[1] JAVAN D T, JIE B, NICOLAS H,et al. Modeling collective dynamics of particulate systems under time-varying operating conditions based on Markov chains [J]. Advanced Powder Technology, 2013, 24(2): 451-458.
[2] JOCHEN M, ECHEHARD S, LIU X Y. Prediction of rolling bed motion in rotating cylinders [J]. AIChE Journal, 2004, 50(11): 2783-2793.
[3] HUCKAUF H, SCHLEGEL R, HOYER L, et al. Rorschungsbericht [R]. Magdeburg: IBU-tec GmbH Weimar/Ottovon-Guericke-Universitt Magdeburg, 1995.
[4] HENEIN H, BRIMACOMBE J K, WATKINSON A P. The modeling of transverse solids motion in rotary kilns [J]. Metall Urgical Transactions B, 1983, 14(B): 207220.
[5] MELLMANN J. The transverse motion of solids in rotating cylinders-forms of motion and transition behavior [J]. Powder Technology, 2001,118(3): 251-270.
[6] DING Y L, FORSTER R, SEVILLE J P K, et al. Granular motion in rotating drums: bed turnover time and slumping-rolling transition [J]. Powder Technology, 2002, 124(1/2): 18-27.
[7] DEMAGH Y, MOUSSA H B, LACHI M, et al. Surface particle motions in rotating cylinders: Validation and similarity for an industrial scale kiln [J]. Powder Technology, 2012, 224: 260-272.
[8] CHENG N S, ZHOU Q, TAN S K, et al. Application of incomplete similarity theory for estimating maximum shear layer thickness of granular flows in rotating drums [J].Chemical Engineering Science, 2011, 66(12): 2872-2878.
[9] LIU X Y, SPECHT E, MELLMANN J. Experimental study of the lower and upper angles of repose of granular materials in rotating drums [J]. Powder Technology, 2005, 154(2/3): 125-131.
[10] SPECHT E, SHI Y C, WOCHE H, et al. Experimental investigation of solid bed depth at the discharge end of rotary kilns [J]. Powder Technology, 2010, 197(1/2): 17-24.
[11] 曹秒艳,董国疆,赵长财.基于离散元法的固体颗粒介质传力特性研究[J].机械工程学报,2011, 47(14): 62-69.
CAO Miao-yan, DONG Guo-jiang, ZHAO Chang-cai. Research on pressure-transfer characteristics in the solid granule medium forming based on the discrete element method [J]. Journal of Mechanical Engineering, 2011, 47(14): 62-69.
[12] YANG R Y, ZOU R P, YU A B. Microdynamic analysis of particle flow in a horizontal rotating drum [J]. Powder Technology, 2003, 130(1-3): 138-146.
[13] YANG R Y, YU A B, MCELROY L, et al. Numerical simulation of particle dynamics in different flow regimes in a rotating drum [J]. Powder Technology, 2008, 188(2): 170-177.
[14] FINNIE G J, KRUYT N P, YE M, et al. Longitudinal and transverse mixing in rotary kilns: A discrete element method approach [J]. Chemical Engineering Science, 2005, 60(15): 4083-4091.
[15] LIU P Y, YANG P Y, YU A B. DEM study of the transverse mixing of wet particles in rotating drums [J]. Chemical Engineering Science, 2013, 86: 99-107.
[16] GUI N, YAN J, XU W K, et al. DEM simulation and analysis of particle mixing and heat conduction in a rotating drum [J]. Chemical Engineering Science, 2013, 97: 225-234.
[17] BOUCHAUD J P, CATES M E, CLAUDIN P. Stress distribution in granular media and nonlinear wave equation[J]. Journal de Physique, 1995, 5: 639-656.
[18] WALSH S D C, TORDESILLAS A, PETERS J F. Development of micromechanical models for granular media: the projection problem [J]. Granular Matter, 2007, 9(5): 337-352.
[19] 宜晨虹,慕青松,苗天德.重力作用下颗粒介质应力链的离散元模拟[J].物理学报, 2009, 58(11): 7750-7755.
YI Chen-hong, MU Qing-song, MIAO Tian-de. Discrete element method simulation on the force chains in the two-dimensional granular system under gravity [J]. ACTA PHYSICA SINICA, 2009, 58(11): 7750-7755.
[20] SUN Q C, WANG G Q, HU K H. Some open problems in granular matter mechanics [J]. Progress in Natural Science, 2009, 19(5): 523-529.
[21] THORNTON C, ANTONY S J. Quasi-static shear deformation of a soft particle system [J]. Powder Technology, 2000, 109(1-3): 179-191. |