1. 毕业设计（论文）的内容和要求

卷式膜组件以其自身独特的优势广泛应用于微滤、纳滤、超滤、反渗透等过程，对于卷式膜组件而言，在膜分离过程中隔网能够增强传质、支撑流道、提供机械支撑等优势。

但是同时会使得压降增加，从而增加能耗。

而隔网的构型是膜分离过程的重要影响因素，本课题针对一定高度的不同入水角度的隔网构型的cfd模型进行实验验证，最终优化最优的入水角度。

2. 参考文献

[1] Tomatis, M., et al., Recent Development of Catalysts for Removal of Volatile Organic Compounds in Flue Gas by Combustion: A Review. Journal of Chemistry, 2016. 2016: p. 1-15. [2] Menon, U., et al., Nature of the active sites for the total oxidation of toluene by CuOCeO2/Al2O3. Journal of Catalysis, 2012. 295: p. 91-103. [3] Kim, S.C. and W.G. Shim, Catalytic combustion of VOCs over a series of manganese oxide catalysts. Applied Catalysis B: Environmental, 2010. 98(3-4): p. 180-185. [4] Rui, Z., et al., Anodic Alumina Supported Pt Catalyst for Total Oxidation of Trace Toluene. Chinese Journal of Chemical Engineering, 2014. 22(8): p. 882-887. [5] Carrillo, A.M. and J.G. Carriazo, Cu and Co oxides supported on halloysite for the total oxidation of toluene. Applied Catalysis B: Environmental, 2015. 164: p. 443-452. [6] Lai, Y.T., et al., Pt/SBA-15 as a Highly Efficient Catalyst for Catalytic Toluene Oxidation. ACS Catalysis, 2014. 4(11): p. 3824-3836. [7] Zhang, Q., et al., Study on Pt-structured anodic alumina catalysts for catalytic combustion of toluene: Effects of competitive adsorbents and competitive impregnation methods. Applied Surface Science, 2016. 360: p. 1066-1074. [8] Zuo, S., et al., Rare Earth-Modified Kaolin/NaY-Supported Pd#8211;Pt Bimetallic Catalyst for the Catalytic Combustion of Benzene. ACS Applied Materials Interfaces, 2014. 6(15): p. 11988-11996. [9] He, C., et al., Anionic starch-induced Cu-based composite with flake-like mesostructure for gas-phase propanal efficient removal. Journal of Colloid and Interface Science, 2015. 454: p. 216-225. [10] Rapagn#224;, S., et al., First Al2O3 based catalytic filter candles operating in the fluidized bed gasifier freeboard. Fuel, 2012. 97: p. 718-724. [11] Ren, Y., et al., Removal of gaseous HxCBz by gliding arc plasma in combination with a catalyst. Chemosphere, 2014. 117: p. 730-736.

3. 毕业设计（论文）进程安排

2016.12.1-2017.1.10 熟悉课题、文献检索及阅读,英文文献翻译 2017.2.20-2017.3.3 熟悉实验操作，开题报告 2017.3-2017.5 完成实验 2017.6 整理数据，撰写论文