A simplified approach for settlement calculation of pile groups considering pile-to-pile interaction in layered soils 被引量：5

A simplified approach for settlement calculation of pile groups considering pile-to-pile interaction in layered soils

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摘要 A simplified approach is presented for the analysis of the settlement of vertically loaded pile groups. In order to simulate the nonlinear pile-to-pile interaction in pile groups, the soils along the piles are assumed to behave as a series of nonlinear springs subjected to the shaft shear stress at the pile/soil interface. Considering the displacement reduction induced by the pile-to-pile interaction, the shear-deformation method is adopted to approximate the displacement field of the layered soils around the piles, and the equivalent stiffness of the springs is obtained. Furthermore, the load-settlement response of pile groups is deduced by modifying the load-transfer functions to account for the pile-to-pile interaction. The settlements of a laboratory pile groups computed by the presented approach are in a good agreement with measured results. The analysis on contrastive parameters shows that the settlements of pile group decrease with the increase of the pile space and pile length, and the part of piles exceeding the critical pile length has little contribution to the bearing capacity of the pile groups. A simplified approach is presented for the analysis of the settlement of vertically loaded pile groups. In order to simulate the nonlinear pile-to-pile interaction in pile groups, the soils along the piles are assumed to behave as a series of nonlinear springs subjected to the shaft shear stress at the pile/soil interface. Considering the displacement reduction induced by the pile-to-pile interaction, the shear-deformation method is adopted to approximate the displacement field of the layered soils around the piles, and the equivalent stiffness of the springs is obtained. Furthermore, the load-settlement response of pile groups is deduced by modifying the load-transfer functions to account for the pile-to-pile interaction. The settlements of a laboratory pile groups computed by the presented approach are in a good agreement with measured results. The analysis on Contrastive parameters shows that the settlements of pile group decrease with the increase of the pile space and pile length, and the part of piles exceeding the critical pile length has little contribution to the beating capacity of the pile groups.

作者杨明辉张小威赵明华

机构地区 College of Civil Engineering

出处《Journal of Central South University》 SCIE EI CAS 2011年第6期2131-2136,共6页 中南大学学报（英文版）

基金 Project(50708033) supported by the National Natural Science Foundation of China Projects(200923, CXKJSF0108-2) supported by Transportation Technical Project of Hunan Province, China

关键词群桩相互作用沉降计算分层土壤荷载传递函数非线性弹簧沉降分析剪切变形等效刚度 pile groups settlement pile-to-pile interaction load transfer shear-deformation method

分类号 TU473.1 [建筑科学—结构工程] TU433 [建筑科学—岩土工程]

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参考文献18

1MOHAMMAD R M, ASADOLLAH N, MANOUCHEH L N. Three-dimensional nonlinear finite element analysis of pile groups in saturated porous media using a new transmitting boundary [J]. International Journal for Numerical and Analytical Methods in Geomechanics, 2008, 32(6): 681-699.
2COMODROMOS E M, BAREKA S V. Response evaluation of axially loaded fixed-head pile groups in clayey soils [J]. International Journal for Numerical and Analytical Methods in Geomechanics, 2009, 33(1): 1839-1865.
3LI Fei-ran, ZHANG Zhe. Numerical analysis of settlement of bridge pile group foundation [J]. Electronic Journal of Geotechnical Engineering, 2009, 14: 1-9.
4杨小礼,邹金锋.Displacement and deformation analysis for uplift piles[J].Journal of Central South University of Technology,2008,15(6):906-910. 被引量：7
5CLANCY P, RANDOLPH M F. Simple design tools for piled raft foundations [J]. Geotechnique, 1996, 46(2): 313-328.
6HORIKOSHI K, RANDOLPH M F. Estimation of overall settlement of piled raft [J]. Soils and Foundation, 1999, 39(2): 59-68.
7CASTELLI F, MAUGERI M. Simplified nonlinear analysis for settlement prediction of pile groups [J]. Journal Geotechnical and Geoenvironmental Engineering, ASCE, 2002, 128( 1): 76-84.
8POULOS H G. Analysis of the settlement of pile groups [J]. Geotechnique, 1968, 18(4): 449-471.
9LEE C Y. Pile group settlement analysis by hybrid layer approach [J]. Joumal of the Geotechnical Engineering, ASCE, 1993, 119(6): 984-997.
10COSTANZO D, LANCELLOTA R. A note on pile interaction factors [J]. Soils and Foundation, 1998, 38(4): 251-253.

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1王涛,刘金砺.桩–土–桩相互作用影响的试验研究[J].岩土工程学报,2008,30(1):100-105. 被引量：14
2黄锋,李广信,吕禾.砂土中抗拔桩位移变形的分析[J].土木工程学报,1999,32(1):31-36. 被引量：42

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Journal of Central South University

2011年第6期

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