Dynamic Compaction of Collapsible Soils Based on U.S. Case Histories
Publication: Journal of Geotechnical and Geoenvironmental Engineering
Volume 136, Issue 9
Abstract
Dynamic compaction (DC) is an economical approach for mitigating the hazard posed by collapsible soils particularly when they are deeper than 3–4 m. In this paper, case histories are provided for 15 projects at 10 locations in the United States where collapsible soils were treated with DC. For each site the soil properties, compaction procedures, and subsequent improvement are summarized. Although cohesionless and low-plasticity collapsible soils were successfully compacted, clay layers in the profile appeared to absorb energy and severely reduced compaction effectiveness. Correlations are presented for estimating the maximum depth of improvement, the degree of improvement versus depth, the depth of craters, and the level of vibration based on measurements made at the various sites. The compactive energy per volume was typically higher than for noncollapsible soils because collapsible soils are usually loose but relatively stiff. The maximum depth of improvement was similar to that for noncollapsible soils; however, significant scatter was observed about the best-fit line. Improvement was nonuniform with nearly 80% of the total improvement occurring within the top 60% of the improvement zone. The crater depth was related to a number of factors besides the drop energy including the number of drops, drop spacing, and contact pressure. The peak particle velocities were typically lower than those for noncollapsible soils at shorter distances, but the vibrations attenuated more slowly with distance.
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Acknowledgments
The collection and analysis of some of the data in this paper was partially supported by NSF Grant No. NSFBCS-9116339 and a grant from the College of Engineering and Technology at Brigham Young University. This support is gratefully acknowledged. The writers are also grateful to Terry Yarger, Michael Hager, Mark Falk, and Jennifer Anderson, Wyoming Department of Transportation; Richard Lueck and Edward Rechter, New Mexico Department of Transportation; Joe Drumheller, Densification, Inc.; Andrew Walker, Geosystems, Inc.; Mark Burgus, Vibra-Tech, Inc.; George Sisuentes, Calif. Dept. of Corrections, Hayward-Baker, and Delta Engineering for supplying data used in this study. The conclusions and recommendations in the paper are those of the writers and do not necessarily reflect those of the sponsors or contributors.
References
CH2M-Hill. (1985a). “Geotechnical explorations for the California State Prison, Kings County Avenal.” Vol. 1 Rep. No. M18037.H1, Calif. Dept. of Corrections, Los Angeles.
CH2M-Hill. (1985b). “Dynamic deep compaction test program for the California State Prison near Avenal, Kings County, California.” Rep. No. M18037.H2, Calif. Dept. of Corrections, Los Angeles.
Lovelace, A. D., Bennet, W. T., and Lueck, R. D. (1982). “A test section for the stabilization of collapsible soils on Interstate 25.” MB-RR-83-1, New Mexico State Hwy. Dept.
Lukas, R. G. (1995). “Dynamic compaction.” Geotechnical Engineering Circular No. 1, U.S. DOT, Publication No. FHWA-SA-95-037, Federal Highway Administration, Washington, D.C.
Mayne, P. W. (1985). “Ground vibrations during dynamic compaction.” Vibration Problems in Geotechnical Engineering, ASCE, Reston, Va., 247–265.
Mayne, P. W., Jones, J. W., and Dumas, J. C. (1984). “Ground response to dynamic compaction.” J. Geotech. Engrg., 110(6), 757–774.
Menard, L., and Broise, Y. (1975). “Theoretical and practical aspects of dynamic consolidation.” Geotechnique, 25(1), 3–18.
Pengelly, A. D., Boehm, D. W., Rector, E., and Welsh, J. P. (1997). “Engineering experience with in situ modification of collapsible and expansive soils.” Unsaturated Soil Engineering Practice, Geotech. Special Pub. No. 68, ASCE, Reston, Va.
Rollins, K. M., Jorgensen, S. J., and Ross, T. (1998). “Optimum moisture content evaluation for dynamic compaction of collapsible soil.” J. Geotech. Geoenviron. Eng., 124(8), 699–708.
Rollins, K. M., and Kim, J. (1994). “U.S. experience with dynamic compaction of collapsible soils.” In Situ Deep Soil Improvement, Geotechnical Special Publication No. 45, ASCE, New York.
Rollins, K. M., Olsen, R., and Kim, J. (1999). “Deep dynamic compaction of collapsible soils.” Proc., XI Pan-American Conf. on Soil Mechanics and Geotechnical Engineering, Balkema, Rotterdam, The Netherlands, 43–50.
Rollins, K. M., and Rogers, G. W. (1994). “Mitigation measures for small structures on collapsible alluvial soils.” J. Geotech. Engrg., 120(9), 1533–1553.
Siskind, D. E., Stagg, M. S., Kopp, J. W., and Dowding, C. H. (1980). “Structure response and damage produced by ground vibrations from surface blasting.” Report of Inverstigations 8507, U.S. Bureau of Mines, Washington, D.C.
Slocombe, B. C. (1993). “Chapter 2: Dynamic compaction.” Ground improvement, M. P. Moseley, ed., CRC, Boca Raton, Fla., 21–39.
Yarger, T. L. (1986). “Dynamic compaction of loose and hydrocompactible soils on Interstate 90 Whitehall-Cardwell, Montana.” Transportation Research Record. 1089, Transportation Research Board, Washington, D.C.
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Information
Published In
Journal of Geotechnical and Geoenvironmental Engineering
Volume 136 • Issue 9 • September 2010
Pages: 1178 - 1186
Copyright
© 2010 ASCE.
History
Received: Jun 22, 2009
Accepted: Jan 28, 2010
Published online: Jan 30, 2010
Published in print: Sep 2010
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