Filtration mechanism of membranes in combination of catalytic wet air oxidation and membrane filtration

doi:10.3969/j.issn.0438-1157.2013.05.020

CIESC Journal ›› 2013, Vol. 64 ›› Issue (5): 1642-1650.DOI: 10.3969/j.issn.0438-1157.2013.05.020

Previous Articles Next Articles

Filtration mechanism of membranes in combination of catalytic wet air oxidation and membrane filtration

LI Xiaoyi, WU Sijun, SUN Dezhi

Beijing Key Laboratory for Source Control Technology of Water Pollution, Beijing Forestry University, Beijing 100083, China

Received:2012-07-30 Revised:2012-09-04 Online:2013-05-05 Published:2013-05-05
Supported by:
supported by the National Natural Science Foundation of China(50978029).

湿式催化氧化/膜过滤组合工艺膜过滤机理

李晓祎, 吴嗣骏, 孙德智

北京林业大学水体污染源控制技术北京市重点实验室, 北京 100083

通讯作者: 孙德智
作者简介:李晓祎(1988-),女,硕士研究生。
基金资助:
国家自然科学基金项目(50978029)。

Abstract

Abstract: The treatment of simulated cationic red GTL dye wastewater was conducted by coupling technology of catalytic wet air oxidation(CWAO)with membrane filtration, using Mo-Zn-Al-O as catalyst.The filtration mechanism of polyvinylidene fluoride hollow fiber microfiltration(MF)membranes with average pore size 0.1 μm and ultrafiltration(UF)membranes with average pore size 0.022 μm was investigated.It was found that the degradation efficiency of hybrid system was superior to CWAO with single process.Under 0.01 MPa pressure for 120 min the fluxes of MF and UF declined 26.63% and 16.48%, respectively.The reason for flux decline of microfiltration membrane was considered to be the blocking of pores and the formation of cake layer on the membrane surface by deposited catalyst powder, while that of ultrafiltration was dominated by cake layer formation.The experimental results showed that the irreversible resistance in microfiltration was larger than that in ultrafiltration after the same process.Under different operation conditions, a linear relationship could be obtained between the filtration resistance and specific deposit.

Key words: catalytic wet air oxidation, membrane filtration, powder catalyst, microfiltration, ultrafiltration

摘要： 采用湿式催化氧化/膜过滤组合工艺,以Mo-Zn-Al-O粉末作为催化剂降解阳离子红GTL模拟染料废水,探讨在膜过滤过程中平均孔径为0.1 μm的微滤和0.022 μm的超滤聚偏氟乙烯(PVDF)中空纤维膜的过滤机理。实验结果表明,两种膜过滤组合工艺对染料的降解效果均优于单独湿式催化氧化,0.01 MPa恒压条件下运行120 min后微滤和超滤的膜通量分别衰减了26.63%和16.48%,其原因是粉末催化剂可在微滤膜孔内部沉积形成中间阻塞过滤,后在表面形成滤饼层;而在超滤膜表面仅形成滤饼层。通过实验结果对膜阻力进行计算,可知在相同反应过程后微滤膜产生的不可逆阻力大于超滤膜。在不同反应条件下,催化剂的沉积量与膜阻力呈现线性相关。

关键词: 湿式催化氧化, 膜过滤, 粉末催化剂, 微滤, 超滤

CLC Number:

X505

LI Xiaoyi, WU Sijun, SUN Dezhi. Filtration mechanism of membranes in combination of catalytic wet air oxidation and membrane filtration[J]. CIESC Journal, 2013, 64(5): 1642-1650.

李晓祎, 吴嗣骏, 孙德智. 湿式催化氧化/膜过滤组合工艺膜过滤机理[J]. 化工学报, 2013, 64(5): 1642-1650.

References 18

[1]	Ma H, Zhuo Q, Wang B.Characteristics of CuO-MoO3-P2O5 catalyst and its catalytic wet oxidation(CWO)of dye wastewater under extremely mild conditions[J].Environmental Science and Technology, 2007, 41:7491-7496
[2]	Liu Yan(刘琰), Sun Dezhi(孙德智).Preparation and activity of Fe2O3-CeO2 /γ-Al2O3 catalyst for catalytic wet peroxide oxidation of dye wastewater[J].Journal of Chemical Industry and Engineering(China)(化工学报), 2006,57(10):2303-2308
[3]	Li W, Zhao S, Qi B, et al.Fast catalytic degradation of organic dye with air and MoO3:Ce nanofibers under room condition[J].Applied Catalysis B:Environmental,2009, 92:333-340
[4]	Yuan M, Wang S, Wang X, et al.Removal of organic dye by air and macroporous ZnO/MoO3/SiO2 hybrid under room conditions[J].Applied Surface Science, 2011, 257:7913-7919
[5]	Wu J M, Wen W.Catalyzed degradation of azo dyes under ambient conditions[J].Environmental Science and Technology, 2010, 44:9123-9127
[6]	Xu Yin(许银), Sun Dezhi(孙德智).Preparation and activity of Mn-Zn-Al-O catalyst for catalytic wet air oxidation under room conditions[J].CIESC Journal(化工学报), 2012,63:1415-1421
[7]	Hua B, Jiang A, Guo L, et al.Photocatalytic membrane reactor for degradation of acid red B wastewater[J].Chemical Engineering Journal, 2010, 156:571-577
[8]	Joanna G D, Sylwia M, Antoni W Morawski.Integration of photocatalysis with membrane processes for purification of water contaminated with organic dyes[J].Catalysis Today, 2010, 156:295-300
[9]	Rahul A Damodara, et al.Coupling of membrane separation with photocatalytic slurry reactor for advanced dye wastewater treatment[J].Separation and Purification Technology, 2010, 76:64-71
[10]	Mozia S.Photocatalytic membrane reactors(PMRs)in water and wastewater treatment:a review[J].Separation and Purification Technology, 2010, 73:71-91
[11]	Chong M N, Jin B,Chow C W K, Saint C.Recent developments in photocatalytic water treatment technology:a review[J].Water Research, 2010, 44:2997-3027
[12]	Xu Y, Li X Y, Sun D Z, et al.Degradation of cationic red GTL by catalytic wet air oxidation over Mo-Zn-Al-O catalyst under room temperature and atmospheric pressure[J].Environmental Science and Technology, 2012, 46:2856-2863
[13]	Jawor A, Hoek E M V.Removing cadmium ions from water via nanoparticle enhanced ultrafiltration[J].Environmental Science and Technology, 2010, 44:2570-2576
[14]	Psoch C, Schiewer S.Resistance analysis for enhanced wastewater membrane filtration[J].Journal of Membrane Science, 2006, 280:284-297
[15]	Zhang Guoliang, Zhang Jiwei, Wang Ling, Meng Qin, et al. Fouling mechanism of low-pressure hollow fiber membranes used in separating nanosized photocatalysts[J].Journal of Membrane Science, 2012, 389:532-543
[16]	Zhong Z, Xing W, Jin W, Xu N.Adhesion of nanosized nickel catalysts in the nanocatalysis/UF system[J].AIChE Journal, 2007, 53:1204-1210
[17]	Luo M L, Zhao J Q, Tang W,Pu C S.Hydrophilic modification of poly(ether sulfone)ultrafiltration membrane surface by self-assembly of TiO2 nanoparticles[J].Applied Surface Science, 2005,249:76-84
[18]	Xi W,Geissen S U.Separation of titanium dioxide from photocatalytically treated water by cross-flow microfiltration[J].Water Research,2001,35:1256-1262

Filtration mechanism of membranes in combination of catalytic wet air oxidation and membrane filtration

湿式催化氧化/膜过滤组合工艺膜过滤机理

PDF (PC)

Knowledge

Cited

Abstract

Cite this article

share this article

References 18

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Min SUN, Hui JIA, Qingwen QIN, Qi WANG, Zinan GUO, Yanru LUO, Jie WANG. In-situ online monitoring of ultrafiltration membrane fouling based on electrical impedance tomography [J]. CIESC Journal, 2022, 73(4): 1754-1762.
[2]	Lanhe ZHANG, Lu WANG, Zimeng LI, Hong TANG, Jingbo GUO, Yanping JIA, Mingshuang ZHANG. The treatment of anionic surfactant wastewater using electrode ultrafiltration membrane bioreactor [J]. CIESC Journal, 2022, 73(10): 4679-4691.
[3]	WANG Kaizhen, WANG Shuhao, LI Yunhao, ZHOU Yong, GAO Congjie. Preparation and performance of high-flux polysulfone ultrafiltration membrane by in-situ synthesis [J]. CIESC Journal, 2021, 72(3): 1712-1721.
[4]	Wenguang WANG, Ming TAN, Xiaohan SUN, Xingtao YANG, Xiaodong ZHANG, Yang ZHANG, Hongwu ZHAO. Ultrafiltration membrane cleaning technology and mechanism based on seawater desalination pilot equipment [J]. CIESC Journal, 2020, 71(S2): 289-296.
[5]	Yuanyuan CAI,Baitao GUO,Weihong XING,Congjie GAO. Progress research on development of membrane technology and materials for health industry [J]. CIESC Journal, 2020, 71(7): 2921-2932.
[6]	Xuehui ZHAO, Xiaole LI, Yang LIU, Yan HU, Qing XU, Hongwei ZHANG. Effect of pH control of KMnO₄ solution on physicochemical properties and fouling behavior of PVDF membrane [J]. CIESC Journal, 2020, 71(5): 2401-2412.
[7]	Ailian XUE, Shouyong ZHOU, Jianjian CAI, Meisheng LI, Yan ZHANG, Yijiang ZHAO. Preparation and properties of temperature-responsive PVDF/PGS-g-PNIPAM nanocomposite ultrafiltration membrane [J]. CIESC Journal, 2020, 71(3): 1380-1389.
[8]	YANG Jihao,GENG Lili,YE Songshou,XIE Jianrong,ZHANG Nuowei,CHEN Binghui. Stable and efficient Ru/TiO₂-ZrO₂ catalysts for catalytic wet air oxidation of phenolsulfonic acid wastewater treatment [J]. CIESC Journal, 2020, 71(12): 5561-5567.
[9]	Hao XU, Kaifeng GU, Yunhao LI, Yong ZHOU, Congjie GAO. Polyethersulfone ultrafiltration membrane with low molecular weight cut off [J]. CIESC Journal, 2019, 70(5): 1999-2006.
[10]	Songze HAO, Hongwei ZHANG, Yun WU, Jie WANG. Study on treatment of biological catalytic filter and membrane fouling with bimetallic catalyst as filter media [J]. CIESC Journal, 2019, 70(11): 4377-4386.
[11]	GENG Lili, YANG Kaixu, ZHANG Nuowei, CHEN Binghui. Synergetic effect of Ru and Cu on catalytic wet oxidation of ammonia-wastewater [J]. CIESC Journal, 2018, 69(9): 3869-3878.
[12]	LIU Lei, REN Jiwei, LIU Xinlu, ZHENG Zhaojuan, LI Xin, OUYANG Jia. Study of simultaneous separation of lignosulfonate and xylooligosaccharides from magnesium bisulfite pretreated wheat straw spent liquor [J]. CIESC Journal, 2018, 69(8): 3678-3685.
[13]	SUN Xuefei, GAO Yongqiang, ZHAO Song, ZHANG Wen, WANG Zhi, WANG Xiaolin. Ultrafiltration membrane with antibacterial and antifouling properties by grafting guanidine based polymer [J]. CIESC Journal, 2018, 69(11): 4869-4878.
[14]	ZHANG Rui, LI Min, ZHOU Tianxu, PENG Hongwei, GUO Xuhong. Treatment of printing and dyeing wastewater with novel temperature-responsive ultrafiltration membrane [J]. CIESC Journal, 2018, 69(11): 4910-4917.
[15]	CHEN Yishan, CAI Yifeng, ZHANG Ming, XUE Fan, GU Tianyu, CHEN Xianfu, QIU Minghui, FAN Yiqun. Application of porous ceramic membranes for separation and purification of carbon quantum dots [J]. CIESC Journal, 2018, 69(10): 4284-4291.