Pullout Test Research on Interfacial Interaction of Reinforced Band and Gravelly Soil

Yan Li Wang; Zhan Lin Cheng; Wei Zhang; Yong Zhen Zuo; Zhen Lin Yu; Yong Wang

doi:10.4028/www.scientific.net/AMM.580-583.684

Paper Titles

Numerical Simulation of Failure Process on Soil Slope with Different Support Measures
p.665

Prediction of Composite Foundation Settlement Based on Multi-Variable Gray Model
p.669

Preparation of a New Type of Joint Filler and Study on Adhesion Performance
p.674

Probability Statistical Model and Network Simulation Technology of Random Fractured Rock Mass
p.679

Pullout Test Research on Interfacial Interaction of Reinforced Band and Gravelly Soil
p.684

Research of Soundless Crack with Different Number of Drillholes
p.689

Research on Negative Skin Friction on Pile by a Simple Model Experiment
p.693

Research on Stability of Foundation Pit Construction
p.697

Research on the Effect of One Debris Flow along Bailong River
p.701

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 580-583Pullout Test Research on Interfacial Interaction...

Pullout Test Research on Interfacial Interaction of Reinforced Band and Gravelly Soil

Abstract:

Taking steel-plastic composite reinforced band (CAT) and gravelly soil as the test materials, the pullout tests of reinforced band in gravelly soil with different water contents have been carried out by the laminated shear test instrument. The interface friction characteristics between reinforced band and gravelly soil are studied, and the influences of water content on the interaction characteristics are also discussed. Results show that (1) the extraction of reinforced band is a gradual process. The anchor end began to move firstly because of the extensibility of reinforced belt itself. As interface friction gradually transfer backward by, the free end start to move onward, then displacement schedule curves of the anchor end and the free end are gradually parallel, the whole movement of reinforced belt happens immediately. (2) Pulling force and displacement curve of the pullout friction test displays obviously nonlinear characteristics. Pulling force of the reinforced band increases greatly with increasing displacement at the beginning of the test, then decrease with the increasing displacement after the peak value is reached, the force-displacement curves generally exhibit strain soften characteristics. But it present strain hardening trend under greater normal stress, and pullout frictional strength increases with the increasing normal stress. (3) The pullout friction coefficient of the interface is sensitive to water content. It decreases linearly with the increasing water content.

You might also be interested in these eBooks

Advances in Civil and Industrial Engineering IV

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 580-583)

Pages:

684-688

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.580-583.684

Citation:

Cite this paper

Online since:

July 2014

Authors:

Yan Li Wang*, Zhan Lin Cheng, Wei Zhang, Yong Zhen Zuo, Zhen Lin Yu, Yong Wang

Keywords:

Interfacial Interaction, Pull-Out Test, Reinforced Band, Water Content

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Shi, D.D., Liu W.B., Shui, W.H., et al. Comparative experimental studies of interface characteristics between uniaxial/biaxial plastic geogrids and different soils., Rock and Soi1 Mechanics, Vol. 30 (2009), pp.2237-2244.

Google Scholar

[2] Ochiai, H., Otani, J. and Hayashic, S. E. A. The pull-out resistance of geogrids in reinforced soil., Geotextiles and Geomenbranes, Vol. 14 (1996), pp.19-42.

DOI: 10.1016/0266-1144(96)00027-1

Google Scholar

[3] Marc, J., Good, H., Tuncer, B., et a1. Interaction of Foundry Sands with Geosynthetics., J. Geotechnical & Geoenv. Engrg., ASCE, Vol. 127 (2001), pp.353-362.

Google Scholar

[4] Sugimoto, M. and Alagiyawanna, A. Pullout behavior of geogrid by test and numerical analysis., Journal of Geotechnical and Geoenvironmental Engineering, Vol. 129 (2003), pp.361-371.

DOI: 10.1061/(asce)1090-0241(2003)129:4(361)

Google Scholar

[5] Fleming, I. R., Sharma, J. S. and Jogi, M. B. Shear strength of geomembrane-soil interface under unsaturated conditions., Geotextiles and Geomenbranes, Vol. 24 (2006), pp.274-284.

DOI: 10.1016/j.geotexmem.2006.03.009

Google Scholar

[6] Mocraci, N. and Recalcati, P. Factors afecting the pullout behaviour of extruded geogrids embedded in a compacted granular soil., Geotextiles and Geomenbranes, Vol. 24 (2006), pp.220-242.

DOI: 10.1016/j.geotexmem.2006.03.001

Google Scholar

[7] Zhang, W.H., Wang, B.T., Zhang, F.H., et al. Test study on interaction characteristics between two-way geogrids and clay., Rock and Soil Mechanics, Vol. 28(2007, pp.1031-1033.

Google Scholar

[8] Yang, G.Q. and Sui, C.Y. Experimental Research on Interface Friction Characteristics of Geogrids and Soil., Journal of Shijiazhuang Tidao Nniversity (Natural Science), Vol. 23 (2010), pp.46-52.

Google Scholar

[9] Wang, M.Y., Bao, C.G., Ding, J.H., et al. Effect of some test conditions on pull-out behaviors of interface between geogrids and compacted expansive soils., Rock and Soil Mechanics, Vol. 29 (2008), pp.442-448.

Google Scholar