sci., 2004, 243 (1/2): 177-187.
[16]	Kulkarni S A, Ogale S B, Vijayamohanan K P. Tuning the hydrophobic properties of silica particles by surface silanization using mixed self-assembled monolayers [J]. Journal of Colloid and Interface Science, 2008, 318 (2): 372-379.
[17]	Wijmans J G, Baker R W. The solution-diffusion model: a review [J]. J. Membr. Sci., 1995, 107: 1-21.
[18]	Scarpello J T, Nair D, Freitas dos S L M, et al. The separation of homogeneous organometallic catalysts using solvent resistant nanofiltration [J]. J. Membr. Sci., 2002, 203: 71-85.
[19]	Sherwood T, Brian P, Fisher R. Desalination by reverse osmosis [J]. Ind. Eng. Chem. Fundam., 1967, 6: 2-12.
[20]	Sun Benhui (孙本惠). The measure and calculation of solubility parameters [J]. Special Purpose Rubber Products (特种橡胶制品), 1983, 4: 47-59.

Nanofiltration performance and mass transfer characteristics of PDMS/PVDF composite membranes filled with white carbon black

白炭黑填充PDMS/PVDF复合膜的纳滤分离性能及传质特性

PDF (PC)

Knowledge

Cited

Abstract

Cite this article

share this article

References 20

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Jingwei CHAO, Jiaxing XU, Tingxian LI. Investigation on the heating performance of the tube-free-evaporation based sorption thermal battery [J]. CIESC Journal, 2023, 74(S1): 302-310.
[2]	Yanpeng WU, Xiaoyu LI, Qiaoyang ZHONG. Experimental analysis on filtration performance of electrospun nanofibers with amphiphobic membrane of oily fine particles [J]. CIESC Journal, 2023, 74(S1): 259-264.
[3]	Yitong LI, Hang GUO, Hao CHEN, Fang YE. Study on operating conditions of proton exchange membrane fuel cells with non-uniform catalyst distributions [J]. CIESC Journal, 2023, 74(9): 3831-3840.
[4]	Jiayi ZHANG, Jiali HE, Jiangpeng XIE, Jian WANG, Yu ZHAO, Dongqiang ZHANG. Research progress of pervaporation technology for N-methylpyrrolidone recovery in lithium battery production [J]. CIESC Journal, 2023, 74(8): 3203-3215.
[5]	Yali HU, Junyong HU, Suxia MA, Yukun SUN, Xueyi TAN, Jiaxin HUANG, Fengyuan YANG. Development of novel working fluid and study on electrochemical characteristics of reverse electrodialysis heat engine [J]. CIESC Journal, 2023, 74(8): 3513-3521.
[6]	Zhaoguang CHEN, Yuxiang JIA, Meng WANG. Modeling neutralization dialysis desalination driven by low concentration waste acid and its validation [J]. CIESC Journal, 2023, 74(6): 2486-2494.
[7]	Yuanyuan ZHANG, Jiangyuan QU, Xinxin SU, Jing YANG, Kai ZHANG. Gas-liquid mass transfer and reaction characteristics of SNCR denitration in CFB coal-fired unit [J]. CIESC Journal, 2023, 74(6): 2404-2415.
[8]	Kuikui HAN, Xianglong TAN, Jinzhi LI, Ting YANG, Chun ZHANG, Yongfen ZHANG, Hongquan LIU, Zhongwei YU, Xuehong GU. Four-channel hollow fiber MFI zeolite membrane for the separation of xylene isomers [J]. CIESC Journal, 2023, 74(6): 2468-2476.
[9]	Lei WANG, Lei WANG, Yunlong BAI, Liuliu HE. Preparation of SA lithium ion sieve membrane and its adsorptive properties [J]. CIESC Journal, 2023, 74(5): 2046-2056.
[10]	Hao GU, Fujian ZHANG, Zhen LIU, Wenxuan ZHOU, Peng ZHANG, Zhongqiang ZHANG. Desalination performance and mechanism of porous graphene membrane in temporal dimension under mechanical-electrical coupling [J]. CIESC Journal, 2023, 74(5): 2067-2074.
[11]	Yongyao SUN, Qiuying GAO, Wenguang ZENG, Jiaming WANG, Yifei CHEN, Yongzhe ZHOU, Gaohong HE, Xuehua RUAN. Design and optimization of membrane-based integration process for advanced utilization of associated gases in N₂-EOR oilfields [J]. CIESC Journal, 2023, 74(5): 2034-2045.
[12]	Chenxin LI, Yanqiu PAN, Liu HE, Yabin NIU, Lu YU. Carbon membrane model based on carbon microcrystal structure and its gas separation simulation [J]. CIESC Journal, 2023, 74(5): 2057-2066.
[13]	Hao WANG, Siyang TANG, Shan ZHONG, Bin LIANG. An investigation of the enhancing effect of solid particle surface on the CO₂ desorption behavior in chemical sorption process with MEA solution [J]. CIESC Journal, 2023, 74(4): 1539-1548.
[14]	Rong WANG, Yonghong WANG, Xinru ZHANG, Jinping LI. Construction of 6FDA-based polyimide carbon molecular sieve membranes for gas separation and its application [J]. CIESC Journal, 2023, 74(4): 1433-1445.
[15]	Yangguang LYU, Peipei ZUO, Zhengjin YANG, Tongwen XU. Triazine framework polymer membranes for methanol/n-hexane separation via organic solvent nanofiltration [J]. CIESC Journal, 2023, 74(4): 1598-1606.