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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1092-1093Feasibility Study on Membrane Technology for Ship...

Feasibility Study on Membrane Technology for Ship Oil-Water Separation in China

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Abstract:

The case study of membrane technology applied in oily water treatment in petrochemical industry demonstrated that it is also technically feasible in ship oil-water separation in China. Based on the analysis of the membrane technological parameter selection, a practical ship oil-water separator has been designed, which consists of two-stage devices, a preliminary treatment device and a membrane filtration device for advanced treatment. The pore size and the hydrophilicity of the membrane should be decided by the influent oil content; the operating temperature could be the influent temperature; the TMP should be controlled at 0.1-0.2 MPa; the influent oil concentration and flux should be modified by the preliminary treatment device so they are appropriate for the membrane filtration device.

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Periodical:

Advanced Materials Research (Volumes 1092-1093)

Pages:

856-861

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1092-1093.856

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Online since:

March 2015

Authors:

Ou Chen Cai*, Jun Feng Chen, Wei Zhang

Keywords:

Feasibility, Membrane Technology, Oily Wastewater, Ship Oil-Water Separation

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© 2015 Trans Tech Publications Ltd. All Rights Reserved

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[1] G.Q. Liu, D. Wang, L.G. Wang and C.D. Gao: Membrane Science and Technology Vol. 27(1) (2007), pp.68-72. In Chinese.

[2] H.L. Wang, Y.C. Wang, J.S. Jiang, J.M. Yun and J.H. Wang: Membrane Science and Technology Vol. 18(2) (1998), pp.59-64. In Chinese.

[3] S.S. Fan and J.Q. Wang: Journal of Dalian University of Technology Vol. 40(1) (2000), pp.61-63. In Chinese.

[4] Y.H. Gu, X.H. Xue and K.W. Liu: Oil-Gas Field Surface Engineering Vol. 20(1) (2001), pp.18-19. In Chinese.

[5] L.X. Yi and J.G. Dong: Journal of Salt and Chemical Industry Vol. 42(2) (2013), pp.18-21. In Chinese.

[6] Y.Q. Pan, H.J. Li, T.H. Wang and L.Y. Ren: Journal of Chemical Engineering of Chinese Universities Vol. 18(1) (2004), pp.13-16. In Chinese.

[7] A.G. Lin and G. Liu: Engineering Plastics Application Vol. 34(3) (2006), pp.39-41. In Chinese.

[8] C.C. Hou, L. Huang and B.X. Huang: Technology of Water Treatment Vol. 39(6) (2013), pp.73-76. In Chinese.

[9] F.Y. Li, Y.C. Li, L. Sun and W.L. Wang: Technology of Water Treatment Vol. 21(3) (1995), pp.145-148. In Chinese.

[10] F.Y. Li, Y. Xu, Y.C. Li and L. Sun: Technology of Water Treatment Vol. 26(5) (2000), pp.285-288. In Chinese.

[11] J. Ge, J.Z. Ren and F.L. Yang: 3rd Conference on Membrane Separation Technology Application in Metallurgical Industry (2009), pp.69-73. In Chinese.

[12] Y.Q. Zhang, Y. Xu, F.L. Liu and G.D. Zhang: Chemical Industry and Engineering Progress Vol. 30(S2) (2011), pp.162-166. In Chinese.

[13] Z.M. Mao, Y.M. Cao, X.M. Jie, M. Li and Q. Yuan: Petrochemical Technology Vol. 39(7) (2010), pp.750-756. In Chinese.

[14] H.J. Li, Y.M. Cao, L.S. Yang and Q. Yuan: Chemical Journal of Chinese Universities Vol. 26(10) (2005), pp.1890-1895. In Chinese.

[15] J. Xu, S.L. Yu, C.P. Liang and X.H. Zhen: Industrial Water Treatment Vol. 26(5) (2006), pp.38-40. In Chinese.

[16] H.B. Li, X.M. Hu and Q. Luo: Journal of Filtration & Separation Vol. 10(4) (2000), pp.10-14. In Chinese.

[17] G.S. Zhang, H.P. Gu, W.H. Xing, N.P. Xu and J. Shi: Journal of Chemical Engineering of Chinese Universities Vol. 12(3) (1998), pp.288-292. In Chinese.

[18] X. Wang, L.Y. Chu, W.M. Chen, X.C. Xiao and G.J. Wang: Oilfield Chemistry Vol. 20(4) p. (2003), 387-390. In Chinese.

[19] H.Y. Yang, Z.Q. Wang and J. Leng: Ship & Ocean Engineering Vol. 39(6) (2010), pp.17-19. In Chinese.