Lateral Spreading Forces on Bridge Piers and Pile Caps in Laterally Spreading Soil: Effect of Angle of Incidence
Publication: Journal of Geotechnical and Geoenvironmental Engineering
Volume 136, Issue 12
Abstract
In this paper, the kinematic forces which may be applied to bridge piers or pile caps from laterally spreading surficial cohesive soil layers (nonliquefied crusts) through which they pass are considered. Such forces often represent the largest load component acting on a structure and/or foundation during liquefaction-induced lateral spreading. Both circular and square structural inclusions are considered, and particular attention is paid to the orientation of the inclusion to the direction of spreading, here defined as the angle of incidence . Experimental modeling was conducted using a modified direct shearbox to simulate the spreading of kaolin past structural inclusions at various . Load-displacement data and particle image velocimetry analysis revealed that the ultimate load for both square and circular cases may be determined using a wedge-based upper-bound plasticity analysis. For circular sections, this ultimate load is independent of due to radial symmetry. The ultimate load on square sections was found to depend more significantly on and a simple analytical method is presented to account for this. The method suggests that the ultimate loads acting on square bridge piers or pile caps will be a maximum when the spreading soil impinges on the corners of the inclusion, at which time the ultimate load will be 19–26% larger (depending on the soil-structure interface roughness) than for spreading impinging on the edge of the inclusion. Experimental tests suggested a value of 22%. Finally, the tests support previous results suggesting that when the underlying soil is unable to carry redistributed shear stress (i.e., when it is liquefied) load-displacement curves in the crustal layers are less stiff than for typical retaining structures under static conditions. The displacement at soil yield was found to be between 20–30% of the height of the inclusion in the layer, and also depends on in the case of square inclusions.
Get full access to this article
View all available purchase options and get full access to this article.
Acknowledgments
The writers would like to sincerely thank Ernie Kuperus and the technical staff of the Division of Civil Engineering for their assistance in modifying the testing apparatus, and acknowledge the support of the British Council, U.K. and the University of Dundee for supporting the second writer’s summer internship to the University of Dundee.
References
Brandenberg, S. J., Boulanger, R. W., Kutter, B. L., and Chang, D. (2005). “Behaviour of pile foundations in laterally spreading ground during centrifuge tests.” J. Geotech. Geoenviron. Eng., 131(11), 1378–1391.
Brandenberg, S. J., Boulanger, R. W., Kutter, B. L., and Chang, D. (2007). “Liquefaction-induced softening of load transfer between pile groups and laterally spreading crusts.” J. Geotech. Geoenviron. Eng., 133(1), 91–103.
Brandenberg, S. J., Boulanger, R. W., Kutter, B. L., Wilson, D. W., and Chang, D. (2004). “Load transfer between pile groups and laterally spreading ground during earthquakes.” Proc., 13th World Conf. on Earthquake Engineering (CD-ROM), Mira Digital Publishing, St. Louis, Paper No. 1516.
Dobry, R., Abdoun, T., O’Rourke, T. D., and Goh, S. H. (2003). “Single piles in lateral spreads: field bending moment evaluation.” J. Geotech. Geoenviron. Eng., 129(10), 879–889.
Earthquake Engineering Field Investigation Team (EEFIT). (2007). “The Ji-Ji, Taiwan Earthquake of 21 September 1999.” Short Rep. Prepared for Institution of Structural Engineers, London.
Hamada, M. (1992). “Large ground deformations and their effects on lifelines: 1964 Niigata earthquake.” Technical Rep. No. NCEER-92-001, National Centre for Earthquake Engineering Research, Univ. of Buffalo, New York, 3-1–3-123.
Klar, A., and Randolph, M. F. (2008). “Upper-bound and load-displacement solutions for laterally loaded piles in clays based on energy minimisation.” Geotechnique, 58(10), 815–820.
Kokusho, T. (1999). “Water film in liquefied sand and its effects on lateral spread.” J. Geotech. Eng., 125(10), 817–826.
Malvick, E. J., Kutter, B. L., Boulanger, R. W., and Kulasingam, R. (2006). “Shear localization due to liquefaction-induced void redistribution in a layered infinite slope.” J. Geotech. Geoenviron. Eng., 132(10), 1293–1303.
Martin, C. M., and Randolph, M. F. (2006). “Upper-bound analysis of lateral pile capacity in cohesive soil.” Geotechnique, 56(2), 141–145.
Matlock, H. (1970). “Correlations of design of laterally loaded piles in soft clay.” Proc., Offshore Technology Conf., Vol. 1, Houston, 577–594.
Murff, J. D., and Hamilton, J. M. (1993). “P-ultimate for undrained analysis of laterally loaded piles.” J. Geotech. Eng., 119(1), 91–107.
Poulos, H. G., and Davis, E. H. (1980). Pile foundation analysis and design, Wiley, New York.
Randolph, M. F., and Houlsby, G. T. (1984). “The limiting pressure on a circular pile loaded laterally in cohesive soil.” Geotechnique, 34(4), 613–623.
Terzaghi, K. (1936). “A fundamental fallacy in earth pressure computations.” J. Boston Soc. Civ. Eng., 23, 71–88.
White, D. J., Take, W. A., and Bolton, M. D. (2003). “Soil deformation measurement using particle image velocimetry (PIV) and photogrammetry.” Geotechnique, 53(7), 619–631.
Information & Authors
Information
Published In
Copyright
© 2010 ASCE.
History
Received: Jul 29, 2009
Accepted: May 5, 2010
Published online: May 12, 2010
Published in print: Dec 2010
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.