Comparative Analysis of Pile Driving Numerical Modeling Approaches
Publication: IFCEE 2021
ABSTRACT
Driven piles have been commonly used as a suitable deep foundation alternative to the soil conditions in Central Florida. Pile driving is a complex dynamic soil-structure interaction problem that induces vibrations and settlements in the surrounding soils. Numerical models need to be capable of accurately simulating pile dynamics so that the response of soil during the pile installation can be properly assessed. In this paper, numerical analyses were conducted using the finite element platform PLAXIS 2D to compare different modeling approaches used in the technical literature (i.e., continuous versus discontinuous) for the pile driving process. A parametric study was performed to elucidate the role of plastic zones in the process of pile penetration. The constitutive soil model used was the hardening soil model enhanced with small strains (i.e., HS small). Subsurface conditions were determined using laboratory and field-testing data collected from a project site. Input parameters were estimated from subsurface exploration data and processed using GRLWEAP, which is a wave equation analysis program. The concept of a plastic zone with reduced stiffness and strength was introduced around the pile to model the continuous process of pile installation. Based on the results, a continuous pile driving approach matched well with field measurements and provided better insight into the pile-dynamic behavior than a discontinuous modeling approach based on a single blow at various depths. The continuous and discontinuous numerical modeling approaches are compared and discussed associated with pile penetration and velocities at the top of the pile.
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REFERENCES
Brinkgreve, R. B. J., Engin, E., and Engin, H. K. (2010). “Validation of Empirical Formulas to Derive Model Parameters for Sands”. Numerical Methods in Geotechnical Engineering, 137-142.
Farshi Homayoun Rooz, A., and Hamidi, A. (2017). “Numerical Analysis of Factors Affecting Ground Vibrations due to Continous Impact Pile Driving”. International Journal of Geomechanics, 17(12), 1-15.
Grizi, A., Athanasopoulus-Zekkos, A., and Woods, R. D. (2018). “H-Pile Driving Induced Vibrations: Reduced-Scale Laboratory Testing and Numerical Analysis”. Proc., IFCEE 2018: Advances in Geomaterial Modeling and Site Characterization, 165-175.
Hudson, M., Idriss, I., and Beikae, M. (1994). QUAD4M: A Computer Program to Evaluate the Seismic Response of Soil Structures Using Finite Element Procedures and Incorporating a Compliant Base. Davis, California: Center for Geotechnical Modeling Dept. of Civil and Environmental Engineering University of California Davis.
Khoubani, A., and Ahmadi, M. M. (2014). “Numerical Study of Ground Vibration Due to Impact Pile Driving”. Proc., of the ICE - Geotechnical Engineering, 167(1), 28-39.
Kulhawy, F. H., and Mayne, P. W. (1990). Manual on Estimating Soil Properties for Foundation Design. Ithaca, NY: Cornell University.
Likitlersuang, S., Teachavorasinskun, S., Surarak, C., Oh, E., and Balasubramaniam, A. (2013). “Small Strain stiffness and Stiffness Degradation Curve of Bangkok Clays”. Journal of Soils and Foundations, 53(4), 498-509.
Mabsout, M. E., Reese, L. C., and Tassoulas, J. L. (1995). “Study of Pile Driving by Finite-Element Method”. Journal of Geotechnical Engineering, 121(7), 535-543.
Obrzud, R. F. (2010). “On the Use of the Hardening Soil Small Strain Model in Geotechnical Practice”. Proc., Numerics in Geotechnics and Structures, 16.
Pile Dynamics, Inc. (2000). CAPWAP for Windows Manual Version 2000-1. Renaissance Parkway, Cleveland, Ohio: <www.pile.com> (Jul.14, 2020).
Pile Dynamics, Inc. (2003). GRLWEAP Procedures and Models Version 2003. Renaissance Parkway, Cleveland, Ohio: <www.pile.com> (Jul.14, 2020).
Smith, E. A. (1960). “Pile-Driving Analysis by the Wave Equation”. J. Soil Mech. and Found. Div., 86(4), 35-61.
Surarak, C., Likitlersuang, S., Wanatowski, D., Balasubramaniam, A., Oh, E., and Guan, H. (2012). “Stiffness and Strength Parameters for Hardening Soil Model of Soft and Stiff Bangkok Clays”. Journal of Soils and Foundations, 52(4), 682-697.
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IFCEE 2021
Pages: 484 - 495
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© 2021 American Society of Civil Engineers.
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Published online: May 6, 2021
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