Performance of Long-Driven H-Piles in Granitic Saprolite
Publication: Journal of Geotechnical and Geoenvironmental Engineering
Volume 135, Issue 2
Abstract
There has been much advancement using conceptual models and analytical methods to explain various aspects of pile performance. They are mainly based on the findings of model tests and full-scale pile tests in fine-grained and coarse-grained soils, and driven piles on land are normally less than . Design methods developed from this data bank of pile geometries and soil conditions for long piles should be treated with caution. In this paper, 13 -piles of and capacity founded on granitic saprolite are studied. Among them, two piles were restriked at different time intervals. All piles were axially load tested statically using a maintained load method. In contrast to the short rigid piles founded on weaker soil, their load-transfer mechanism varied with the magnitude of applied load and pile length. They deformed almost linearly at small loads and might have buckled when the loads were large and the creep settlements were found to be length dependent. Existing criteria might not be able to interpret failure loads sometimes, but a pile dynamic analyzer was found to give the best estimate on pile capacity.
Get full access to this article
View all available purchase options and get full access to this article.
Acknowledgments
The writers would like to express their gratitude to the Hong Kong Housing Authority for its sincere kindness in permitting the writers to use the raw field data.
References
Axelsson, G. (2000). “Long-term set-up of driven piles in sand.” Ph.D. thesis, Division of Soil and Rock Mechanics, Dept. of Civil and Environmental Engineering, Royal Institute of Technology, Stockholm, Sweden.
BD. (2004a). “Code of practice for foundations.” Buildings Dept., Hong Kong Government.
BD. (2004b). “PNAP 66—Piled foundations.” Practice notes for authorized persons and registered structural engineers, Buildings Dept., Hong Kong Government.
BD. (2005). “Code of practice for structural use of steel.” Buildings Dept., Hong Kong Government.
Bowman, E. T., and Soga, K. (2005). “Mechanisms of setup of displacement piles in sand: Laboratory creep tests.” Can. Geotech. J., 42(5), 1391–1407.
Brinch Hansen, J. (1963). “Discussion on hyperbolic stress-strain response: Cohesive soils.” J. Soil Mech. and Found. Div., 89(4), 241–242.
BSI. (1986). “British standard code of practice for foundations.” BS8004, British Standard Institute.
Butler, H. D., and Hoy, H. E. (1977). Users manual for the Texas quick-load method for foundation load testing, Federal Highway Administration, Washington, D.C.
Chin, F. K. (1970). “Estimation of the ultimate load of piles not carried to failure.” Proc., of the Second Southeast Asian Conf. on Soil Engineering, 81–90.
Cho, C. W., Lee, M. W., and Randolph, M. F. (2000). “Set-up considerations in wave equation analysis of pile driving.” Proc., Sixth Int. Conf. on the Application of Stress Wave Theory to Piles, 41–46.
Davisson, M. T. (1972). “High capacity piles.” Proc., ASCE Lecture Series, Innovations in Foundation Construction, Illinois Section, 81–112.
De Beer, E. E. (1967). “Proefondervindelijke bijdrage tot de studie van het grensdraag vermogen van zand onder funderingen op staal.” Tijdshrift der Openbar Werken van Belgie, No. 6.
FDOT. (1999). Standard specification for road and bridge construction, Florida Dept. of Transportation, Tallahassee, Fla., 398–451.
Fuller, F. M., and Hoy, H. E. (1970). “Pile load tests including quick-load test method, conventional methods and interpretations.” Highw. Res. Rec., 333, 74–86.
GEO. (1988). “Geoguide 3: Guide to rock and soil descriptions.” Geotechnical Engineering Office, Civil Engineering Dept., Hong Kong Government.
GEO. (1993). Geoguide 1: Guide to retaining wall design, 2nd ed., Geotechnical Engineering Office, Civil Engineering Dept., Hong Kong Government.
GEO. (2006). “Foundation design and construction.” Geotechnical Engineering Office, Civil Engineering Dept., Hong Kong Government.
Hiley, A. (1925). “Rational pile driving formula and its application in piling practice explained.” Engineering (London), 657.
HKCA. (1994). “Report on hydraulic hammers performance.” Hong Kong Construction Association.
HKCA. (2004). “Use of hydraulic hammer for driven piles.” Hong Kong Construction Association.
HKG. (1992). “General specification for civil engineering works.” Hong Kong Government.
HKG. (1997). “CAP 123B—Building (construction) regulations.” Chap. 123, Buildings Ordinance (and Building Regulations), Laws of Hong Kong, Hong Kong Government.
Jardine, R. J., and Chow, F. C. (1996). “New design methods for offshore piles.” MTD Publication 96/103, Marine Technology Directorate, London.
Jardine, R. J., Chow, F. C., Overy, R. F., and Standing, J. R. (2005). ICP design methods for driven piles in sands and clays, Imperial College, Thomas Telford.
Jardine, R. J., Standing, J. R., and Chow, F. C. (2006). “Some observations of the effects of time on the capacity of piles driven in sand.” Geotechnique, 56(4), 227–244.
Kuln, M. R., and Mitchell, J. K. (1993). “New perspectives on soil creep.” J. Geotech. Engrg., 119(3), 507–524.
Lehane, B. M., and Jardine, R. J. (1994). “Displacement-pile behaviour in a soft marine clay.” Can. Geotech. J., 31(2), 181–191.
Lehane, M. B., Jardine, R. J., Bond, A. J., and Frank, R. (1993). “Mechanisms of shaft friction in sand from instrumented pile tests.” J. Geotech. Engrg., 119(1), 19–25.
Lehane, M. B., and White, D. J. (2005). “Lateral stress changes and shaft friction for model displacement piles in sand.” Can. Geotech. J., 42(4), 1039–1052.
Mejia, C. A., Vaid, Y. P., and Negussey, D. (1988). “Time dependent behaviour of sand.” Proc., Int. Conf. on Rheology and Soil Mechanics, 312–326.
Mesri, G., and Vardhanabhuti, B. (2005). “Secondary compression.” J. Geotech. Geoenviron. Eng., 131(3), 398–401.
Poulos, H. G., and Davis, E. H. (1980). Pile foundation analysis and design, Wiley, New York.
Randolph, M. F. (1983). “Design considerations for offshore piles.” Proc., Conf. on Geotechnical Practice in Offshore Engineering, 422–439.
Randolph, M. F. (2003). “Science and empiricism in pile foundation design.” Geotechnique, 53(10), 847–875.
Skov, R., and Denver, H. (1988). “Time-dependence of bearing capacity of piles.” Proc., Third Int. Conf. on the Application of Stress Wave Theories to Piles, 879–888.
Svinkin, M. R., Morgano, C. M., and Morvant, M. (1994). “Pile capacity as a function of time in clayey and sandy soils.” Proc., Fifth Int. Conf. and Exhibition on Piling and Deep Foundations, 1.11.1–1.11.8.
Svinkin, M. R., and Skov, R. (2000). “Set-up effect of cohesive soils in pile capacity.” Proc., Sixth Int. Conf. on the Application of Stress Wave Theory to Piles, 107–111.
Tan, S. B. (1971). “An empirical method for estimating secondary and total settlement.” Proc., Fourth Asian Regional Conf. on Soil Mechanics and Foundation Engineering, 147–151.
Triantafyllidis, T. (2001). “On the Application of the hiley formula in driving long piles.” Geotechnique, 51(10), 891–895.
Wang, Y. H., and Yan, W. M. (2006). “Laboratory studies of two common saprolitic soils in Hong Kong.” J. Geotech. Geoenviron. Eng., 132(7), 923–930.
White, D. J., and Bolton, M. D. (2002). “Observing friction fatigue on a jacked pile.” Centrifuge and constitutive modelling: Two extremes, S. M. Springman, eds., Swets and Zeitlinger, Rotterdam, The Netherlands, 347–354.
Information & Authors
Information
Published In
Journal of Geotechnical and Geoenvironmental Engineering
Volume 135 • Issue 2 • February 2009
Pages: 246 - 258
Copyright
© 2009 ASCE.
History
Received: Aug 4, 2007
Accepted: Mar 28, 2008
Published online: Feb 1, 2009
Published in print: Feb 2009
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.