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Simulation gas-solid flow in the downer with new structure-based drag model. POWDER TECHNOLOGY[J]. 2018, 323: 163-175, http://dx.doi.org/10.1016/j.powtec.2017.10.015.[5] Li, Jun, Li, Jianwei, Zhu, Qingshan, Li, Hongzhong. Magnetic field acceleration of CO2 reforming of methane over novel hierarchical Co/MgO catalyst in fluidized bed reactor. CHEMICAL ENGINEERING JOURNAL[J]. 2018, 350: 496-506, http://dx.doi.org/10.1016/j.cej.2018.05.034.[6] Peng, Li, Zou, Zheng, Zhang, Libo, Zhu, Qingshan, Li, Hongzhong. GPU-based discrete element simulation on flow stability of flat-bottomed hopper. CHINESE JOURNAL OF CHEMICAL ENGINEERING[J]. 2018, 26(1): 43-52, http://lib.cqvip.com/Qikan/Article/Detail?id=674661931.[7] Zhao, Hu, Li, Jun, Zhu, Qingshan, Li, Hongzhong. Modulating the mean residence time difference of wide-size particles in a fluidized bed. CHINESE JOURNAL OF CHEMICAL ENGINEERING[J]. 2018, 26(2): 238-244, http://lib.cqvip.com/Qikan/Article/Detail?id=674758405.[8] Yan, Dong, Li, Hongzhong, Zou, Zheng, Zhu, Qingshan. Simulation with a structure-based mass-transfer model for turbulent fluidized beds. PARTICUOLOGY[J]. 2018, 39: 40-47, http://lib.cqvip.com/Qikan/Article/Detail?id=675485815.[9] Li, Jun, Kong, Jing, He, Shengyi, Zhu, Qingshan, Li, Hongzhong. Self-agglomeration mechanism of iron nanoparticles in a fluidized bed. CHEMICAL ENGINEERING SCIENCE[J]. 2018, 177: 455-463, http://dx.doi.org/10.1016/j.ces.2017.11.038.[10] Li, Changjin, Zou, Zheng, Li, Hongzhong, Zhu, Qingshan. A hydrodynamic model of loop seal with a fluidized standpipe for a circulating fluidized bed. PARTICUOLOGY[J]. 2018, 36: 50-58, http://dx.doi.org/10.1016/j.partic.2017.02.005.[11] Zou, Zheng, Zhao, Yunlong, Zhao, Hu, Li, Hongzhong, Zhu, Qingshan, Xie, Zhaohui, Li, Yingbo. Numerical analysis of residence time distribution of solids in a bubbling fluidized bed based on the modified structure-based drag model. PARTICUOLOGY[J]. 2017, 32: 30-38, http://lib.cqvip.com/Qikan/Article/Detail?id=672365184.[12] 张涛. A model for improving the Euler CEuler two-phase flow theory to predict chemical reactions in circulating fluidized beds. Powder Technol. 2017, 321: 13-30, [13] Zou, Zheng, Zhao, Yunlong, Zhao, Hu, Zhang, Libo, Xie, Zhaohui, Li, Hongzhong, Zhu, Qingshan. Hydrodynamic and solids residence time distribution in a binary bubbling fluidized bed: 3D computational study coupled with the structure-based drag model. CHEMICAL ENGINEERING JOURNAL[J]. 2017, 321: 184-194, http://dx.doi.org/10.1016/j.cej.2017.03.110.[14] Liu, Wenming, Li, Hongzhong, Zhu, Qingshan. Modeling the hydrodynamics of downer reactors based on the meso-scale structure. POWDER TECHNOLOGY[J]. 2017, 314: 367-376, http://dx.doi.org/10.1016/j.powtec.2016.09.087.[15] 李洪钟. A transfer coefficient-based structure parameters method for CFD simulation of bubbling fluidized beds of Geldart A particles. Powder Technology. 2016, 295: 122-132, [16] 李洪钟. Eulerian Simulation of a Circulating Fluidized Bed with a New Flow Structure-Based Drag Model. Chemical Engineering Journal[J]. 2016, 284: 1224-1232, http://dx.doi.org/10.1016/j.cej.2015.09.073.[17] 李洪钟. Simulation of hydrodynamics in gas-solid bubbling fluidized bed with louver baffles in three dimensions. Powder Technology[J]. 2016, 296(AUG): 37-44, http://dx.doi.org/10.1016/j.powtec.2015.09.026.[18] Peng, Li, Xu, Ji, Zhu, Qingshan, Li, Hongzhong, Ge, Wei, Chen, Feiguo, Ren, Xinxin. GPU-based discrete element simulation on flow regions of flat bottomed cylindrical hopper. POWDER TECHNOLOGY[J]. 2016, 304(DEC): 218-228, http://dx.doi.org/10.1016/j.powtec.2016.08.029.[19] 李洪钟. The experiment and simulation of mass transfer in bubbling fluidized beds. Powder Technology[J]. 2016, 292(MAY): 323-330, http://dx.doi.org/10.1016/j.powtec.2016.02.001.[20] 李洪钟. Hydrodynamic behavior of magnetized fluidized beds with admixtures of Geldart-B magnetizable and nonmagnetizable particles. Particuology[J]. 2016, 29(DEC): 86-94, http://dx.doi.org/10.1016/j.partic.2015.12.010.[21] Yang, Shuai, Li, Hongzhong, Zhu, Qingshan. Experimental study and numerical simulation of baffled bubbling fluidized beds with Geldart A particles in three dimensions. CHEMICAL ENGINEERING JOURNAL[J]. 2015, 259: 338-347, http://dx.doi.org/10.1016/j.cej.2014.07.055.[22] 李洪钟. A structure-based drag model for the simulation of Geldart A and B particles in turbulent fluidized beds. Powder Technology[J]. 2015, 274(APR): 112-122, http://dx.doi.org/10.1016/j.powtec.2015.01.010.[23] 李洪钟. A two-stage reduction process for production of high purity ultrafine Ni particle in a micro-fluidized bed reactor. Particuology. 2015, 19: 27-34, [24] 李洪钟. Roasting-induced phase change and its influence on phosphorus removal through acid leaching for high phosphorus iron ore. International Journal of Minerals:Metallurgy and Materials[J]. 2015, 22(4): 346-352, http://lib.cqvip.com/Qikan/Article/Detail?id=664390186.[25] 李洪钟. A new structural parameters model based on drag coefficient for simulation of circulating fluidized beds. Powder Technology[J]. 2015, 286(DEC): 516-526, http://dx.doi.org/10.1016/j.powtec.2015.08.049.[26] Lei, Chao, Zhu, Qingshan, Li, Hongzhong. Experimental and theoretical study on the fluidization behaviors of iron powder at high temperature. CHEMICAL ENGINEERING SCIENCE[J]. 2014, 118(OCT.): 50-59, http://www.irgrid.ac.cn/handle/1471x/903985.[27] 李洪钟. Hydrodynamic study on magnetized fluidized beds with Geldart-B magnetizable particles. Powder Technology[J]. 2014, 268: 48-58, http://dx.doi.org/10.1016/j.powtec.2014.08.019.[28] 李洪钟. A new drag model for TFM simulation of gas-solid bubbling fluidized beds with Geldart-B particles. Particuology[J]. 2014, 15(S1): 151-159, http://dx.doi.org/10.1016/j.partic.2013.07.003.[29] Lei, Chao, Zhang, Tao, Zhang, Jianbo, Fan, Chuanlin, Zhu, Qingshan, Li, Hongzhong. Influence of Content and Microstructure of Deposited Carbon on Fluidization Behavior of Iron Powder at Elevated Temperatures. ISIJ INTERNATIONAL[J]. 2014, 54(3): 589-595, http://cas-ir.dicp.ac.cn/handle/321008/145440.[30] Li, Jun, Zhou, Li, Zhu, Oingshan, Li, Hongzhong. Decoupling reduction-sulfurization synthesis of inorganic fullerene-like WS2 nanoparticles in a particulately fluidized bed. CHEMICAL ENGINEERING JOURNAL[J]. 2014, 249: 54-62, http://dx.doi.org/10.1016/j.cej.2014.03.085.[31] Zhang, Jianbo, Zhang, Gengyu, Zhu, Qingshan, Lei, Chao, Xie, Zhaohui, Li, Hongzhong. Morphological Changes and Reduction Mechanism for the Weak Reduction of the Preoxidized Panzhihua Ilmenite. 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