Discrete element simulation of impact disaggregation for wet granule agglomerate

Jiao Yang; Zhang Xin-Xi; Kong Fan-Cheng; Liu Hair-Shun

doi:10.7498/aps.64.154501

Abstract

Based on the combination of linear contact model, Coulomb slip contact model and parallel bond contact model, a discret element model (DEM) of wet granule agglomerates with coating structure is constructed. Disaggregation processes of wet agglomerates in impacting to a horizontal plate are performed by applying particle flow code (PFC). Three failure patterns are obtained corresponding to those in experiment. The variation of velocities and rupture characteristics of liquid bridge in disaggregation process are investigated. Effects of impact velocity, gravity of adhered granules, and rotation of core granule are analyzed. DEM simulations show that there are three disaggregation patterns in the coating structure of agglomerates: impact disaggregation, gravity-impact disaggregation and shear-impact disaggregation, depending on the size of primary particles and the rotation of the core granules. With the enlargement of size, gravity plays an increasingly important role and the impact disaggregation pattern shifts to gravity-impact disaggregation. The rotation of core can generate a shear force to separate the fine and disaggregation pattern to turn to shear-impact disaggregation. Impacting results in a heterogeneous distribution of granule velocities and a tendency of relative movement in agglomerates. Relative movement will bring about the stretch of liquid bridge between granules. If the maximum separation distance of wet granules exceeds the rupture distance of liquid bridge, disaggregation happens. The ruptures of liquid bridge start from impact point and expand to outward, from bottom to up, from inside to outside in coating agglomeration. It is found that the rupture of liquid bridge needs time for accumulation and goes through three stages termed as slow rupture stage, quick rupture stage and entire rupture stage. With the increase of impact velocity, particle gravity, and rotating speed of core granules, disaggregation processes of wet granule agglomerates become fast and thorough. Impact velocity plays a primary role in disaggregation. DEM simulations are consistent with the experimental results.

Keywords:

Authors and contacts

1.
College of Science, China University of Mining & Technology, Xuzhou 221116, China;
2.
School of Chemical Engineering and Technology, China University of Mining & Technology, Xuzhou 221116, China;
3.
Department of aerial ammunition, Air Force Logistics College, Xuzhou 221000, China
Funds: Project supported by the Natural Science Foundation Research of Jiangsu Province, China (Grant No. BK20141124).

References

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[2]	Jinsheng F, Gavin K R, Michael J A 2005 Chemical Engineering Science 60 4005
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[9]	Sergiy A, Manoj K, Jurgen T 2006 Chemical Engineering and Processing 45 838
[10]	Mishra B K, Thornton C 2001 International Journal of Mineral Processing 61 225
[11]	Liu L, Kafui K D, Thornton C 2010 Powder Technology 199 189
[12]	Xu Y, Sun Q C, Zhang L,Huang W B 2003 Advanced in Mechanics 33 253 (in Chinese) [徐泳,孙其诚,张凌,黄文彬 2003 力学进展 33 253]
[13]	Christopher D, Michael J 2000 Langmuir 16 9396
[14]	Hotta K, Taked A K, Iinoya K 1974 Powder Technology 10 231
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[16]	Davis R H, Serayssol J M, Hinch E J 1986 Journal of Fluid Mechanics 163 479
[17]	Zhang R 2005 Ph. D. Dissertation (Jilin: Ji Lin University) (in Chinese) [张锐 2005 博士学位论文(吉林:吉林大学)]
[18]	Zhang R, Li J Q, Zhou C H, Xu S C 2007 Transactions of the Chinese Society of Agricultural Engineering 23(9) 13 (in Chinese) [张锐,李建桥,周长海,许述财 2007 农业过程学报 23(9) 13]
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Cited By

[1]	Fu J S, Cheong Y S, Adams M J, Reynolds G K 2004 Powder Technology 140 24
[2]	Jinsheng F, Gavin K R, Michael J A 2005 Chemical Engineering Science 60 4005
[3]	Gao H L, Chen Y C, Zhao Y Z, Zhen J Y 2011 Acta Phys. Sin. 60 124501 (in Chinese) [高红利, 陈友川, 赵永志, 郑津洋 2011 物理学报 60 124501]
[4]	Zhao L L, Zhao Y M, Liu C S, Li J 2014 Acta Phys. Sin. 63 034501 (in Chinese) [赵啦啦, 赵跃民, 刘初升, 李珺 2014 物理学报 63 034501]
[5]	Radl S, Kalvoda E, Glasser B J, Khinast J G 2010 Powder Technology 200 171
[6]	Zhu R R, Zhu W B, Xing L C, Sun Q Q 2011 Powder Technology 210 73
[7]	He Y, Peng W, Wang T, Yan S 2014 Mathematical Problems in Engineering 31 568
[8]	Thornton C, Liu L 2004 Powder Technology 143 110
[9]	Sergiy A, Manoj K, Jurgen T 2006 Chemical Engineering and Processing 45 838
[10]	Mishra B K, Thornton C 2001 International Journal of Mineral Processing 61 225
[11]	Liu L, Kafui K D, Thornton C 2010 Powder Technology 199 189
[12]	Xu Y, Sun Q C, Zhang L,Huang W B 2003 Advanced in Mechanics 33 253 (in Chinese) [徐泳,孙其诚,张凌,黄文彬 2003 力学进展 33 253]
[13]	Christopher D, Michael J 2000 Langmuir 16 9396
[14]	Hotta K, Taked A K, Iinoya K 1974 Powder Technology 10 231
[15]	Lian G, Adamsand M J, Thornton C 1996 Journal of Fluid Mechanics 311 141
[16]	Davis R H, Serayssol J M, Hinch E J 1986 Journal of Fluid Mechanics 163 479
[17]	Zhang R 2005 Ph. D. Dissertation (Jilin: Ji Lin University) (in Chinese) [张锐 2005 博士学位论文(吉林:吉林大学)]
[18]	Zhang R, Li J Q, Zhou C H, Xu S C 2007 Transactions of the Chinese Society of Agricultural Engineering 23(9) 13 (in Chinese) [张锐,李建桥,周长海,许述财 2007 农业过程学报 23(9) 13]
[19]	Itasca C 2004 Particle flow code, PFC2D 3.1 (Minneapolis, Minnesota Press) p123
[20]	Shen Z F, Jiang M J, Zhu F Y, Hu H J 2011 Northwestern Seismological Journal 33(8) 160 (in Chinese) [申志福,蒋明镜,朱方园,胡海军 2011 西北地震学报 33(8) 160]
[21]	Cundall P A, Strack O L 1997 Geotechnique 29(1) 47
[22]	Yang Y, Tang S G, Wang J L 2007 Computer Aider Engineering 16 (3) 65 (in Chinese) [杨洋, 唐寿高,王居林 2007 计算机辅助工程 16 (3) 65]
[23]	Iwashita K, Oda M 1998 Journal of Engineering Mechanics 124 285
[24]	Jiao Y , Zhang X X , Kong F C 2014 Journal ofChina Coal Society 39 2092 (in Chinese) [焦杨,章新喜,孔凡成 2014 煤炭学报 39 2092]

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Vol. 64, Issue 15 - 2015-08-05

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