Journal of Shanghai University >
Numerical simulation of particle flow during a drawing test of a ribbed geomembrane and sandy soil interface under different temperatures
Received date: 2018-11-07
Online published: 2021-04-27
The features of a ribbed geomembrane and sandy soil interface in a landfill liner system were studied by comparing the results of an indoor experiment and a two-dimensional particle flow code (PFC$^{\rm 2D})$ simulation using the discrete element method. An interface drawing test of the ribbed geomembrane and sandy soil interface was conducted under different combinations of ribbed heights and temperatures. Then, the macroscopic stress-strain curves of the ribbed geomembrane and sandy soil interface, the changing rule of the displacement field of microscopic particles, and the stress field were investigated. The results showed that the tensile stress of the ribbed geomembrane and sandy soil interface was superior to that of the smooth geomembrane ($h =0$ mm) and sandy soil interface. The drawing stress limit of the interface increased with the increase in rib height, and decreased with the increase in temperature. In addition, the friction coefficient of the interface decreased with the increase in temperature. Simulation of the microscopic aspects (particle displacement and internal contact force) also corresponded with the results of the ribbed geomembrane and sandy soil interface drawing experiment. The soil particle displacement near the ribbed geomembrane and sandy soil interface was larger, and the overall particles moved to the top left. The sandy soil at the top after the rib had downward movement owing to the normal stress. With an increase in temperature or decrease in rib height, the displacement of sand particles near the ribbed geomembrane and sandy soil interface increased, and the interface stability between the ribbed geomembrane and sandy soil became negligible. The contact forces on the left side of the drawing model and near the ribbed geomembrane were larger, and gradually decreased to the upper and lower sides. With an increase in rib height or a decrease in temperature, the contact force around the interface between the ribbed geomembrane and sandy soil increased. The entire process of drawing the ribbed geomembrane and sandy soil interface from macroscopic to microscopic was described.
Key words: numerical simulation; ribbed geomembrane; drawing test; displacement; contact force
GAO Junli, XU Hongfei, YUAN Chuan, CAO Wei . Numerical simulation of particle flow during a drawing test of a ribbed geomembrane and sandy soil interface under different temperatures[J]. Journal of Shanghai University, 2021 , 27(2) : 336 -346 . DOI: 10.12066/j.issn.1007-2861.2128
| [1] | Bely V, Sviridenok A, Petrokovets M. Friction and wear in polymer-based materials[J]. Tribology International, 1982,15(5):272. |
| [2] | Osswald T, Menges G. Material science of polymers for engineers[M]. 3rd Ed. Munich: Carl Hanser Verlag, 2012. |
| [3] | Irsyam M, Hryciw R D. Friction and passive resistance in soil reinforced by plane ribbed inclusions[J]. Journal of Geotechnical and Geoenvironmental Engineering, 1991,41(4):485-498. |
| [4] | 许四法, 王国才, 王哲. 温度和填埋高度引起的垃圾填埋场边坡部土工膜张拉力评价[J]. 岩土力学, 2010(10):3120-3124. |
| [4] | Xu S F, Wang G C, Wang Z. Evaluation of tensile forces of geomembrane placed on waste landfill slope due to temperature variation and filling height[J]. Rock and Soil Mechanics, 2010(10):3120-3124. |
| [5] | 景苏明. 土工格栅拉拔试验界面等效摩擦力研究[D]. 天津: 天津大学, 2014. |
| [5] | Jing S M. Study on interaction equivalent friction of geogrid pullout test[D]. Tianjin: Tianjin University, 2014. |
| [6] | 高俊丽, 张孟喜, 林永亮, 等. 加肋土工膜与砂性土界面相互作用机制分析[J]. 岩土力学, 2012,33(8):2465-2471. |
| [6] | Gao J L, Zhang M X, Lin Y L, et al. Analysis of interaction mechanism of reinforced geomembrane and sandy soil interface[J]. Rock and Soil Mechanics, 2012,33(8):2465-2471. |
| [7] | 高俊丽, 张孟喜, 张文杰. 加肋土工膜与砂土界面特性研究[J]. 岩土力学, 2011,32(11):3225-3230. |
| [7] | Gao J L, Zhang M X, Zhang W J. Interface property between sand and reinforced geomembrane[J]. Rock and Soil Mechanics, 2011,32(11):3225-3230. |
| [8] | 张孟喜, 张石磊. H-V 加筋土性状的颗粒流细观模拟[J]. 岩土工程学报, 2008(5):625-631. |
| [8] | Zhang M X, Zhang S L. Behaviour of soil reinforced with H-V inclusions by PFC$^{\rm 2D}$[L]. Chinese Journal of Geotechnical Engineering, 2008(5):625-631. |
| [9] | 周健, 池毓蔚, 池永, 等. 砂土双轴试验的颗粒流模拟[J]. 岩土工程学报, 2000(6):701-704. |
| [9] | Zhou J, Chi Y W, Chi Y, et al. Simulation of biaxial test on sand by particle flow code[J]. Chinese Journal of Geotechnical Engineering, 2000(6):701-704. |
| [10] | 郑俊杰, 苗晨曦, 张军, 等. 土工格栅与砂土接触界面细观特性离散元研究[J]. 华中科技大学学报(自然科学版), 2013,41(7):5-9. |
| [10] | Zheng J J, Miao C X, Zhang J, et al. Study on mesoscopical properties of interface between geogrid and sand by DEM[J]. Journal of Huazhong Unversity of Science and Technology (Nature Science), 2013,41(7):5-9. |
| [11] | 林永亮, 张波, 张孟喜, 等. 网格状带齿加筋体界面特性的宏细观力学机制研究[J]. 岩土力学, 2013,34(10):2863-2868. |
| [11] | Lin Y L, Zhang B, Zhang M X, et al. Micro and meso-mechanism study of interface behavior of earth reinforced with denti-inclusions[J]. Rock and Soil Mechanics, 2013,34(10):2863-2868. |
| [12] | Dyer M R. Observation of the stress distribution in crushed glass with applications to soil reinforcement[D]. Oxford: University of Oxford, 1985. |
/
| 〈 |
|
〉 |
