Improved similarity criterion for seepage erosion using mesoscopic coupled PFC–CFD model 被引量：3

Improved similarity criterion for seepage erosion using mesoscopic coupled PFC–CFD model

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摘要 Conventional model tests and centrifuge tests are frequently used to investigate seepage erosion. However, the centrifugal test method may not be efficient according to the results of hydraulic conductivity tests and piping erosion tests. The reason why seepage deformation in model tests may deviate from similarity was first discussed in this work. Then, the similarity criterion for seepage deformation in porous media was improved based on the extended Darcy-Brinkman-Forchheimer equation. Finally, the coupled particle flow code–computational fluid dynamics(PFC-CFD) model at the mesoscopic level was proposed to verify the derived similarity criterion. The proposed model maximizes its potential to simulate seepage erosion via the discrete element method and satisfy the similarity criterion by adjusting particle size. The numerical simulations achieved identical results with the prototype, thus indicating that the PFC-CFD model that satisfies the improved similarity criterion can accurately reproduce the processes of seepage erosion at the mesoscopic level. Conventional model tests and centrifuge tests are frequently used to investigate seepage erosion. However, the centrifugal test method may not be efficient according to the results of hydraulic conductivity tests and piping erosion tests. The reason why seepage deformation in model tests may deviate from similarity was first discussed in this work. Then, the similarity criterion for seepage deformation in porous media was improved based on the extended Darcy-Brinkman-Forchheimer equation. Finally, the coupled particle flow code-computational fluid dynamics（PFC-CFD） model at the mesoscopic level was proposed to verify the derived similarity criterion. The proposed model maximizes its potential to simulate seepage erosion via the discrete element method and satisfy the similarity criterion by adjusting particle size. The numerical simulations achieved identical results with the prototype, thus indicating that the PFC-CFD model that satisfies the improved similarity criterion can accurately reproduce the processes of seepage erosion at the mesoscopic level.

作者倪小东王媛陈珂赵帅龙

机构地区 Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering

出处《Journal of Central South University》 SCIE EI CAS CSCD 2015年第8期3069-3078,共10页 中南大学学报（英文版）

基金 Project(51309086)supported by the National Natural Science Foundation of China Project(20110094120002)supported by the Ministry Education Foundation of China Projects(2014B04914,2011B07214)supported by the Fundamental Research Funds for the Central Universities,China

关键词 mesoscopic model centrifugal model similarity criterion particle flow code-computational fluid dynamics （PFC-CFD） cfd模型耦合渗流相似准则侵蚀过程介观层次计算流体动力学离心试验模型试验

分类号 O357.3 [理学—流体力学]

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参考文献17

1KAMIL K, TUGCE B, MEHMET C B, ERSIN K. Evaluation of the hydraulic conductivity of saturated, fine-grained soils using a small-size centrifuge [J]. Electronic Journal of Geotechnical Engineering, 2013, 28: 2383-2395.
2THUSYANTHAN N I, MADABHUSHI S P G. Scaling of seepage flow velocity in centrifuge models [J]. 2003, CUED/D-SOILS/TR326.
3EDUARDO D, JORGE G Z, ALEXANDRE R C. Suction profiles and scale factor for unsaturated flow and increased gravitational field [J] Soils and Foundations, 2004, 40(3): 79-89.
4DEVENDRA N S, ASHOK K G. Modelling hydraulic conductivity in a small centrifuge [J]. Canadian Geotechnical Journal, 2000, 37(5): 1150-1155.
5王秋生,陈祖煜,隋海宾,侯瑜京,梁建辉.离心机模拟中渗流相似率的试验验证[J].岩土工程学报,2011,33(8):1235-1239. 被引量：7
6HAN Y, CUNDALL P A. LBM-DEM modeling of fluid-solid interaction in porous media [J]. International Journal for Numerical and Analytical Methods in Geomechanics, 2012, 37: 1391-1407.
7YU Yu-zhen, DENG Li-jun, SUN Xun, LIJ He. Centrifuge modeling of dynamic behavior of pile-reinforced slopes during earthquakes [J]. Journal of Central South University of Technology, 2010, 17(4): 1070-1078.
8ZHAO Yan-lin, CAO Ping, WANG Wei-jun, WAN Wen, CHEN Rui Wing crack model subjected to high hydraulic pressure and far field stresses and its numerical simulation [J]. Journal of Central South University, 2012, 19(2): 578-585.
9GARNIER J, GAUDIN C, SPRINGMAN S M, CULLIGAN P J, GOODINGS D J, KONIG D, THOREL L. Catalogue of scaling laws and similitude questions in geotechnical centrifuge modeling [J]. International Journal of Physical Modelling in Geotechnics, 2007, 7(3): 1-23.
10LI Chuan-xun, XIE Kang-he, HU An-feng, HU Bai-xiang. One-dimensional consolidation of double-layered soil with non-Dareian flow described by exponent and threshold gradient [J]. Journal of Central South University, 2012, 19: 562-571.

二级参考文献11

1LAUT P. Application of centrifugal tests in connection with studies of flow patterns of contaminated water in soil structures[J]. Geotechnique, 1975, 25:401 - 406.
2GOODINGS D J. Relationships for centrifugal modelling of seepage and surface flow effects on embankment dams[J]. Geotechnique, 1982, 32: 149- 152.
3BUTTERFIELD R. Scale-modelling of fluid in geotechnical centrifuges[J]. Soils and Foundations, 2000, 40(6): 39 - 45.
4ARULANANDAN K, THOMPSON P Y, KUTTER B L, et al. Centrifuge modelling of transport processes for pollutants in soils[J]. Journal of Geotechnical Engineering, ASCE, 1988, 114(2): 185 - 205.
5SINGH D N, GUPTA K A. Modelling hydraulic conductivity in a small centrifuge[J]. Canadian Geotechnical Journal, 2000, 37(1): 1150- 1155.
6THUSYANTHAN N I, MADABHUSHI S P G Scaling of seepage flow velocity in centrifuge models[C]// CUED/D-SOILS/TR-326, 2003.
7BEAR J. Dynamics of fluids in porous media[M]. New York: American Elsevier Publishing Company, 1972.
8TAYLOR R N. Geotechnical centrifuge technology[M]. Blackie Academic & Professional, 1995.
9TAYLOR R N. Discussion on Tan&Scott[J]. Geotechnique, 1987, 37(1): 131 - 133.
10LORRAINE E F, JOHN S S. Use of porosity to estimate hydraulic properties of vocanic tufts[J]. Advances in Water Resources, 2003, 26:561 - 571.

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2梁建辉,宋献慧.基于液压系统的离心模拟试验大荷载施加方法研究[J].中国水利水电科学研究院学报,2017,15(4):324-328. 被引量：2
3蔡耀军,杨兴国,张利民,周家文,彭文祥,范刚.堰塞湖风险评估快速检测与应急抢险技术和装备研发研究构想与成果展望[J].工程科学与技术,2020,52(2):10-18. 被引量：12
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5ZHAO Tian-long,CHEN Sheng-shui,FU Chang-jing,ZHONG Qi-ming.Centrifugal model tests and numerical simulations for barrier dam break due to overtopping[J].Journal of Mountain Science,2019,16(3):630-640. 被引量：6
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1LIANG Yue,WANG Jun-jie,LIU Ming-wei.Two-flow model for piping erosion based on liquid-solid coupling[J].Journal of Central South University,2013,20(8):2299-2306. 被引量：2
2庄峰青,刘大有.圆球形粒子超高速撞击侵蚀过程的数值模拟[J].宇航学报,1996,17(2):65-69. 被引量：3
3Xue Li SONG,Van Ren HOU.Uniform Attractors for a Non-Autonomous Brinkman-Forchheimer Equation[J].Journal of Mathematical Research with Applications,2012,32(1):63-75. 被引量：1
4赵国昌,过增元,胡桅林.熔窑内玻璃液流动与传热模型实验的新准则[J].清华大学学报（自然科学版）,1996,36(6):26-30.
5李宏,徐曾和,王泳嘉.弹性流体一维耦合渗流的计算机代数解[J].东北大学学报（自然科学版）,1998,19(2):111-115. 被引量：1
6戎子标.FB2—A型15kg—300g离心加速度试验机的研制[J].湖北航天科技,1994(4):18-24.
7赵国昌.熔窑玻璃液流模型实验设计方法[J].玻璃,1996,23(5):1-5.
8朱崇军,左可正.关于一个矩阵的秩的等式[J].湖北师范学院学报（自然科学版）,2000,20(2):36-39.
9Jum-Ran KANG,Jong-Yeoul PARK.Uniform Attractors for Non-autonomous Brinkman-Forchheimer Equations with Delay[J].Acta Mathematica Sinica,English Series,2013,29(5):993-1006. 被引量：2
10徐曾和,徐小荷,沈连山.可变形多孔介质中的一维非定常耦合渗流[J].应用力学学报,1999,16(4):46-51. 被引量：9

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