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Separating iron, arsenic from crude tin by condensation鄄 centrifugal filtration. Yunnan Metall, 1982(2): 41 (柯金星. 凝析鄄鄄离心机过滤法脱除粗锡中的铁、砷. 云南冶 金, 1982(2): 41) [6] Ramshaw C, Mallinson R H. Mass Transfer Apparatus and Its Use: Eur Patent, 0002568. 1984鄄鄄6鄄鄄20 [7] El鄄Hadad S, Sato H, Miura鄄Fujiwara E, et al. Fabrication of Al鄄鄄 Al3 Ti / Ti3Al functionally graded materials under a centrifugal force. Materials, 2010, 3(9): 4639 [8] Watanabe Y, Hattori Y, Sato H. Distribution of microstructure and cooling rate in Al鄄鄄Al2Cu functionally graded materials fabrica鄄 ted by a centrifugal method. J Mater Process Technol, 2015, 221: 197 [9] Liu X B, Zhao Y G, Zhou D K, et al. Microstructure and wear re鄄 sistance of Mg2 Si / Al gradient composites fabricated by using cen鄄 trifugal casting. Foundry, 2015, 64(8): 747 (刘晓波, 赵宇光, 周德坤, 等. 离心铸造原位 Mg2 Si / Al 梯度 复合材料的组织和耐磨性. 铸造, 2015, 64(8): 747) [10] Watanabe K, Miyakawa O, Takada Y, et al. Casting behavior of titanium alloys in a centrifugal casting machine. Biomaterials, 2003, 24(10): 1737 [11] Chirita G, Soares D, Silva F S. Advantages of the centrifugal casting technique for the production of structural components with Al鄄鄄 Si alloys. Mater Des, 2008, 29(1): 20 [12] Liu K, Ma Y C, Gao M, et al. Single step centrifugal casting TiAl automotive valves. Intermetallics, 2005, 13(9): 925 [13] Liu Y, Chen C, L俟 W L. Study on friction and wear properties of high lead tin鄄bronze alloy by centrifugal casting. J Northeast Univ, 2016, 37(3): 338 (刘越, 陈超, 吕文玲. 离心铸造高铅锡青铜合金摩擦磨损 性能研究. 东北大学学报( 自然科学版), 2016, 37 (3 ): 338) [14] Miki Y, Kitaoka H, Sakuraya T, et al. Mechanism for separating inclusions from molten steel stirred with a rotating electro鄄magnet鄄 ic field. ISIJ Int, 1992, 32(1): 142 [15] Li J C, Guo Z C, Gao J T. Isothermal enriching perovskite phase from CaO鄄鄄TiO2 鄄鄄 SiO2 鄄鄄Al2O3 鄄鄄MgO melt by super gravity. ISIJ Int, 2014, 54(4): 743 [16] Li J C, Guo Z C. Innovative methodology to enrich britholite (Ca3Ce2 [(Si,P)O4 ]3 F) phase from rare鄄earth鄄rich slag by su鄄 per gravity. Metall Mater Trans B, 2014, 45(4): 1272 [17] Song G Y, Song B, Yang Y H, et al. Separating behavior of nonmetallic inclusions in molten aluminum under super鄄gravity field. Metall Mater Trans B, 2015, 46(5): 2190 [18] Yang Y H, Song B, Song G Y, et al. Enriching and separating primary copper impurity from Pb鄄3 mass pct Cu melt by super鄄 gravity technology. Metall Mater Trans B, 2016, 47(5): 2714 [19] Kumar K C H, Wollants P, Delaey L. Thermodynamic evaluation of Fe鄄鄄 Sn phase diagram. Calphad, 1996, 20(2): 139 [20] Watanabe Y, Inaguma Y, Sato H, et al. A novel fabrication method for functionally graded materials under centrifugal force: the centrifugal mixed鄄powder method. Materials, 2009, 2 (4 ): 2510 [21] McNown J S, Malaika J. Effects of particle shape on settling ve鄄 locity at low Reynolds numbers. Eos Trans AGU, 1950, 31(1): 74 [22] Zu L J, Luo S J, Sun J K. Effects of strain rate, liquid volume fraction and liquid viscosity on deformation force of semi鄄solid compression of metals. Chin J Nonferrous Met, 2000, 10( Suppl 1): 192 (祖丽君, 罗守靖, 孙家宽. 应变速率、液体体积分数和液体 黏度对金属半固态成形变形力的影响. 中国有色金属学报, 2000, 10(增刊 1): 192) [23] Zhao H, Shao L, Chen J F. High鄄gravity process intensification technology and application. Chem Eng J, 2010, 156(3): 588 ·50·