Shear Test and PFC Meso-simulation Analysis of Sand-Steel Interface

doi:10.11988/ckyyb.20230994

Abstract

Abstract:

This study investigates the influence of normal stress and interfacial roughness on the shear mechanical properties of sand-steel plate contact interface and explores the underlying mechanisms through large-scale interface shear tests and PFC mesoscopic simulations. The findings indicate that increased interfacial roughness leads to a higher interfacial friction angle, enhanced interfacial shear strength and residual strength, and more pronounced shear shrinkage and dilatancy of the sand. As normal stress increases, interfacial shear strength and residual strength improve, shear shrinkage of the sand increases, and dilatancy decreases. During the shear process, sand particles move and aggregate in the shear direction, resulting in the merging of strong contact force chains, with a decrease in their numbers but improved force transmission performance. The interfacial roughness affects the contact area between sand particles and the steel plate by altering the number of sand particles in the steel plate grooves, thereby influencing the interface’s shear mechanical properties. Normal stress affects the compactness and contact force between sand and steel plate, leading to changes in the interface’s shear mechanical properties.

Key words: sand-steel plate contact interface, interface shear test, PFC, mesoscopic simulation, interface roughness, normal stress

CLC Number:

TU411实验室试验(室内土工试验)

LI Yong-hui, WANG Hai, NIU Heng-yu, JIANG Xiao-tian. Shear Test and PFC Meso-simulation Analysis of Sand-Steel Interface[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(2): 107-114.

Figures/Tables 18

Table 1 Basic physical parameters of test sand

颗粒相对密度 G_s	平均粒径D₅₀/ mm	不均匀系数C_u	曲率系数C_c	最大干密度 ρ_{d max}/ (g·cm^-3)	最小干密度 ρ_{d min}/ (g·cm^-3)
2.65	1.00	4.03	0.93	1.74	1.46

Fig.1 Particle gradation curve of test sand

Fig.2 Test steel plate and embossing

Fig.3 Large direct shear test device

Fig.4 Shear test diagram

Fig.5 Curves of shear stress vs. shear displacement

Fig.6 Curves of normal displacement vs. shear displacement

Fig.7 Fitting of shear strength

Fig.8 Curves of interfacial friction angle vs. interfacial roughness

Fig.9 Particle shape template

Fig.10 Microscopic model

Table 2 Related parameters of meso-samples

参数	数值
试样尺寸/(mm×mm)	500×150
颗粒总数量/个	41 000~43 000
颗粒密度/(kg∙m^-3)	2 650
初始孔隙率	0.14
赫兹剪切模量/Pa	1.5×10⁹
泊松比	0.3
制样摩擦系数	0.2
加载摩擦系数	0.5
目标恢复系数	0.6
墙法向刚度/(N∙m^-1)	1.0×10⁸
墙切向刚度/(N∙m^-1)	1.0×10⁸
加载rblock-rblock接触有效模量/Pa	6.0×10⁷
加载rblock-facet接触剪切模量/Pa	9.0×10⁷
刚度比	1.0
抗转动系数	0.3
模拟剪切速度/(mm∙s^-1)	0.05

Fig.11 Comparison between experimental and simulated characteristic curves

Fig.12 Change of porosity field in shear process

Fig.13 Change of strong contact force chain in shearing process

Fig.14 Complete shear displacement field with varied interfacial roughness

Fig.15 Average horizontal displacements of particles at different heights of the sample

Fig.16 Variation curves of mesoscopic parameters of the whole specimen and the shear zone

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