Wave Propagation in a Pipe Pile for Low-Strain Integrity Testing
Publication: Journal of Engineering Mechanics
Volume 137, Issue 9
Abstract
This paper presents an analytical solution methodology for a tubular structure subjected to a transient point loading in low-strain integrity testing. The three-dimensional effects on the pile head and the applicability of plane-section assumption are the main problems in low-strain integrity testing on a large-diameter tubular structure, such as a pipe pile. The propagation of stress waves in a tubular structure cannot be expressed by one-dimensional wave theory on the basis of plane-section assumption. This paper establishes the computational model of a large-diameter tubular structure with a variable wave impedance section, where the soil resistance is simulated by the Winkler model, and the exciting force is simulated with semisinusoidal impulse. The defects are classified into the change in the wall thickness and Young’s modulus. Combining the boundary and initial conditions, a frequency-domain analytical solution of a three-dimensional wave equation is deduced from the Fourier transform method and the separation of variables methods. On the basis of the frequency-domain analytic solution, the time-domain response is obtained from the inverse Fourier transform method. The three-dimensional finite-element models are used to verify the validity of analytical solutions for both an intact and a defective pipe pile. The analytical solutions obtained from frequency domain are compared with the finite-element method (FEM) results on both pipe piles in this paper, including the velocity time history, peak value, incident time arrival, and reflected wave crests. A case study is shown and the characteristics of velocity response time history on the top of an intact and a defective pile are investigated. The comparisons show that the analytical solution derived in this paper is reliable for application in the integrity testing on a tubular structure.
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Acknowledgments
The financial support of the National Nature Science Foundation of China under Contract No. NNSFC51008115 and the Provincial Science Foundation of Jiangsu, China, under Contract No. UNSPECIFIEDBK2008040 are gratefully acknowledged.
References
Chen, F., and Luo, W. Z. (2004). “Dimension effect on low strain integrity testing of prestressed pipe piles.” Chin. J. Geotech. Eng., 26(3), 353–356.
Chow, Y. K., Phoon, K. K., Chow, W. F., and Wong, K. Y. (2003). “Low strain integrity testing of piles: Three-dimensional effects.” J. Geotech. Geoenviron. Eng., 129(11), 1057–1062.
Gazis, D. C. (1959a). “Three-dimensional investigation of the propagation of waves in hollow circular cylinders: I. Analytical foundation.” J. Acoust. Soc. Am., 31(5), 568–573.
Gazis, D. C. (1959b). “Three-dimensional investigation of the propagation of waves in hollow circular cylinders: II. Numerical results.” J. Acoust. Soc. Am., 31(5), 573–578.
Goble, G. G., and Hery, P. (1984). “Influence of residual forces on pile driveability.” Proc. 2nd Int. Conf. of the Application of Stress-Wave Theory on Piles, Swedish Pile Commission, Stockholm, Sweden, 154–161.
Goble, G. G., Likins, G. E., and Rausche, F. (1975). Bearing capacity of piles from dynamic measurements—Final Rep., Dept. of Civil Engineering, Case Western Reserve Univ., Cleveland, 41–45.
Han, Y. C. (1997). “Dynamic vertical response of piles in nonlinear soil.” J. Geotech. Geoenviron. Eng., 123(8), 710–716.
Likins, G. E., and Rausche, F. (2000). “Recent advances and proper use of PDI low strain pile integrity testing.” Proc. 6th Int. Conf. on the Application of Stress-Wave Theory to Piles, CRC Press, 211–218.
Liu, H. L., Chu, J., and Deng, A. (2009). “Use of large-diameter, cast-in situ concrete pipe piles for embankment over soft clay.” Can. Geotech. J., 46(8), 915–927.
Liu, H. L., Fei, K., and Xu, X. T. (2005). “Development and application of the large-diameter driven cast-in-place concrete thin-wall pipe pile.” Proc. 16th Int. Conf. on Soil Mechanics and Geotechnical Engineering, IOS Press, Amsterdam, Netherlands, 2137–2140.
Liu, H. L., Ng, C. W. W., and Fei, K. (2007). “Performance of a geogrid-reinforced and pile-supported highway embankment over soft clays: A case study.” J. Geotech. Geoenviron. Eng., 133(12), 1483–1493.
Massoudi, N., and Teffera, W. (2004). “Non-destructive testing of piles using the low strain integrity method.” Proc. 5th Int. Conf. on Case Histories in Geotechnical Engineering, Missouri Univ. of Science and Technology, Rolla, MO, 13–17.
Militano, G., and Rajapakse, R. K. N. D. (1999). “Dynamic response of a pile in a multi-layered soil to transient torsional and axial loading.” Geotechnique, 49(1), 91–109.
Morgano, C. M. (1996). “Determining embedment depths of deep foundations using non-destructive methods.” Proc. 5th Int. Conf. on the Application of Stress-Wave Theory to Piles, Univ. of Florida, Orlando, FL, 734–747.
Novak, M., and Beredugo, Y. O. (1972). “Vertical vibration of embedded footings.” J. Soil Mech. and Found. Div., 98(12), 1291–1310.
Novak, M., Nogami, T., and Aboul-Ella, F. (1978). “Dynamics soil reactions for plane strain case.” J. Engrg. Mech. Div., 104(EM4), 953–959.
Rausche, F. (1970). “Soil response from dynamic analysis and measurement on piles.” Ph.D. dissertation, Div. of Solid Mechanics, Structures and Mechanical Design, Case Western Reserve Univ., Cleveland.
Rausche, F. (1972). “Soil resistance prediction from pile dynamics.” J. Soil Mech. and Found. Div., 98(9), 917–937.
Rausche, F., Goble, G. G., and Likins, G. E. (1992). “Investigation of dynamic soil resistance on piles using GRLWEAP.” Proc. 4th Int. Conf. on the Application of Stress-Wave Theory to Piles, CRC Press, 137–142.
Smith, E. A. L. (1960). “Pile driving analysis by the wave equation.” J. Soil Mech. and Found. Div., 86(4), 35–64.
Xu, X. T., Liu, H. L., and Lehane, B. M. (2006). “Pipe pile installation effects in soft clay.” Geotech. Eng., 159(4), 285–296.
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© 2011 American Society of Civil Engineers.
History
Received: Dec 26, 2009
Accepted: Mar 11, 2011
Published online: Mar 14, 2011
Published in print: Sep 1, 2011
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