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Load Testing of a Closed-Ended Pipe Pile Driven in Multilayered Soil |
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| Authors: | Daehyeon Kim Adriano Virgilio Damiani Bica Rodrigo Salgado Monica Prezzi Wonje Lee |
| Affiliation: | 1Assistant Professor, Department of Civil Engineering, Chosun Univ., Gwangju 501-759, Korea (corresponding author). E-mail: dkimgeo@chosun.ac.kr 2Visiting Professor, School of Civil Engineering, Purdue Univ., West Lafayette, IN 47907-2051. E-mail: abica@purdue.edu 3Professor, School of Civil Engineering, Purdue Univ., West Lafayette, IN 47907-2051. E-mail: rodrigo@purdue.edu 4Associate Professor, School of Civil Engineering, Purdue Univ., West Lafayette, IN 47907-2051. E-mail: mprezzi@purdue.edu 5Postdoctoral Fellow, School of Civil Engineering, Purdue Univ., West Lafayette, IN 47907-2051. E-mail: lee114@ecn.purdue.edu |
| Abstract: | Piles are often driven in multilayered soil profiles. The accurate prediction of the ultimate bearing capacity of piles driven in mixed soil is more challenging than that of piles driven in either clay or sand because the mechanical behavior of these soils is better known. In order to study the behavior of closed-ended pipe piles driven into multilayered soil profiles, fully instrumented static and dynamic axial load tests were performed on three piles. One of these piles was tested dynamically and statically. A second pile served as reaction pile in the static load test and was tested dynamically. A third pile was tested dynamically. The base of each pile was embedded slightly in a very dense nonplastic silt layer overlying a clay layer. In this paper, results of these pile load tests are presented, and the lessons learned from the interpretation of the test data are discussed. A comparison is made of the ultimate base and limit shaft resistances measured in the pile load tests with corresponding values predicted from in situ test-based and soil property-based design methods. |
| Keywords: | Bearing capacity Pipe piles Pile load tests Layered soils |