Peak Friction Behavior of Smooth Geomembrane-Particle Interfaces
Publication: Journal of Geotechnical and Geoenvironmental Engineering
Volume 125, Issue 7
Abstract
An investigation of shear mechanisms at interfaces between particles and relatively smooth materials using contact mechanics and basic friction theory reveals that a combination of sliding and plowing governs dense Ottawa 20/30 sand/smooth high density polyethylene geomembrane peak interface shear behavior. Contact area and the corresponding shear resistance during sliding increase at a slower rate than the applied normal stress, resulting in a decreasing friction coefficient and flattening of the peak strength envelope. Plowing of soil grains results in an increasing peak friction coefficient with increasing normal stress and can produce an upward curvature of the strength envelope above a critical stress level. Plowing is primarily controlled by the relative hardness of the interface materials and by grain shape with angular particles exhibiting plowing in all normal stress ranges, whereas nearly perfect spheres exhibit only sliding. High surface hardness is shown to constrain shear behavior to a sliding mode with little contribution from plowing. These findings are consistent with results reported in the tribology literature.
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References
1.
Adams M. J. ( 1992). “Friction of granular non-metals.” Fundamentals of friction: Macroscopic and microscopic processes, I. L. Singler and H. M. Pollock, eds., Kluwer, Dordrecht, The Netherlands, 183–207.
2.
Adamson, A. W. (1982). Physical chemistry of surfaces. Wiley, New York.
3.
Archard, J. F. (1957). “Elastic deformation and the laws of friction.” Proc., Royal Soc. of London, Ser. A, 243, Royal Society of London, 190–205.
4.
Beer, F. P., and Johnson, E. R. (1981). Mechanics of materials. McGraw-Hill, New York.
5.
Bowden, F. P., and Tabor, D. (1956). Friction and lubrication. Methuen, London.
6.
Briscoe, B. J. (1992). “Friction of organic polymers.” Fundamentals of friction: Macroscopic and microscopic processes, I. L. Singler and H. M. Pollock, eds., Kluwer, Dordrecht, The Netherlands, 167–182.
7.
Childs, T. H. C. (1992). “Deformation and flow of metals in sliding friction.” Fundamentals of friction: Macroscopic and microscopic processes, I. L. Singler and H. M. Pollock, eds., Kluwer, Dordrecht, The Netherlands, 209–225.
8.
Czichos, H. ( 1985). “Importance of properties of solids to friction and wear behavior.” New directions in lubrication, materials, wear, and surface interactions—Tribology in the 80s, W. R. Loomis, ed., Noyes, Park Ridge, N.J., 68–103.
9.
Derjaguin B. V., Muller, V. M., and Toporov, Y. P. (1975). “Effect of contact deformations on the adhesion of particles.” J. Colloid and Interface Sci., 67, 378–326.
10.
Dove, J. E. ( 1996). “Particle-geomembrane interface strength behavior as influenced by surface topography,” PhD dissertation, School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta.
11.
Dove, J. E., and Frost, J. D. (1996). “A method for measuring geomembrane surface roughness.” Geosynthetics Int., 3(3), 369–392.
12.
Dove, J. E., Frost, J. D., Han, J., and Bachus, R. C. (1997). “The influence of geomembrane surface roughness on interface strength.” Proc., Geosynthetics '97, 2, Industrial Fabrics Association International, Roseville, Minn., 863–876.
13.
Dove, J. E., and Harpring, J. C. (1999). “Geometric and spatial parameters for analysis of geomembrane/soil interface behavior.” Proc., Geosynthetics '99, Industrial Fabrics Association International, Roseville, Minn., in press.
14.
“Dura-Seal HD geomembrane specifications—40 mil (1.0 mm).” (1996). National Seal Company, Gailsburg, Ill.
15.
Greenwood, J. A., and Williamson, J. B. P. (1966). “Contact of nominally flat surfaces.” Proc., Royal Soc. of London, Ser. A, 295, Royal Society of London, 300–319.
16.
Han, J. ( 1997). “Mechanical behavior of fiber reinforced polymeric piles in sand,” PhD dissertation, School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta.
17.
Hryciw, R. D., and Irsyam, M. (1993). “Behavior of sand particles around rigid ribbed inclusions during shear.” Soils and Found., 33(3), 1–13.
18.
Johnson, K. L. (1982). “One hundred years of hertz contact.” Proc., Instn. of Mech. Engrs., 196, Institution of Mechanical Engineers, London, 363–378.
19.
Johnson, K. L. ( 1992). “Introduction to contact mechanics—A summary of principle formulae.” Fundamentals of friction: Macroscopic and microscopic processes, I. L. Singler and H. M. Pollock, eds., Kluwer, Dordrecht, The Netherlands, 589–603.
20.
Johnson, K. L., Kendall, K., and Roberts, A. D. (1971). “Surface energy and the contact of elastic solids.” Proc., Royal Soc. of London, Ser. A, 324, Royal Society of London, 301–313.
21.
Lee, S.-W. ( 1998). “Influence of surface topography on interface strength and counterface soil structure,” PhD dissertation, School of Civil and Environmental Engineering, Georgia Institute of Technology, Atlanta.
22.
Ludema, K. C. (1996). Friction, wear and lubrication. CRC Press, Boca Raton, Fla.
23.
Luellen, J. R., Dove, J. E., and Swan, R. H. (1999). “Seismic engineering for interfaces in a landfill containment system.” Geotech. Fabrics Rep., 17(1), Industrial Fabrics Association International, Roseville, Minn.
24.
Mindlin, R. D. (1949). “Compliance of elastic bodies in contact.” J. Appl. Mech., 16, 259–268.
25.
O'Rourke, T. D., Druschel, S. J., and Netravali, A. N. (1990). “Shear strength characteristics of sand-polymer interfaces.”J. Geotech. Engrg., ASCE, 116(3), 451–469.
26.
Paikowsky, S. G., Player, C. P., and Connors, P. J. (1995). “A dual interface apparatus for testing unrestricted friction of soil along solid surfaces.” Geotech. Testing J., 18(2), 168–193.
27.
Poon, C. Y., and Sayles, R. S. (1992). “The classification of rough surface contacts in relation to tribology.” J. Phys. D: Appl. Phys., 25, A249–A256.
28.
Rubin, I. I. (1990). Handbook of plastic materials and technology. Wiley, New York.
29.
Shooter K. V. (1951). “Frictional properties of plastics.” Proc., Royal Soc. of London, Ser. A, 212, Royal Society of London, 488–491.
30.
Shooter, K. V., and Tabor, D. (1952). “The frictional properties of plastics.” Proc., Phys. Soc., Ser. B, 65, 661–671.
31.
Stachowiak, G. W., and Batchelor, A. W. (1993). Engineering tribology. Elsevier Science, Amsterdam.
32.
Tuzun, U., Adams, M. J., and Briscoe, B. J. (1988). “An interface dilation model for the prediction of wall friction in a particulate bed.” Chemical Engrg. Sci., 43(5), 1083–1098.
33.
Tuzun, U., and Walton, O. R. (1992). “Micromechanical modeling of load-dependent friction in contacts of elastic spheres.” J. Appl. Phys., 25, A44–A52.
34.
Underwood, E. E. (1981). Quantitative stereology. Ervin E. Underwood, Marietta, Ga.
35.
Williams, N. D., and Houlihan, M. F. (1987). “Evaluation of interface friction properties between geosynthetics and soils.” Proc., Geosynthetics '87, Industrial Fabrics Association International, Roseville, Minn., 616–627.
36.
Yoshimi, Y., and Kishida, T. (1982). “A ring torsion apparatus for evaluating friction between soil and metal surfaces.” Geotech. Testing J., 4, 145–152.
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Published online: Jul 1, 1999
Published in print: Jul 1999
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