Predicting wall drag coefficient and settling velocity of particle in parallel plates filled with Newtonian fluids

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摘要 The hindrance of boundary to particle transport exists widely in various industrial applications.In this study,the wall drag force of parallel plates on settling particles was revealed through settling experiment.High-speed camera was used to record and analyze the settling process of particles in parallel plates that are filled with Newtonian fluids.A total of 600 experiments were carried out,involving the range of relative diameter and particle Reynolds number of 0.01-0.95 and 0.004-14.30,respectively.The wall drag coefficient was defined to quantitatively analyze the wall drag force of the parallel plates.The influence of relative diameter,particle properties,rheological properties,and the settling dynamic process on the wall drag coefficient was revealed,and the wall drag coefficient model with mean relative error of 5.90% was established.Furthermore,an explicit settling velocity model with mean relative error of 8.96% for the particle in parallel plates was developed by introducing a dimensionless variable independent of settling velocity,the Archimedes number.Finally,a calculation example was provided to clarify the using process of the explicit model.This research is expected to provide guidance for optimizing water hydraulic fracturing in the oil and gas industry.

作者 Zhaopeng Zhu Xianzhi Song Gensheng Li Zhengming Xu Silin Jing Xiaozhou Qin Shiming Duan

机构地区 State Key Laboratory of Petroleum Resources and Prospecting China University of Geosciences

出处《Particuology》 SCIE EI CAS CSCD 2021年第5期242-250,共9页 颗粒学报（英文版）

基金 the Strategic Cooperation Technology Projects of CNPC and CUPB(ZLZX2020-03) the National Science and Technology Major Project(No.2016ZX05028) China Scholarship Council(No.201906440166)for their financial support.

关键词 Wall drag coefficient Settling velocity Parallel plates Explicit model

分类号 O35 [理学—流体力学]

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参考文献6

1Okorie E.Agwu,Julius U.Akpabio,Adewale Dosunmu.Artificial neural network model for predicting drill cuttings settling velocity[J].Petroleum,2020,6(4):340-352. 被引量：2
2Lei Kong,Chao Zhang,Jesse Zhu.Evaluation of the effect of wall boundary conditions on numerical simulations of circulating fluidized beds[J].Particuology,2014,12(2):114-123. 被引量：3
3Guang Lu,James R.Third,Christoph R.Müller.Effect of wall rougheners on cross-sectional flow characteristics for non-spherical particles in a horizontal rotating cylinder[J].Particuology,2014,12(1):44-53. 被引量：8
4Rupesh K.Reddy,Jyeshtharaj B.Joshi.CFD modeling of pressure drop and drag coefficient in fixed beds:Wall effects[J].Particuology,2010,8(1):37-43. 被引量：7
5Zhengming Xu,Xianzhi Song,Gensheng Li,Zhaoyu Pang,Zhaopeng Zhu.Settling behavior of non-spherical particles in power-law fluids:Experimental study and model development[J].Particuology,2019,17(5):30-39. 被引量：7
6Xinyu Zhou,Jinsen Gao,Chunming Xu,Xingying Lan.Effect of wall boundary condition on CFD simulation of CFB risers[J].Particuology,2013,11(5):556-565. 被引量：6

二级参考文献85

1Calis, H. P. A., Nijenhuis, J., Paikert, B. C., Dautzenberg, F. M., & van den Bleek, C M. (2001). CFD modeling and experimental validation of pressure drop and flow profile in a novel structured catalytic reactor packing. Chemical Engineering Science, 56, 1713-1720.
2Carman, P. C. (1937 ). Fluid flow through granular beds. Transactions of the Institution of Chemical Engineers, 15. 150-166.
3Chu, C, F., & Ng, K. M. (1989). Flow in packed bed tubes with small tube to particle diameter ratio. AIChEJoumal, 35, 148-158.
4Coulson, J. M. (1949). The flow of fluids through granular beds: Effect of particle shape and voids in streamline flow. Transactions of the Institution of Chemical Engineers, 27, 237-257.
5Dalman, M. T., Merkin, J. H., & McGreav,J, C. (1986). Fluid flow and heat transfer past two spheres in a cylindrical tube. Computers & Fluids, 14, 267-281.
6Di Felice, R., & Gibilaro, L G. (2004). Wall effects for the pressure drop in fixed beds. Chemical Engineering Science, 59, 3037-3040.
7Eisfeld, B., & Schnitzlein, K. (2001). The influence of confining walls on the pressure drop in packed beds. Chemical Engineering Science, 56, 4321-4329.
8Ergun, S. (1952). Fluid flow through packed columns. Chemical Engineering Progress, 48. 89-94.
9Foumeny, E. A., Benyahia, F., Castro, J. A. A., Moallemi, H. A., & Roshani. S. 0993). Correlations of pressure drop in packed beds taking into account the effect of confining wall. International Journal of Heat and Mass Transfer, 36, 536-540.
10Guardo, A., Coussirat, M., Larrayoz, M. A., Recasens, F., & Egusquiza, E. (2005). Influence of the turbulence model in CFD modeling of wall-to-fluid heat transfer in packed beds, Chemical Engineering Science,60, 1733-1742.

共引文献26

1陈静,程党国,陈丰秋.乙炔氢氯化固定床反应器的模拟分析[J].浙江大学学报（工学版）,2012,46(4):749-755. 被引量：6
2卢竟蔓,蓝兴英,徐春明,高金森.壁面条件对FCC颗粒湍动床气固流动影响的模拟[J].化学反应工程与工艺,2014,30(1):57-62. 被引量：3
3冯军胜,董辉,李明明,蔡九菊.烧结余热回收竖罐内固定床层的阻力特性[J].中南大学学报（自然科学版）,2014,45(8):2566-2571. 被引量：16
4钟汉斌,郑亚君,张智平.双组分颗粒瞬态分级过程的三维CFD模拟[J].中国粉体技术,2016,22(4):19-24. 被引量：2
5张立栋,韦庆文,秦宏,王擎.柱状生物质颗粒与钢球颗粒在滚筒中的混合特性[J].化工进展,2016,35(10):3057-3064. 被引量：8
6Milinkumr T. Shah,Ranjeet P. Utikar,Vishnu K. Pareek.CFD study： Effect of pulsating flow on gas-solid hydrodynamics in FCC riser[J].Particuology,2017,15(2):25-34. 被引量：5
7Lei Huang,Lin Qi,Hongna Wang,Jinli Zhang,Xiaoqiang Jia.Optimal design of heat exchanger header for coal gasification in supercritical water through CFD simulations[J].Chinese Journal of Chemical Engineering,2017,25(8):1101-1108. 被引量：1
8王春雷,王日杰,杨晓霞,乔胜超.固定床内压降的CFD分析[J].化学工业与工程,2017,34(6):88-94. 被引量：3
9Nan Gui,Xingtuan Yang,Jiyuan Tu,Shengyao Jiang.Flow fields and packing states in the discharge flow of noncircular particles-A SIPHPM simulation[J].Particuology,2017,15(6):10-21. 被引量：1
10吴南星,赵增怡,朱祚祥,廖达海,余冬玲,陈涛.基于铰刀厚度的陶瓷干法造粒混料过程数值分析[J].中国粉体技术,2018,24(1):25-31. 被引量：1

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Predicting wall drag coefficient and settling velocity of particle in parallel plates filled with Newtonian fluids

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