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Treatment and Reuse of Process Water with High Suspended Solids in Low￾grade Iron Ore dressing. J Cleaner Prod, 2020, 278(8): 123493 [9] Xu S, Zhou X L, Liu X C, et al. Development process, classification and research status of high efficiency improvement of thickener. Metal Mine, 2021(05): 167 (徐帅, 周兴龙, 刘肖楚, 等. 浓密机发展历程、分类及其高效化改进研究现状. 金属矿山, 2021(05): 167) [10] Yang B D, Xie J Y, Li P. Study on Mechanism of high efficiency thickener . Nonfer metals , 2011 (05): 38 (杨保东, 谢纪元, 李鹏. 高效浓密机机理研究. 有色金属, 2011(05): 38) [11] Chen Q L, Li C J, Yang Y. Analysis on technical characteristics of φ53m center drive automatic rake lifting high efficiency thickener. Mod Min, 2009, 25(06): 130 (陈庆来, 李从军, 杨勇. φ53m 中心传动自动提耙高效浓缩机技术特点分析. 现代矿业, 2009, 25(06): 130) [12] Xie D D, Tong X, Xie X, et al. Application status and research progress of thickener in Beneficiation. Conv & Util Mineral Res, 2015 (02): 73 (谢丹丹, 童雄, 谢贤, 等. 浓密机在选矿中的应用现状及研究进展[J]. 矿产保护与利用, 2015(02): 73) [13] Xu Y R, Ban X J, Wang X K, et al. Simulations of silicone oil filling for use in retinal detachment surgery. Chin J Eng, 2021, 43(09): 1233 (徐衍睿, 班晓娟, 王笑琨, 等. 面向视网膜脱离手术的硅油填充模拟. 工程科学学报, 2021, 43(09): 1233) [14] Cui Y, Ravnik J, Steinmann P, et al. Settling characteristics of nonspherical porous sludge flocs with nonhomogeneous mass distribution. Water Res, 2019, 158(1): 159 [15] Gao H, Stenstrom M K. Development and applications in computational fluid dynamics modeling for secondary settling tanks over the last three decades: A review. Water Environ Res, 2020, 92(6): 796 [16] Shan M T, Parmar H B, Rhyne L D, et al. A novel settling tank for produced water treatment: CFD simulations and PIV experiments. J Pet Sci Eng, 2019, 182: 106352 [17] Yao J J, Song L L, Liu C. Numerical simulation and structural optimization of the water distribution channel in front of the inclined plate sedimentation tank. J Water Res Eng , 2020, 31(05): 120 (姚娟娟, 宋莉莉, 刘存. 斜板沉淀池前配水渠的数值模拟及结构优化. 水资源与水工程学报, 2020, 31(05): 120) [18] Wei W L, Hu J J, Wang C Z, et al. Numerical simulation study on the optimization of the outlet position of the radial flow sedimentation tank. Chin J Appl Mech, 2021, 38(02): 670 (魏文礼, 胡嘉冀, 王长洲, 等. 辐流式沉淀池出口位置优化数值模拟研究. 应用力学学报, 2021, 38(02): 670) [19] Lan B, Xu Ji, Liu Z C, et al. Simulation of scale-up effect of particle residence time distribution 录用稿件，非最终出版稿