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Geotechnical and Geological Engineering
Published in: Geotechnical and Geological Engineering 6/2020

10-06-2020 | Original Paper

DEM Analysis and Prediction for the Lateral Interaction of Monopile in Gravel Soil

Authors: Wanquan Sun, Emile Niringiyimana

Published in: Geotechnical and Geological Engineering | Issue 6/2020

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Abstract

Gravel is a common geotechnical material in civil engineering. To investigate the lateral bearing behavior of monopile in gravel materials and deeply understand the microscopic mechanisms, parametric three-dimensional discrete element analyses are performed to study the lateral interaction between the single pile and gravel. First, using the experimental data of two typical gravel samples, the discrete element methods (DEM) for monopile in gravel materials are investigated. A discrete particle flow model of pile segments that allows for the construction of p–y curves at various depths is proposed. The lateral mechanical behaviors (p–y curves) between monopile and different gravel material are then studied. The effects of gravel porosity, distribution and grain-size on both the strength and shape of the p–y curves are investigated. The results show that the influences of porosity and depth on the p–y behaviors of gravel are significantly different from those of sand. Furthermore, the obvious differences in p–y behaviors between the coarse gravel and fine sand are the effects of grain size and size distribution. Based on these results, corresponding equations for the estimation of the p–y curves are proposed and further validated by independent field test data. It is concluded that the proposed p–y curve is capable of modeling both different grain sizes and size distributions in gravel-monopile interaction analyses during lateral loading.
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Literature
API (American Petroleum Institute) (2000) Recommended practice for planning, designing, and constructing fixed offshore platforms-working stress design. API Recommended Practice 2A-WSD (RP 2A-WSD), Twenty-first edition, Washington
Azizkandi AS, Baziar MH, Yeznabad AF (2018) 3D dynamic finite element analyses and 1 g shaking table tests on seismic performance of connected and nonconnected piled raft foundations. KSCE J Civ Eng 22(5):1750–1762CrossRef
Chiou JS, Ko YY, Hsu SY, Tsai YC (2012) Testing and analysis of a laterally loaded bridge caisson foundation in gravel. Soils Found 52(3):562–573CrossRef
Fan CC, Long JH (2005) Assessment of existing methods for predicting soil response of laterally loaded piles in sand. Comput Geotech 32(4):274–289CrossRef
Gong J, Liu J (2017) Mechanical transitional behavior of binary mixtures via DEM: effect of differences in contact-type friction coefficients. Comput Geotech 85(5):1–14CrossRef
Hamed M, Canakci H, Nasr A (2019) Analysis of vertical piles embedded in organic soil under oblique pull-out load. Geotech Test J 42(5):1185–1206CrossRef
Haque MN, Abu-Farsakh MY (2019) Development of analytical models to estimate the increase in pile capacity with time (pile setup) from soil properties. Acta Geotech 14(3):881–905CrossRef
Itasca Consulting Group Inc. PFC3D (2008) Particle flow code in 3 dimensions user’s guide. Itasca Consulting Group Inc. PFC3D, Minneapolis
Jagodnik V, Arbanas Z (2015) Testing of laterally loaded piles in natural sandy gravels. Int J Phys Model Geotech 15(4):191–208
Jenck O, Dias D, Kastner R (2009) Discrete element modelling of a granular platform supported by piles in soft soil-validation on a small scale model test and comparison to a numerical analysis in a continuum. Comput Geotech 36(6):917–927CrossRef
Li Q, Yang ZH (2017) P–Y approach for laterally loaded piles in frozen silt. J Geotech Geoenviron Eng 143(5):04017001CrossRef
Lobo-Guerrero S, Vallejo LE (2007) Influence of pile shape and pile interaction on the crushable behavior of granular materials around driven piles: DEM analyses. Granul Matter 9(3–4):241–250CrossRef
Macklin PR, Chou NNS (1989) Lateral load test on seven foot diameter caissons. In: Conference name: foundation engineering: current principles and practices, ASCE, New York, pp 1122–1131
Matlock H (1970) Correlations for design of laterally loaded piles in soft clay. In: Proceedings of the annual offshore technology conference, Houston, vol 1970-April, pp 577–594
Mayoral JM, Pestana JM, Seed RB (2016) Multi-directional cyclic p–y curves for soft clays. Ocean Eng 115:1–18CrossRef
Omidvar M, Iskander M, Bless S (2014) Response of granular media to rapid penetration. Int J Impact Eng 66:60–82CrossRef
Reese LC (1997) Analysis of laterally loaded piles in weak rock. J Geotech Geoenviron Eng 123(11):1010–1017CrossRef
Reese LC, Cox WR, Koop FD (1974) Analysis of laterally loaded piles in sand. In: Proceedings, VI annual offshore technology conference, vol II, Houston, pp 473–485
Reese LC, Cox WR, Koop FD (1975) Field testing and analysis of laterally loaded piles in stiff clay. In: Proceedings, VII annual offshore technology conference, vol II, Houston, pp 671–690
Rollins KM, Kwon KH, Gerber TM (2008) Static and dynamic lateral load tests on a pile cap with partial gravel backfill. In: Geotechnical special publication, proceedings of the geotechnical earthquake engineering and soil dynamics IV congress 2008—geotechnical earthquake engineering and soil dynamics, ASCE, GSP 181
Rollins KM, Price JS, Bischoff J (2011) Lateral resistance of piles near vertical MSE abutment walls. In: Proceedings of geo-frontiers 2011: advances in geotechnical engineering. Geotechnical Special Publication, ASCE, no. 211, pp 3526–3535
Rollins K, Price J, Bischoff J (2012) Reduced lateral resistance of abutment piles near MSE walls based on full-scale tests. Int J Geotech Eng 6(2):245–250CrossRef
Saeedi Azizkandi A, Kashkooli A, Baziar MH (2014) Prediction of uplift pile displacement based on cone penetration tests (CPT). Geotech Geol Eng 32(4):1043–1052CrossRef
Salimi SN, Yazdanjou V, Hamidi A (2008) Shape and size effects of gravel grains on the shear behavior of sandy soils. In: 10th international symposium on landslides and engineered slopes, Xian, People’s Republic of China
Smith TD, Park R, Hannan R (2000) Lateral load prediction and testing of 3.05 m diameter shafts. In: Proceedings of the ASCE geo-institute specialty conference on performance confirmation of constructed geotechnical facilities-performance confirmation of constructed geotechnical facilities, ASCE, GSP 94, 300, pp 184–197
Stahl M, Konietzky H (2011) Discrete element simulation of ballast and gravel under special consideration of grain-shape, grain-size and relative density. Granul Matter 13(4):417–428CrossRef
Ueda T, Matsushima T, Yamada Y (2011) Effect of particle size ratio and volume fraction on shear strength of binary granular mixture. Granul Matter 13(6):731–742CrossRef
Vallejo LE (2001) Interpretation of the limits in shear strength in binary granular mixtures. Can Geotech J 38(5):1097–1104CrossRef
Yu G, Gong W, Chen M et al (2019) Prediction and analysis of behaviour of laterally loaded single piles in improved gravel soil. Int J Civ Eng 17(6):809–822CrossRef
Zhao H, Zhang J, Qiu P et al (2019) Hierarchical modeling method for DEM simulation and its application in soil-pile-cap interaction and impact case. Int J Geomech 19(7):P04019076CrossRef
Metadata
Title
DEM Analysis and Prediction for the Lateral Interaction of Monopile in Gravel Soil
Authors
Wanquan Sun
Emile Niringiyimana
Publication date
10-06-2020
Publisher
Springer International Publishing
Published in
Geotechnical and Geological Engineering / Issue 6/2020
Print ISSN: 0960-3182
Electronic ISSN: 1573-1529
DOI
https://doi.org/10.1007/s10706-020-01406-2

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