Modelling of statically loaded single pile taking into account nonlinearity of foundation soil

Introduction. Modelling of pile foundations in modern software packages (PC) is often carried out in a linear formulation of the problem and with the use of coefficients that overestimate the results of pile foundations by several times. This approach leads to significant overconsumption of materials and overestimation of the estimated cost of the object under construction. In modern realities, designers are faced with the problem of modelling the design situation, which is closest to the real operation of the pile in the ground, and since the foundation soil is a heterogeneous medium, the calculation must be carried out non–linearly, which is quite time-consuming in software packages. A numerical comparison of full-scale tests of a single pile under static load and calculation in a software package, taking into account the nonlinearity of the foundation soils, is carried out.

Materials and methods. The calculations are carried out in the finite element software package LIRA-CAD by modelling the design scheme with volumetric finite elements. The change in the settlement of piles in different soils under step load is analyzed.

Results. Numerical experiment of change in the settlement of a single pile using a volumetric finite element model with a given physical nonlinearity of the soil was performed. The obtained results of the numerical experiment are compared with the results of the full-scale experiment.

Conclusions. The results of the study show a large discrepancy between the settlements of piles according to field tests and the results of calculations according to SP 24.13330.2021. With the help of modern software packages, it is possible to carry out more accurate calculations. However, the introduction of correction coefficients can bring the calculated situation according to regulatory documents closer to more real conditions of deformation of the foundation soils in the process of preliminary selection.

1. Konyushkov V.V., Le V.T. Side friction of sandy and clay soils and their resistance under the toe of deep bored piles. Architecture and Engineering. 2020; 5(1):36-44. DOI: 10.23968/2500-0055-2020-5-1-36-44

2. Kupchikova N.V., Alyokhin V.S. Analysis of the deformation and strength characteristics of bored micro-piles with terminal expansion of crushed stone. Prospects for the Development of the Construction Complex. 2017; 1:158-162. EDN ZOFUHN. (rus.).

3. Egorova E.S., Ioskevich A.V., Ioskevich V.V., Agishev K.N., Kozhevnikov K.V. Soil model implemented in the software packages SCAD Office and Plaxis 3D. Construction of Unique Buildings and Structures. 2016; 3(42):31-60. EDN VSYFHT. (rus.).

4. Mangushev R.A., Sakharov I.I., Konyushkov V.V., Lan’ko S.V. Comparative analysis of computational modeling of the system “building-foundation-base” in the soft ware packages SCAD and PLAXIS. Bulletin of Civil Engineers. 2013; 3(24):96-101. EDN NDVKMZ. (rus.).

5. Belov V.V., Boldyrev Yu.Ya., Romanov S.V., Shanina A.S. Experience in applying mathematical modeling of ground foundations of buildings and structures. St. Petersburg Polytechnical University Journal. Computer Science. Telecommunication and Control Systems. 2010; 5(108):103-109. EDN MVXAZD. (rus.).

6. Sokolova O.V. The selection of soil models parameters in Plaxis 2D. Magazine of Civil Engineering. 2014; 4(48):10-16. DOI: 10.5862/MCE.48.2. EDN SFOUPH. (rus.).

7. Shiryaeva M.P., Krivonos E.A. Classification of soil foundation models. Electronic network polythematic journal “Scientific works of KUBSTU”. 2014; 3:18-25. EDN TGILJV.

8. Kurguzov K.V., Fomenko I.K. Constitutive mathematical soil models in geotechnical practice. Review. Natural and Technical Sciences. 2019; 5(131):240-247. DOI: 10.25633/ETN.2019.05.04. EDN KGJTQF. (rus.).

9. Kolesnikov A.O., Popov V.N., Kostiuk T.N. Evaluation of the pile interaction at vertical vibrations of foundation. Structural Mechanics of Engineering Constructions and Buildings. 2020; 16(3):209-218. DOI: 10.22363/1815-5235-2020-16-3-209-218 (rus.).

10. Das S.K., Manna B., Baidya D.K. Prediction of pile-separation length under vertical vibration using ANN. 14th Asian Regional Conference on Soil Mechanics and Geotechnical Engineering. 2011.

11. Holeyman A., Whenham V. Axial non-linear dynamic soil-pile interaction. Springer Proceedings in Physics. 2015; 305-333. DOI: 10.1007/978-3-319-19851-4_15

12. Ishibashi I., Zhang X. Unified dynamic shear moduli and damping ratios of sand and clay. Soils and Foundations. 1993; 33(1):182-191. DOI: 10.3208/SANDF1972.33.182

13. Katzenbach R., Choudhury D. ISSMGE Combined Pile-Raft Foundation Guideline. Technische Universität Darmstadt, Darmstadt, Germany, 2013; 1-23.

14. Bokov I.A., Fedorovsky I.A. Calculation of the settlement of pile foundations containing piles of various lengths and diameters by the interaction factors method. Proceedings of The XVII European Conference on Soil Mechanics and Geotechnical Engineering. 2019.

15. Van Impe W.F., De Clerq Y. A piled raft interaction model. Proc. 5th Int. Conf. on Piling and Deep Foundations. Bruges, Balkema, Rotterdam.

16. Idriss I.M., Dobry R., Singh R.D. Nonlinear behavior of soft clays during cyclic loading. Journal of the Geotechnical Engineering Division. 1978; 104(12):1427-1447. DOI: 10.1061/ajgeb6.0000727

17. Wang G., Sitar N. Numerical analysis of piles in elasto-plastic soils under axial loading. 17th ASCE Engineering Mechanics Conference. 2004.

18. Geuse E.C.W.A., Tjong-Kie T. The mechanical behaviors of clays. Proceedings of the International Congress on Rheology. London, 1954; 247-259.

19. Henkel D.J. Investigation of two long-term failures in London clay slopes at Wood Green and Northolt. Proceedings 4th International Conference on Soil Mechanics and Foundation Engineering (London). 1957; 2:315-320.

20. Higo Y., Oka F., Kodaka T., Kimoto S. Three-dimensional strain localization of water-saturated clay and numerical simulation using an elasto-viscoplastic model. Philosophical Magazine. 2006; 86(21-22):3205-3240. DOI: 10.1080/14786430500321203

21. Kharichkin A. Numerical analysis of static loading pile groups with different conditions of pile location in group. Bulletin of Science and Research Center of Construction. 2019; 1(20):113-119. EDN VTBFNK. (rus.).

22. Shkolyar F.S., Tyapkina P.A. Comparison of methods for calculating the precipitation of a pile foundation. Week of Science ISI: collection of materials of the All-Russian Conference. 2022; 281-283. EDN IPJAFV. (rus.).