Authors: T.V. Tran, S. Teramoto, M. Kimura, T. Boonyatee, Le Ba Vinh

Abstract:

In this paper, two centrifugal model tests (case 1: raft foundation, case 2: 2x2 piled raft foundation) were conducted in order to evaluate the effect of ground subsidence on load sharing among piles and raft and settlement of raft and piled raft foundations. For each case, two conditions consisting of undrained (without groundwater pumping) and drained (with groundwater pumping) conditions were considered. Vertical loads were applied to the models after the foundations were completely consolidated by selfweight at 50g. The results show that load sharing by the piles in piled raft foundation (piled load share) for drained condition decreases faster than that for undrained condition. Settlement of both raft and piled raft foundations for drained condition increases more quickly than that for undrained condition. In addition, the settlement of raft foundation increases more largely than the settlement of piled raft foundation for drained condition.

Keywords: Ground subsidence, Piled raft, Load sharing, Centrifugal model test.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1074345

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2880

References:

[1] Phienwej N., Thepparak S., Giao P. H. (2004). Prediction of differential settlement of buildings induced by land subsidence from deep well pumping. 15th Southeast Asian Geotechnical Society Conference, Bangkok, Thailand. 165 - 170.
[2] Zeevaert, L. (1957). Compensated friction-pile foundation to reduce the settlement of buildings on the highly compressible volcanic clay of Mexico City. Proc. 4th Int. Conf. Soil Mech. Foundn Engng, London, England, Aug. 1957, 2, 81−86. Butterworths Scientific Publications, London.
[3] Le Van Trung & Ho Tong Minh Dinh (2008). Measuring ground subsidence in Ho Chi Minh city using differential inSAR techniques. Science & Technology Development, Vol 11, No.12, 121 - 130.
[4] Hemsley, J. A. (2000). Developments in raft analysis and design. Design applications of raft foundations. Hemsley J. A., editor, Thomas Telford, London, 487-605.
[5] Katzenbach, R., Arslan, U., and Moormann, C. (2000). Piled raft foundations projects in Germany. Design applications of raft foundations. Hemsley J. A., editor, Thomas Telford, London, 323-392.
[6] Y. El-Mossallamy, associate Prof., Ain shams University, Cairo, Egypt c/o ARCADIS, Berliner allee 6, D - 64295 Darmstadt, Germany (2008). Plaxis Bulletin issue 23 / March 2008, pp.10-13.
[7] Vincenzo Fioravante, Daniela Giretti and Michele Jamiolkowski (2008). Physical Modeling of Raft on Settlement Reducing Piles. From Research to Practice in Geotechnical Engineering Congress 2008 (ASCE). 325(2), 206-229.
[8] S. Teramoto, T. V. Tran, M. Kimura & T. Boonyatee (2011). Centrifuge modeling of piled raft and piled group foundation on soft clay under some ground water condition. Proceedings of the Twenty-Fourth KKCNN Symposium on Civil Engineering. December 14-16, 2011, Hyogo, Japan. 377 - 380.
[9] Vincenzo Fioravante (1998). Load transfer mechanism of piled raft foundation. Centrifuge 98, Kimura al. el., Editor, Balkema, Rotterdam, Vol.1, 495-500.
[10] Horikoshi, K. & Randolph, M. F. (1996). Centrifuge modelling of piled raft foundations on clay. Geotechnique 46, No. 4, 741-752.
[11] Burland, J.B. (1995). Piles as Settlement Reducers. Keynote Address, 18th Italian Congress on Soil Mechanics, Pavia, Italy.