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On-line Access: 2024-08-27

Received: 2023-10-17

Revision Accepted: 2024-05-08

Crosschecked: 2023-03-31

Cited: 0

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Citations:  Bibtex RefMan EndNote GB/T7714

 ORCID:

Tuo WANG

https://orcid.org/0000-0001-6884-2763

Feng-shou ZHANG

https://orcid.org/0000-0002-4998-6259

Pei WANG

https://orcid.org/0000-0003-3835-2477

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Journal of Zhejiang University SCIENCE A 2023 Vol.24 No.4 P.319-331

http://doi.org/10.1631/jzus.A2200198


Experimental and numerical study of seepage-induced suffusion under K0 stress state


Author(s):  Tuo WANG, Feng-shou ZHANG, Pei WANG

Affiliation(s):  Key Laboratory of Geotechnical & Underground Engineering of Ministry of Education, Tongji University, Shanghai 200092, China; more

Corresponding email(s):   fengshou.zhang@tongji.edu.cn

Key Words:  Suffusion, Gap-graded soil, Discrete element method (DEM), Dynamic fluid mesh (DFM)


Tuo WANG, Feng-shou ZHANG, Pei WANG. Experimental and numerical study of seepage-induced suffusion under K0 stress state[J]. Journal of Zhejiang University Science A, 2023, 24(4): 319-331.

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author="Tuo WANG, Feng-shou ZHANG, Pei WANG",
journal="Journal of Zhejiang University Science A",
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pages="319-331",
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publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2200198"
}

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Abstract: 
suffusion in gap-graded soil involves selective erosion of fine particles through the pores formed by coarse particles under seepage forces. As the fines content (FC) decreases, the hydraulic and mechanical behavior of the soil will change, posing a huge threat to engineering safety. In this study, we first conduct a series of experimental tests of suffusion by using gap-graded soils and then analyze the evolution process of suffusion and the effect of the hydraulic gradient. Subsequently, according to the physical model, a discrete element method (DEM) numerical model with dynamic fluid mesh (DFM) is developed to extend the experimental study to the pore scale. Our results reveal the migration process of fines and the formation of erosion zones. A parametric study is then conducted to investigate the effect of the hydraulic gradient, FC, and K0 pressure (which limits the lateral displacement of the sample and applies vertical pressure) on eroded weight. The results show that the eroded weight increases with the increase of the hydraulic gradient and FC but decreases with the increase of K0 pressure.

K0应力状态下渗流潜蚀试验与数值研究

作者:王拓1,2,张丰收1,2,王培3
机构:1同济大学,岩土与地下工程教育部重点实验室,中国上海,200092;2同济大学,土木工程学院,地下工程系,中国上海,200092;3香港理工大学,土木与环境工程系,中国香港,999077
目的:目前,潜蚀过程并不能被直接观察到。本研究期望采用透明仪器直接观察潜蚀的演化过程,探讨K0应力状态下间断级配土的潜蚀过程。
创新点:1.研制出一个透明潜蚀仪器,可直接观测间断级配土的潜蚀过程;2.建立数值模型,扩展试验参数,在颗粒尺度上解释潜蚀规律。
方法:1.采用透明的潜蚀仪器,直接观测间断级配土的潜蚀过程,并记录潜蚀质量;2.通过离散元数值模拟的方法,在颗粒尺度上揭示颗粒的迁移规律。
结论:1.随着侵蚀的进行,试样内部形成侵蚀带并逐渐扩大;从力链分析可知,细颗粒在水流作用下逐渐堆积在粗颗粒形成的孔隙中,并被粗颗粒堵塞。2.当侵蚀和阻塞区形成时,流速也逐渐局部化;在侵蚀区,孔隙度增大,流速普遍较快,但在阻塞区,流速较慢。3.参数分析表明,最终潜蚀重量与水力梯度呈正相关关系,且潜蚀重量随K0压力的增大而减小;随着细粉含量的增加,潜蚀重量增加。

关键词:潜蚀;间断级配土;离散元法(DEM);动态流体网格(DFM)

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1]AhmadiM, ShireT, MehdizadehA, et al., 2020. DEM modelling to assess internal stability of gap-graded assemblies of spherical particles under various relative densities, fine contents and gap ratios. Computers and Geotechnics, 126:103710.

[2]BendahmaneF, MarotD, AlexisA, 2008. Experimental parametric study of suffusion and backward erosion. Journal of Geotechnical and Geoenvironmental Engineering, 134(1):57-67.

[3]ChangDS, 2012. Internal Erosion and Overtopping Erosion of Earth Dams and Landslide Dams. PhD Thesis, Hong Kong University of Science and Technology, Hong Kong, China.

[4]ChangDS, ZhangLM, 2011. A stress-controlled erosion apparatus for studying internal erosion in soils. Geotechnical Testing Journal, 34(6):GTJ103889.

[5]ChangDS, ZhangLM, 2013. Critical hydraulic gradients of internal erosion under complex stress states. Journal of Geotechnical and Geoenvironmental Engineering, 139(9):1454-1467.

[6]ChenC, ZhangLM, ChangDS, 2016. Stress-strain behavior of granular soils subjected to internal erosion. Journal of Geotechnical and Geoenvironmental Engineering, 142(12):06016014.

[7]ChengK, WangY, YangQ, 2018. A semi-resolved CFD-DEM model for seepage-induced fine particle migration in gap-graded soils. Computers and Geotechnics, 100:30-51.

[8]GolayF, BonelliS, 2011. Numerical modeling of suffusion as an interfacial erosion process. European Journal of Environmental and Civil Engineering, 15(8):1225-1241.

[9]HuZ, ZhangYD, YangZX, 2019. Suffusion-induced deformation and microstructural change of granular soils: a coupled CFD–DEM study. Acta Geotechnica, 14(3):795-814.

[10]HuangZ, BaiYC, XuHJ, et al., 2021. A theoretical model to predict suffusion-induced particle movement in cohesionless soil under seepage flow. European Journal of Soil Science, 72(3):1395-1409.

[11]HunterRP, BowmanET, 2018. Visualisation of seepage-induced suffusion and suffosion within internally erodible granular media. Géotechnique, 68(10):918-930.

[12]Itasca Consulting Group Inc., 2015. PFC3D (Particle Flow Code in 3 Dimensions), Version 5.0. Itasca Consulting Group Inc., Minneapolis, USA.

[13]JiSM, GeJQ, TanDP, 2017. Wall contact effects of particle-wall collision process in a two-phase particle fluid. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 18(12):958-973.

[14]JinZ, LuZ, YangY, 2021. Numerical analysis of column collapse by smoothed particle hydrodynamics with an advanced critical state-based model. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 22(11):882-893.

[15]KeL, TakahashiA, 2014. Experimental investigations on suffusion characteristics and its mechanical consequences on saturated cohesionless soil. Soils and Foundations, 54(4):713-730.

[16]KeL, TakahashiA, 2015. Drained monotonic responses of suffusional cohesionless soils. Journal of Geotechnical and Geoenvironmental Engineering, 141(8):04015033.

[17]KenneyTC, LauD, 1985. Internal stability of granular filters. Canadian Geotechnical Journal, 22(2):215-225.

[18]LiuQ, ZhaoB, SantamarinaJC, 2019. Particle migration and clogging in porous media: a convergent flow microfluidics study. Journal of Geophysical Research: Solid Earth, 124(9):9495-9504.

[19]LiuYJ, WangLZ, HongY, et al., 2020. A coupled CFD-DEM investigation of suffusion of gap graded soil: coupling effect of confining pressure and fines content. International Journal for Numerical and Analytical Methods in Geomechanics, 44(18):2473-2500.

[20]LuoYL, QiaoL, LiuXX, et al., 2013. Hydro-mechanical experiments on suffusion under long-term large hydraulic heads. Natural Hazards, 65(3):1361-1377.

[21]MarotD, LeVD, GarnierJ, et al., 2012. Study of scale effect in an internal erosion mechanism: centrifuge model and energy analysis. European Journal of Environmental and Civil Engineering, 16(1):1-19.

[22]MoffatR, FanninRJ, 2011. A hydromechanical relation governing internal stability of cohesionless soil. Canadian Geotechnical Journal, 48(3):413-424.

[23]MoffatR, FanninRJ, GarnerSJ, 2011. Spatial and temporal progression of internal erosion in cohesionless soil. Canadian Geotechnical Journal, 48(3):399-412.

[24]NardelliV, CoopMR, AndradeJE, et al., 2017. An experimental investigation of the micromechanics of Eglin sand. Powder Technology, 312:166-174.

[25]RochimA, MarotD, SibilleL, et al., 2017. Effects of hydraulic loading history on suffusion susceptibility of cohesionless soils. Journal of Geotechnical and Geoenvironmental Engineering, 143(7):04017025.

[26]ShireT, O’SullivanC, 2013. Micromechanical assessment of an internal stability criterion. Acta Geotechnica, 8(1):81-90.

[27]ShireT, O’SullivanC, HanleyKJ, et al., 2014. Fabric and effective stress distribution in internally unstable soils. Journal of Geotechnical and Geoenvironmental Engineering, 140(12):04014072.

[28]Silpa-AnanC, HartleyR, 2008. Optimised KD-trees for fast image descriptor matching. IEEE Conference on Computer Vision & Pattern Recognition, p.1-8.

[29]TangY, YaoXY, ChenYN, et al., 2020. Experiment research on physical clogging mechanism in the porous media and its impact on permeability. Granular Matter, 22(2):37.

[30]TaoR, YangMM, LiSQ, 2018. Filtration of micro-particles within multi-fiber arrays by adhesive DEM-CFD simulation. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 19(1):34-44.

[31]WanCF, FellR, 2008. Assessing the potential of internal instability and suffusion in embankment dams and their foundations. Journal of Geotechnical and Geoenvironmental Engineering, 134(3):401-407.

[32]WangP, GeY, WangT, et al., 2022a. CFD-DEM modelling of suffusion in multi-layer soils with different fines contents and impermeable zones. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), in press.

[33]WangP, YinZY, WangZY, 2022b. Micromechanical investigation of particle-size effect of granular materials in biaxial test with the role of particle breakage. Journal of Engineering Mechanics, 148(1):04021133.

[34]WenMJ, WangKH, WuWB, et al., 2021. Dynamic response of bilayered saturated porous media based on fractional thermoelastic theory. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 22(12):992-1004.

[35]YangJ, YinZY, LaouafaF, et al., 2019. Analysis of suffusion in cohesionless soils with randomly distributed porosity and fines content. Computers and Geotechnics, 111:157-171.

[36]YinZY, JinYF, ZhangX, 2021. Large deformation analysis in geohazards and geotechnics. Journal of Zhejiang University-SCIENCE A (Applied Physics & Engineering), 22(11):851-855.

[37]ZhangFS, LiML, PengM, et al., 2019. Three-dimensional DEM modeling of the stress–strain behavior for the gap-graded soils subjected to internal erosion. Acta Geotechnica, 14(2):487-503.

[38]ZhangFS, WangT, LiuF, et al., 2020. Modeling of fluid-particle interaction by coupling the discrete element method with a dynamic fluid mesh: implications to suffusion in gap-graded soils. Computers and Geotechnics, 124:103617.

[39]ZhangFS, WangT, LiuF, et al., 2022. Hydro-mechanical coupled analysis of near-wellbore fines migration from unconsolidated reservoirs. Acta Geotechnica, 17(8):‍3535-3551.

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