Numerical analysis of piled rafts with short bored piles

Oliveira, Eduardo Augusto dos Santos; Justino, Marcos Oliveira; Garcia, Jean Rodrigo

doi:10.1590/S1983-41952022000400008

Abstract

Numerical analysis of the behavior of piled rafts seated on uniform soil with low bearing capacity has been important to support the project design. The calibration of the numerical model with instrumented load test allows usage of the results, in given conditions, in the foundation design of small and medium-sized buildings built on soils with the same mechanical properties analyzed in this paper. In this context, this paper evaluates numerical models, which allow to consider the influence of short bored piles connected to the raft. The models are also assessed using piled rafts concepts. From the results obtained, the load supported by the total shaft resistance is significant for the case of bored piles, and this load is from 14% to 30% higher in the case more flexible or thinner raft. Inserting piles in the rafts reduces settlement and increases overall stiffness. Such effects are amplified in piles with higher slenderness ratios (L/d).

Keywords:
piled raft; numerical modeling; bored piles; load sharing; settlement reduction

Resumo

A análise numérica do comportamento de radiers estaqueados assentes em solo uniforme e de baixa capacidade de suporte tem se mostrado importante para subsidiar a concepção do projeto. A calibração do modelo numérico com uma prova de carga instrumentada permite que os resultados possam ser aplicados, dentro das condições estabelecidas, ao projeto de fundações para edificações de pequeno e médio porte assentes em solos com as mesmas propriedades mecânicas analisadas neste artigo. Nesse sentido, o artigo avalia modelos numéricos, que permitam estudar a influência de estaca curta executada por escavação acoplada ao radier. Os modelos também são avaliados a partir dos conceitos de radier estaqueado. A partir dos resultados obtidos, verifica-se que a carga suportada pela resistência lateral, significativa para o caso de estacas escavadas, é de 14% a 30% maior para radiers mais flexíveis ou com menores espessuras. A introdução de estacas nos radiers promove a redução de recalques e o aumento da rigidez do sistema, tendo seus efeitos ampliados para estacas com esbeltezes (L/d) mais elevadas.

Palavras-chave:
radier estaqueado; modelagem numérica; estacas escavadas; distribuição de carga; redução de recalques

1 INTRODUCTION

Understanding the behavior of a piled raft foundation leads to the need of analyzing not just the foundation system in each separate element, the piles and the raft, but also the interactions among them over time.

In typical foundation projects, such as pile groups, the cap resistance is neglected in the design, even when the cap is in contact with the soil. Investigations and analytical methods have been developed to consider the soil-structure interaction, enabling to assess the contribution of the raft on the bearing capacity of the system. Sophisticated methodologies and the search for refined results have become main points in the field of foundations, due to the decrease of computational costs. In practice, the creation of numerical models that can guide the engineer to an efficient foundation design is a key factor to achieve efficacy of a project.

Among other advantages, numerical modeling enables fast parametric analyses, saving tests and experimentations, even though it does not replace them. Correlations factors can be deduced from the model results, and then combined and calibrated with experimental results.

The foundations considered in this work consist of rafts of varying thicknesses and short bored piles of varying lengths. The concepts and characteristics of each one of these elements are discussed, as well as how they affect the behavior of the piled rafts studied. In addition, features and results are presented in terms of the behavior of the system and their elements separately.

The present work is limited to considering the following hypotheses:

the soils have constant mechanical characteristics along its depth, since short piles are used;
the load is applied of loading distributed over the entire raft area; loading takes place at time intervals that do not allow soil consolidation;
pore pressure and saturation are not considered;
effects due to suction are implicit in the calibration and validation of the model with experimental results.

The numerical analysis considered elastoplastic constitutive model materials, based on the elastic perfectly plastic behavior with of Mohr-Coulomb failure criterion.

From the analysis of sixteen cases of piled rafts, it was possible to quantify the load distribution between the raft and the pile, as well as to estimate the influence of the piles on reducing settlements, on the variation of the shaft resistance according to the pile depth, on the axial load transfer, on the pile lateral and toe strength portions and on the overall stiffness.

1.1 Previous works

The number of studies on the behavior of piled foundations has increased significantly since the 1950’s, strengthening and consolidating the understanding of these systems. Several works have studied the influence of foundation geometry [¹1 T. Whitaker, "Experiments with model piles in groups," Geotechnique, vol. 7, no. 4, pp. 147–167, Dec 1957, http://dx.doi.org/10.1680/geot.1957.7.4.147.
http://dx.doi.org/10.1680/geot.1957.7.4.... ]–[⁴4 J. R. Garcia and P. J. R. de Albuquerque, "Analysis of the contribution of the block-soil contact in piled foundations," Lat. Am. J. Solids Struct., vol. 16, no. 6, pp. 1–22, 2019, http://dx.doi.org/10.1590/1679-78255565.
http://dx.doi.org/10.1590/1679-78255565... ], the contribution of raft-soil contact and load distribution among the elements and their variables [⁵5 R. Butterfield and P. K. Banerjee, "The problem of pile group–pile cap interaction," Geotechnique, vol. 21, no. 2, pp. 135–142, Jun 1971, http://dx.doi.org/10.1680/geot.1971.21.2.135.
http://dx.doi.org/10.1680/geot.1971.21.2... ] and the use of numerical models for analysis of piled rafts [⁶6 M. Ottaviani, "Three-dimensional finite element analysis of vertically loaded pile groups," Geotechnique, vol. 25, no. 2, pp. 159–174, 1975, http://dx.doi.org/10.1680/geot.1975.25.2.159.
http://dx.doi.org/10.1680/geot.1975.25.2... ].

Many authors report several advantages in considering the raft-soil contact, such as reduction and uniformity of settlements (differential and total) and the increase in load capacity [⁶6 M. Ottaviani, "Three-dimensional finite element analysis of vertically loaded pile groups," Geotechnique, vol. 25, no. 2, pp. 159–174, 1975, http://dx.doi.org/10.1680/geot.1975.25.2.159.
http://dx.doi.org/10.1680/geot.1975.25.2... ]–[⁸8 M. F. Randolph, “Design methods for pile groups and piled rafts,” in Int. Conf. Soil Mech. and Found. Eng., 1994, pp. 61–82.]. According to Butterfield and Banerjee [⁵5 R. Butterfield and P. K. Banerjee, "The problem of pile group–pile cap interaction," Geotechnique, vol. 21, no. 2, pp. 135–142, Jun 1971, http://dx.doi.org/10.1680/geot.1971.21.2.135.
http://dx.doi.org/10.1680/geot.1971.21.2... ], the load supported by the raft can range from 20% to 60%, assuming larger values for higher spacing between piles. Experiments reported in Garcia and Albuquerque [⁴4 J. R. Garcia and P. J. R. de Albuquerque, "Analysis of the contribution of the block-soil contact in piled foundations," Lat. Am. J. Solids Struct., vol. 16, no. 6, pp. 1–22, 2019, http://dx.doi.org/10.1590/1679-78255565.
http://dx.doi.org/10.1590/1679-78255565... ] and numerical studies reported in Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.] considering porous residual soil and piles spacing (s) equal to five times their diameter, shows a contribution of 21% and 36% of the raft-soil contact, respectively. Kuwabara [¹⁰10 F. Kuwabara, "An elastic analysis for piled raft foundations in a homogeneous soil," Soil Found., vol. 29, no. 1, pp. 82–92, Mar 1989, http://dx.doi.org/10.3208/sandf1972.29.82.
http://dx.doi.org/10.3208/sandf1972.29.8... ], reports study using boundary elements method in cases of piles spacing smaller than ten times their diameter normal spacing and compared pile groups and piled rafts and founding a distribution of 20% to 40% of the total load to the raft.

The parameters involving foundation geometry, number of piles, and materials properties influence the behavior of the foundation [²2 H. G. Poulos and E. H. Davis, Pile Foundation Analysis and Design. Rainbom-Bridge Book Co., 1980.]. According to Ottaviani [⁶6 M. Ottaviani, "Three-dimensional finite element analysis of vertically loaded pile groups," Geotechnique, vol. 25, no. 2, pp. 159–174, 1975, http://dx.doi.org/10.1680/geot.1975.25.2.159.
http://dx.doi.org/10.1680/geot.1975.25.2... ] and Kuwabara [¹⁰10 F. Kuwabara, "An elastic analysis for piled raft foundations in a homogeneous soil," Soil Found., vol. 29, no. 1, pp. 82–92, Mar 1989, http://dx.doi.org/10.3208/sandf1972.29.82.
http://dx.doi.org/10.3208/sandf1972.29.8... ], the effect of raft-soil contact influences the load distribution and transfer to the soil, and are affected by in terms of the position of the pile in the raft. Brown and Wiesner [⁷7 P. T. Brown and T. J. Wiesner, "The behaviour of uniformly loaded piled strip footings," Soil Found., vol. 15, no. 4, pp. 13–21, Dec 1975, http://dx.doi.org/10.3208/sandf1972.15.4_13.
http://dx.doi.org/10.3208/sandf1972.15.4... ] highlighted the importance of parameters such as pile slenderness, L/d, relative pile spacing, s/d, relative stiffness between raft and soil, and relative stiffness between pile and soil for a preliminary assessment of the piled foundation design.

Saeedi Azizkandi et al. [¹¹11 A. Saeedi Azizkandi, H. Rasouli, and M. H. Baziar, "Load sharing and carrying mechanism of piles in non-connected pile rafts using a numerical approach," Int. J. Civ. Eng., vol. 17, no. 6, pp. 793–808, 2019., http://dx.doi.org/10.1007/s40999-018-0356-2.
http://dx.doi.org/10.1007/s40999-018-035... ] investigated the load sharing mechanisms in piled rafts using numerical analyses with and without connection of the piles to the raft. The authors reported that the increase in the pile length reflected an increase in the portion of shared load, particularly in rafts with connected piles.

An important aspect in the analysis of piled foundations is related to the raft and how it is designed to be either rigid or flexible. Clancy and Randolph [¹²12 P. Clancy and M. F. Randolph, "An approximate analysis procedure for piled raft foundations," Int. J. Numer. Anal. Methods Geomech., vol. 17, no. 12, pp. 849–869, Dec 1993, http://dx.doi.org/10.1002/nag.1610171203.
http://dx.doi.org/10.1002/nag.1610171203... ] concluded that the behavior of the foundation changed with the increase in raft flexibility when the foundation models have few piles (less than 4 piles). Analyzing the measurements taken at the foundation of the Messeturm building in Frankfurt, Randolph [⁸8 M. F. Randolph, “Design methods for pile groups and piled rafts,” in Int. Conf. Soil Mech. and Found. Eng., 1994, pp. 61–82.] observed that the failure of the piled raft foundation occurred mostly by punching the raft, since the piles prevent the raft from moving with the soil, submitting it to the Ultimate Limit State of the foundation. However, pile rafts must be classified according to their dimensions in order to define the appropriate analysis. Russo and Viggiani [¹³13 G. Russo and C. Viggiani, “Factors controlling soil structure interaction for piled rafts,” in Int. Conf. Soil-Structure Interaction, Darmstadt University of Technology, 1998, http://dx.doi.org/10.13140/2.1.4035.7125.
http://dx.doi.org/10.13140/2.1.4035.7125... ] categorize piled rafts in two groups, calling “small” rafts those in which rafts do not have sufficient bearing capacity and the piling alone will ensure adequate safety factor, and “large” rafts, which have enough bearing capacity, ensuring a certain share of and requiring the introduction of piles as settlement reducers.

Katzenbach and Choudhury [¹⁴14 R. Katzenbach and D. Choudhury, Combined Pile-Raft Foundation Guideline, Darmstadt: Institute and Laboratory of Geotechnics, 2013.] recommended evaluating piled rafts at Ultimate Limit State (ULS) and at Service Limit State (SLS), by means modeling that can consider the effects of the interaction among the elements of the foundation. For each limit state, an external check, considering the behavior of the whole foundation, and an internal check, evaluating the elements separately, should be performed and the most unfavorable results used for design. In this context, the use of numerical tools for the analysis of the complexity involved in piled raft foundation is important, as well as its benefits to obtain the appropriate design and to avoiding overdesigning when considering simplified methods. Poulos [¹⁵15 H. Poulos, “Methods of analysis of piled raft foundations,” Int. Soc. Soil Mech. Geotech. Eng., no. July, pp. 46, 2001.] highlights the importance of considering the effects of interactions among the raft, pile and soil by using structural numerical models in order to avoid under designing the foundation with simplified methods.

Mandolini, Russo and Viggiani [¹⁶16 A. Mandolini, G. Russo, and C. Viggiani, “Pile Foundations : Experimental Investigations, Analysis and Design,” in Proceedings of the 16th International Conference on Soil Mechanics and Geotechnical Engineering: Geotechnology in Harmony with the Global Environment, Osaka, Japan, 2005, vol. 1, no. 2003, pp. 177–213.] and Randolph [⁸8 M. F. Randolph, “Design methods for pile groups and piled rafts,” in Int. Conf. Soil Mech. and Found. Eng., 1994, pp. 61–82.], report evaluating 125 pile load tests with different installation processes. They conclude that the type of installation affects more the load capacity of piles than their axial stiffnesses determined by estimation of the tangent to the curve containing the first three loading points.

The evaluation of the behavior of the elements that form piled rafts is related not only to load capacity and settlement, but also to how the shaft resistance and the toe resistance are mobilized.

Studies performed by Lee et al. [¹⁷17 J. Lee, D. Park, D. Park, and K. Park, "Estimation of load-sharing ratios for piled rafts in sands that includes interaction effects," Comput. Geotech., vol. 63, pp. 306–314, Jan 2015, http://dx.doi.org/10.1016/j.compgeo.2014.10.014.
http://dx.doi.org/10.1016/j.compgeo.2014... ] on the interaction among elements of piled raft in sands described the load distribution in the pile as a function of the overall displacement, and the established coefficients considering the initial rapid increase of the load on the pile with small displacements that do not considerably increase with larger displacements. These coefficients were later incorporated into the model proposed by Clancy and Randolph [¹⁸18 P. Clancy and M. F. Randolph, "Simple design tools for piled raft foundations," Geotechnique, vol. 46, no. 2, pp. 313–328, Jun 1996, http://dx.doi.org/10.1680/geot.1996.46.2.313.
http://dx.doi.org/10.1680/geot.1996.46.2... ].

1.2 Some concepts on piled rafts

Katzenbach and Choudhury [¹⁴14 R. Katzenbach and D. Choudhury, Combined Pile-Raft Foundation Guideline, Darmstadt: Institute and Laboratory of Geotechnics, 2013.] and Abdel-Azim et al. [¹⁹19 O. A. Abdel-Azim, K. Abdel-Rahman, and Y. M. El-Mossallamy, "Numerical investigation of optimized piled raft foundation for high-rise building in Germany," Innov. Infrastruct. Solut., vol. 5, no. 1, pp. 11, Apr 2020., http://dx.doi.org/10.1007/s41062-019-0258-4.
http://dx.doi.org/10.1007/s41062-019-025... ] consider two parameters to distinguish the behavior of piled raft foundations with respect to the pile group and to isolated rafts. In the case of the piled rafts, the coefficient α_pr is a correlation related to the characteristic values and is presented as function of a given settlement, s, according to Equations 1 and 2:

α_{p r} = \frac{\sum_{j = 1}^{m} R_{p i l e, k, j} (s)}{R_{t o t, k} (s)}

(1)

α_{s} = \frac{s_{p r}}{s_{r}}

(2)

Where:

α_pr = piled raft coefficient;

α_s = settlement reduction coefficient;

\sum_{j = 1}^{m} R_{p i l e, k, j} (s)

= sum of the characteristic pile resistances for a given settlement;

R_{t o t, k} (s)

= characteristic value of the total resistance for a given settlement;

s_pr = settlement of piled raft foundation;

s_r = settlement of a spread foundation.

The α_pr values vary between 0 for raft alone and 1 for pile group without raft contribution, as well as the α_s value vary within the range from 0 (piled raft) to 1 (raft alone), as verified by Katzenbach and Choudhury [¹⁴14 R. Katzenbach and D. Choudhury, Combined Pile-Raft Foundation Guideline, Darmstadt: Institute and Laboratory of Geotechnics, 2013.], verified the interdependence between the foundation behavior as a function of stress level and settlement (Figure 1).

Figure 1
Correlation between settlement reduction coefficient, α_s, and load sharing coefficient α_pr of piled raft.

1.3 Effect of rafts on skin friction and axial force

Abdel-Azim et al. [¹⁹19 O. A. Abdel-Azim, K. Abdel-Rahman, and Y. M. El-Mossallamy, "Numerical investigation of optimized piled raft foundation for high-rise building in Germany," Innov. Infrastruct. Solut., vol. 5, no. 1, pp. 11, Apr 2020., http://dx.doi.org/10.1007/s41062-019-0258-4.
http://dx.doi.org/10.1007/s41062-019-025... ] analyzed numerically the piled foundations proposed by Katzenbach et al. [²⁰20 R. Katzenbach, U. Arslan, and C. Moormann, “13. Piled raft foundation projects in Germany,” in Design applications of raft foundations, Thomas Telford Publishing, 2000, pp. 323–391.] evaluating the distribution of skin friction along the 30-meter-long pile assessed for settlements, s, equal to 0.5%, 1% and 10% of “d”. According to these authors, the best position to obtain the skin friction readings along the shaft interface is at a radial offset of 0.1d from the outer face of the shaft (Figure 2). It is observed that, for the first loading stages, the friction is mobilized to the toe, which has its skin friction exhausted from the sixth loading stage (60% of total load), and then leads to a greater resistance mobilization in a region close to the raft, as previously verified by Fioravante et al. [²¹21 V. Fioravante, D. Giretti, and M. B. Jamiolkowski, “Physical modelling of piled raft,” in Deep Foundations on Bored and Auger Piles, W. F. Van Impe and P. O. Van Impe, Eds. Routledge, 2009.].

Figure 2
Influence of the pile-raft interaction on axial load transfer and skin friction with depth based on the Frankfurt Clay model (Katzenbach et al. [²⁰20 R. Katzenbach, U. Arslan, and C. Moormann, “13. Piled raft foundation projects in Germany,” in Design applications of raft foundations, Thomas Telford Publishing, 2000, pp. 323–391.]).

1.4 Bored piles

De Cock [²²22 F. A. De Cock, “Sense and sensitivity of pile load-deformation behaviour,” in Deep Foundations on Bored and Auger Piles, W. F. Van Impe and P. O. Van Impe, Eds. 2009.] describes a series of studies carried out by Caputo [²³23 V. Caputo, “Experimental evidence for the validation of load-settlement predictions,” 2003.] and reinforced the influence of the pile installation method on soil confinement, and mentioning for example the tendency of the base of bored piles to move in the opposite direction of the excavation, which does not occur with driven piles.

Some studies show that shaft resistance of piles develops before toe resistance because it requires small displacements for mobilization [²⁴24 M. W. O’Neill and L. C. Reese, Behavior of Axially Loaded Shafts in Beaumont Clay, Part Four Design Inferences and Conclusions, Center for Highway Research, the University of Texas at Austin, 1970.], ^[25]25 A. S. Vesic, “Design of pile fundations: National Cooperative Highway Research Program, Synthesis Highway Practice,” Report No. 42, Transportation Research Board National Academy of Sciences, 1977.. Through field tests, Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.] observed that shaft resistance mobilization occurs mainly within a range of relative displacement to the pile diameter s/d between 1% and 5%.

Zhang et al. [²⁶26 Q.-Q. Zhang, Z.-M. Zhang, and S.-C. Li, "Investigation into Skin friction of bored pile including influence of soil strength at pile base," Mar. Georesour. Geotechnol., vol. 31, no. 1, pp. 1–16, Jan 2013., http://dx.doi.org/10.1080/1064119X.2011.626506.
http://dx.doi.org/10.1080/1064119X.2011.... ] outline three soil situations at the pile toe to explain the mechanism of toe resistance mobilization when there is relative displacement between the pile and the soil. In the first situation (Figure 3a), the soil layer shows a relatively normal resistance. In the second situation (Figure 3b), soil resistance is low, which may be caused by accumulated sediments at the pile base; in the third situation (Figure 3c) the soil under the toe has high resistance. The authors discuss the interaction between the lateral and toe resistance in the three situations with the use of the Mohr-Coulomb's failure criterion.

Figure 3
Stress state of soil element near pile end with different soil strengths at pile base (after Zhang et al. [²⁶26 Q.-Q. Zhang, Z.-M. Zhang, and S.-C. Li, "Investigation into Skin friction of bored pile including influence of soil strength at pile base," Mar. Georesour. Geotechnol., vol. 31, no. 1, pp. 1–16, Jan 2013., http://dx.doi.org/10.1080/1064119X.2011.626506.
http://dx.doi.org/10.1080/1064119X.2011.... ]).

The piles studied in this article relate to the situation described in Figure 3b, of low resistance soil at the base of the pile, aiming to better represent the behavior of foundations composed by short bored piles, also behaving as friction piles.

2 VALIDATION WITH EXPERIMENTAL STUDY

The material properties were obtained through calibration with experimental results obtained by Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.] in piled cap composed of a short and small diameter bored pile, subjected to axial compression in residual soil. The block geometry (0.60 m x 0.60 m) was adjusted to an equivalent circular geometry, keeping the contact area with the soil to apply axisymmetric numerical modeling with Finite Elements (FEM-2D) by means of the Rocscience RS2 software. The pile used in the model has dimensions of 0.25-m diameter and 5-m length. The numerical model for validation considered non-contact between the side faces of the cap and the soil and included the modeling technique discussed in this work. Hence, the insertion of a region of low resistance soil under the pile toe (Figure 4) to represent the installation method of the pile usually employed in typical foundations.

Figure 4
Numerical model for validation and detail of the soft material region inserted below the pile toe and graded mesh type and 6-noded triangle element.

The model was validated by comparing the load vs. settlement curve adjustment, both numerical and experimental, described by Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.]. Although the numerical model has not taken into account the variation of soils and properties with the depth considered by Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.], the results of the load-settlement curves (Figure 5) denote optimal adjustment up to the sixth stage of the applied load, in addition to the good agreement in the general behavior of the foundation under the aspect of load distribution, axial load transfer and skin friction. The material parameters obtained with the numerical calibration stage are shown in Table 1.

Figure 5
Load-settlement curves of the piled rafts by Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.] versus numerical model.

Thumbnail

Table 1
Mechanical characteristics and materials deformability.

The parameters were derived from compressive and tensile strengths for mass concrete based on the suggestion given by Ardiaca [²⁷27 D. H. Ardiaca, “Mohr-Coulomb parameters for modelling of concrete structures,” Plaxis Bull., pp. 12–15, 2009.].

3 PARAMETRIC ANALYSIS

The analyses were carried out based on a parametric study, varying the geometric characteristics, such as raft thickness and pile length (Table 2).

Thumbnail

Table 2
Details of the piled raft geometries analyzed and their loads.

The geometry of the piled raft cases under consideration has fixed parameters such as raft and pile diameter, and variable parameters such as raft thickness and pile length (Figure 6).

Figure 6
Geometry of the piled raft.

4 NUMERICAL ANALYSIS

The numerical analyses were performed with the aid of Rocscience RS2 software, which enables two-dimensional analyses on geotechnical structures and foundations by means of finite elements by considering, plane strain state or axisymmetric conditions.

The three-dimensional geometry of the foundation was converted into a plane model with axisymmetry around the axis of rotation (Figure 6). For the discretization of the soil mass and the piled raft, elements of the triangular type composed of 6 nodes were used (Figure 5). A graded mesh was adopted, discretized according to the number of dividing elements at the interfaces between the structure and the soil contour, having elements of size at a ratio of 1:70 between the interface around the contact of the structure with the ground and the interior of the soil mass. The number of elements in the models ranged from 4,000 to 6,000; such variation was due to the need for greater discretization inside the piled raft. Therefore, models with thicker rafts and longer piles resulted in a higher number of elements and nodes.

The type of loading chosen in the software was Body Force and Field Stress. It is divided into two stages: first a stress due to the self-weight of the elements is applied considering the horizontal response; then the loading is imposed, according to the stage.

The boundary dimensions were assumed to be about 1.6 times the length of the longest pile (L=6m). Moreover, the lateral boundaries of the model were restrained in the X-direction, and the lower boundary was restrained to move in X and Z-directions.

The dimensions of the low-strength soil element (soft material) were taken with a diameter of 1.2d and height equals to 2 times the diameter of the pile. The choice of extending the width of the region situated at the pile toe beyond the diameter was designed to overcome problems related to stress concentration in zones between different materials, as well as to improve the quality of the mesh in this region.

5 RESULTS AND DISCUSSION

From the methodology presented, an analytical structure was elaborated to briefly represent the steps that compose the present study (Figure 7).

Figure 7
Scheme describing the steps of the present study.

5.1 Load settlement curves

The load versus displacement responses of each foundation under analysis were obtained from the application of a 10-stage series, with 10% increments up to the maximum load (Table 2). Unloading was performed in a 4-stage series, with 25% decreases of the maximum test load until total unloading (Figure 8 to Figure23).

Figure 8
Load-settlement curve for case 1 - L=3m; t=0.1m

Figure 9
Load-settlement curves for case 2 - L=3m; t=0.2m

Figure 10
Load-settlement curves for case 3 - L=3m; t=0.3m

Figure 11
Load-settlement curves for case 4 - L=3m; t=0.4m

Figure 12
Load-settlement curves for case 8 - L=4m; t=0.1m

Figure 13
Load-settlement curves for case 6 - L=4m; t=0.2m

Figure 14
Load-settlement curves for case 7 - L=4m; t=0.3m

Figure 15
Load-settlement curves for case 8 - L=4m; t=0.4m

Figure 16
Load-settlement curve for case 9 - L=5m; t=0.1m

Figure 17
Load-settlement curves for case 10 - L=5m; t=0.2m

Figure 18
Load-settlement curves for case 11 - L=5m; t=0.3m

Figure 19
Load-settlement curves for case 12 - L=5m; t=0.4m

Figure 20
Load-settlement curves for case 13 - L=6m; t=0.1m

Figure 21
Load-settlement curves for case 14 - L=6m; t=0.2m

Figure 22
Load-settlement curves for case 15 - L=6m; t=0.3m

Figure 23
Load-settlement curves for case 16 - L=6m; t=0.4m

The maximum test loads were established for each piled raft to obtain approximately 50 mm of displacement, conventionalizing the geotechnical “failure” of the foundation by one of the limit states. As a failure criterion for ultimate resistance, according to the recommendations from the British Standard BS 8004:2015 [²⁸28 British Standard. Code of Practice for Foundations Foundations, BS 8004:1986, 2004.], the displacement assumed was of 10% of the pile diameter or 25 mm.

The load settlement curves show a greater pile share in the load capacity of the foundation system for 0.10-m thick rafts. The contribution of the pile is reduced for rafts with thickness of 0.20 m or more. On the other hand, in all cases analyzed, the participation of the raft-soil contact is preponderant in comparison to the pile participation. Such evidence can be attributed to the high raft contribution area in the overall bearing capacity. The following curves are basically distinguished by the characteristics of the raft-soil stiffness, i.e., for rafts considered flexible (0.10 m in height) and rigid (> 0.20 m).

5.2 Influence of raft thickness on shaft resistance of piles

The effect of raft thickness on the portion of total load supported by total shaft resistance of piles (Figure 24). The 0.10-m thick rafts influenced positively the mobilization of skin friction, compared to models with 0.20 m, 0.30 m, 0.40 m thicknesses: differences between 14% and 30% can be seen. In addition, with increasing loads, rafts thicker than 0.10 m led to minor load sharing by the pile due to little toe resistance and to greater participation of the raft. During the loading test with piled rafts instrumented and described by Garcia [⁹9 J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.], the values measured for total toe resistance were around 6% of the total load applied to the foundation, even at displacement levels of approximately 20% of the pile diameter. In all cases, the axial load reaching the pile toe was less than 2% of the total load, even for large relative displacements, close to 20% of the pile diameter (50 mm). The behavior of the piles compares to that of floating piles, which orient their resistance predominantly to the shaft. Such values imply that the model represents adequately a short bored pile of small diameter inserted in uniform soil.

Figure 24
Portion of the maximum load taken by the total shaft resistance.

6 RESPONSE AND BEHAVIOR ANALYSES

The choice of geometric parameters to evaluate the interaction among the soil, raft and pile is based on previous works in the literature on piled foundations, among which, those of Poulos and Davis [²2 H. G. Poulos and E. H. Davis, Pile Foundation Analysis and Design. Rainbom-Bridge Book Co., 1980.], Kuwabara [¹⁰10 F. Kuwabara, "An elastic analysis for piled raft foundations in a homogeneous soil," Soil Found., vol. 29, no. 1, pp. 82–92, Mar 1989, http://dx.doi.org/10.3208/sandf1972.29.82.
http://dx.doi.org/10.3208/sandf1972.29.8... ] and Clancy and Randolph [¹⁸18 P. Clancy and M. F. Randolph, "Simple design tools for piled raft foundations," Geotechnique, vol. 46, no. 2, pp. 313–328, Jun 1996, http://dx.doi.org/10.1680/geot.1996.46.2.313.
http://dx.doi.org/10.1680/geot.1996.46.2... ].

The behavior analyses regarding relative stiffness were established with respect to the pile slenderness ratio (L/d), and the ratio between raft thickness and pile diameter (t/d). Based on the parametric characteristics and properties of the mechanical behavior of foundations under analysis, this work seeks to correlate the favorable features to the appropriate design elaboration, supporting premises for a qualitative evaluation for conception and predesign of foundation elements of superstructures.

6.1 Initial Stiffnesses of Piled Rafts

For the 16 cases analyzed, the stiffness of piled rafts foundations (K_{piled raft}) and their elements (K_pile e K_raft) were calculated by means of the loading and displacement values obtained in the first stages (i.e., up to 50% of the maximum load of a given foundation (Q_max), and therefore, the structural elements exhibit a linear elastic behavior and they have a good potential to be used in practical applications.

The increase in raft thickness for a constant diameter (t/d) does not influence the increase in stiffness of the piled raft unit, which remains almost constant for the same pile slenderness ratio (Figure 25a). On the other hand, for a higher pile slenderness ratio, there is an increase in relative stiffness of the piled rafts under analysis, showing that the isolated stiffness of the pile (Figure 25b) is directly related to its slenderness ratio (L/d). The raft stiffness is small for flexible rafts (t/d = 0.4), but it remains almost constant for rafts considered as rigid (t/d ≥ 0.8) (Figure 25c). The models with 0.1-m thick rafts (t/d = 0.4) allow greater pile response, since the surface element has lower capacity to restrain displacements due to its lower stiffness.

Figure 25
Effect of t/d ratio on piled raft, pile and raft responses

When analyzing the influence of the use of longer piles connected to thicker rafts, it was found that piled raft stiffness is predominantly influenced by pile stiffness and its slenderness ratio (Figures 25 and 26). For rafts considered rigid (t/d ≥ 0.8), the raft response is practically uniform for different values of pile slenderness (L/d), while the contribution to pile stiffness and overall stiffness is linearly increasing. Distinct behavior is observed for rafts considered flexible (t/d= 0.4), in which raft stiffness (K_r) decreases linearly with increasing ratio L/d This is explained by the increasing pile stiffness (K_p), as seen in Figure 26b and Figure 26c.

Figure 26
Effect of L/d ratio on piled raft, pile and raft responses.

6.2 Settlement Reduction and Load Sharing

A comparison of the effects of using piles combined with rafts shows that rafts of heights equal to 0.1 m are more sensitive to distribution of loads among the foundation elements, thus increasing the load portion supported by the piles.

Based on the analyses carried out and considering the reduced settlement in the piled foundation (Figure 27), it is verified that increasing raft thickness has little influence on the reduction of its total settlement (s_pr), when compared to those of unpiled rafts (s_r). The insertion of piles in the raft and the increase in pile length leads to a significant reduction of the total settlement of the piled raft, for all thicknesses analyzed.

Figure 27
Evaluation of settlement reduction and load sharing for the piled rafts (at 50% of Q_max).

The load sharing in the analyzed models increases with the increase of raft thickness, whose values varied from 28% to 45% (Table 3) for the cases of rigid rafts (t ≥ 0.2 m). On other hand, based on the average of the coefficient α_s values, the total settlements presented 44% to 78% reduction when compared to isolated rafts, showing the efficiency of the pile insertion. In the cases analyzed in this work, the piles were positioned at the point of occurrence of the greatest displacement, i.e., the central region of the raft.

Thumbnail

Table 3
Results from the evaluation of the piled raft units.

The results above agree with the propositions given in De Sanctis et al. [²⁹29 L. De Sanctis, A. Mandolini, G. Russo, and C. Viggiani, “Some remarks on the optimum design of piled rafts,” Deep Foundations., vol. 132, no. 12, pp. 405–425, Feb. 2002, http://dx.doi.org/10.1061/40601(256)30.
http://dx.doi.org/10.1061/40601(256)30... ] about what occurs in “small rafts” where the ratio is D/L <1. According to the classification of these authors, a “small” isolated raft does not have enough bearing capacity to support the total load, thus requiring the insertion of piles to ensure reduced settlement. It also improves the bearing capacity of the system. In this case, differential settlement is not essential for rafts considered as rigid since the raft in this situation has enough flexural stiffness.

7 CONCLUSIONS

The determination of parameters through numerical validation of experimental tests is an important tool to study the behavior of piled foundations, since it is possible to assess the interaction between the elements, by means of an appropriate modeling. A careful check is required during the modeling to verify if the conditions observed in the field can be implemented in the numerical model.

For a t/d ratio equal to or higher than 0.8 (t = 0.2 m), there is no increase in the overall initial response, although it is possible to reach a load sharing on the pile equal to 28% to 45% of the total applied load and a 44% to 78% reduction in piled raft settlements compared to those of unpiled rafts.

The pile length has a greater influence on the initial stiffness of the piled raft than the raft thickness. Models with 0.10 m raft thickness positively modified the axial response of the pile, and from the thickness of 0.20m, the models uniformed their behaviors, meaning more distant from the “flexible” raft condition pointed out by Clancy and Randolph [¹²12 P. Clancy and M. F. Randolph, "An approximate analysis procedure for piled raft foundations," Int. J. Numer. Anal. Methods Geomech., vol. 17, no. 12, pp. 849–869, Dec 1993, http://dx.doi.org/10.1002/nag.1610171203.
http://dx.doi.org/10.1002/nag.1610171203... ].

The results of the present study showed good agreement with key points emphasized by El-Mossallamy, Lutz and Duerrwang [³⁰30 Y. M. El-Mossallamy, B. Lutz, and R. Duerrwang, “Special aspects related to the behavior of piled raft foundation,” Proc. 17th Int. Conf. Soil Mech. Geotech. Eng. Acad. Pract. Geotech. Eng., vol. 2, pp. 1366–1369, 2009, http://dx.doi.org/10.3233/978-1-60750-031-5-1366.
http://dx.doi.org/10.3233/978-1-60750-03... ] regarding the confinement caused by raft-soil contact that increases the stress in the region near the top of the pile, and also on the effects of interaction between the elements, for example the load sharing, that has been shown to be dependent on the level of loading.

The results here reported are valid for application under conditions similar to those conducted by this research, and therefore, it cannot be considered a generalized approach.

ACKNOWLEDGEMENTS

The authors would like to thank the Federal University of Uberlândia for the acquisition of the software license used in the analyses of this work and Professor Michael Andrade Maedo for his technical contribution. This work was supported by a FAPEMIG grant funded by the State of Minas Gerais and Coordination for the Improvement of Higher Education Personnel (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES) financing code 001.

Financial support: This work was supported through a FAPEMIG grant funded by the State of Minas Gerais and Coordination for the Improvement of Higher Education Personnel (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES) financing code 001.
Data Availability: The data that support the findings of this study are available from the corresponding author, JRG, upon reasonable request.

REFERENCES

¹
T. Whitaker, "Experiments with model piles in groups," Geotechnique, vol. 7, no. 4, pp. 147–167, Dec 1957, http://dx.doi.org/10.1680/geot.1957.7.4.147
» http://dx.doi.org/10.1680/geot.1957.7.4.147
²
H. G. Poulos and E. H. Davis, Pile Foundation Analysis and Design. Rainbom-Bridge Book Co., 1980.
³
J. E. Bezerra, R. P. Da Cunha, and M. M. Sales, “Optimization concepts for the design of piled raft foundation systems Optimisation concepts pour le projet de fondation en Radier sur piex,” in Proc. 16th Int. Conf. Soil Mech. and Geotech. Eng., 2005, pp. 1947–1950, http://dx.doi.org/10.3233/978-1-61499-656-9-1947
» http://dx.doi.org/10.3233/978-1-61499-656-9-1947
⁴
J. R. Garcia and P. J. R. de Albuquerque, "Analysis of the contribution of the block-soil contact in piled foundations," Lat. Am. J. Solids Struct., vol. 16, no. 6, pp. 1–22, 2019, http://dx.doi.org/10.1590/1679-78255565
» http://dx.doi.org/10.1590/1679-78255565
⁵
R. Butterfield and P. K. Banerjee, "The problem of pile group–pile cap interaction," Geotechnique, vol. 21, no. 2, pp. 135–142, Jun 1971, http://dx.doi.org/10.1680/geot.1971.21.2.135
» http://dx.doi.org/10.1680/geot.1971.21.2.135
⁶
M. Ottaviani, "Three-dimensional finite element analysis of vertically loaded pile groups," Geotechnique, vol. 25, no. 2, pp. 159–174, 1975, http://dx.doi.org/10.1680/geot.1975.25.2.159
» http://dx.doi.org/10.1680/geot.1975.25.2.159
⁷
P. T. Brown and T. J. Wiesner, "The behaviour of uniformly loaded piled strip footings," Soil Found., vol. 15, no. 4, pp. 13–21, Dec 1975, http://dx.doi.org/10.3208/sandf1972.15.4_13
» http://dx.doi.org/10.3208/sandf1972.15.4_13
⁸
M. F. Randolph, “Design methods for pile groups and piled rafts,” in Int. Conf. Soil Mech. and Found. Eng., 1994, pp. 61–82.
⁹
J. R. Garcia, “Análise experimental e numérica de radiers estaqueados executados em solo da região de Campinas/SP,” Ph.D. dissertation, Univ. Estadual de Campinas, 2015.
¹⁰
F. Kuwabara, "An elastic analysis for piled raft foundations in a homogeneous soil," Soil Found., vol. 29, no. 1, pp. 82–92, Mar 1989, http://dx.doi.org/10.3208/sandf1972.29.82
» http://dx.doi.org/10.3208/sandf1972.29.82
¹¹
A. Saeedi Azizkandi, H. Rasouli, and M. H. Baziar, "Load sharing and carrying mechanism of piles in non-connected pile rafts using a numerical approach," Int. J. Civ. Eng., vol. 17, no. 6, pp. 793–808, 2019., http://dx.doi.org/10.1007/s40999-018-0356-2
» http://dx.doi.org/10.1007/s40999-018-0356-2
¹²
P. Clancy and M. F. Randolph, "An approximate analysis procedure for piled raft foundations," Int. J. Numer. Anal. Methods Geomech., vol. 17, no. 12, pp. 849–869, Dec 1993, http://dx.doi.org/10.1002/nag.1610171203
» http://dx.doi.org/10.1002/nag.1610171203
¹³
G. Russo and C. Viggiani, “Factors controlling soil structure interaction for piled rafts,” in Int. Conf. Soil-Structure Interaction, Darmstadt University of Technology, 1998, http://dx.doi.org/10.13140/2.1.4035.7125
» http://dx.doi.org/10.13140/2.1.4035.7125
¹⁴
R. Katzenbach and D. Choudhury, Combined Pile-Raft Foundation Guideline, Darmstadt: Institute and Laboratory of Geotechnics, 2013.
¹⁵
H. Poulos, “Methods of analysis of piled raft foundations,” Int. Soc. Soil Mech. Geotech. Eng., no. July, pp. 46, 2001.
¹⁶
A. Mandolini, G. Russo, and C. Viggiani, “Pile Foundations : Experimental Investigations, Analysis and Design,” in Proceedings of the 16th International Conference on Soil Mechanics and Geotechnical Engineering: Geotechnology in Harmony with the Global Environment, Osaka, Japan, 2005, vol. 1, no. 2003, pp. 177–213.
¹⁷
J. Lee, D. Park, D. Park, and K. Park, "Estimation of load-sharing ratios for piled rafts in sands that includes interaction effects," Comput. Geotech., vol. 63, pp. 306–314, Jan 2015, http://dx.doi.org/10.1016/j.compgeo.2014.10.014
» http://dx.doi.org/10.1016/j.compgeo.2014.10.014
¹⁸
P. Clancy and M. F. Randolph, "Simple design tools for piled raft foundations," Geotechnique, vol. 46, no. 2, pp. 313–328, Jun 1996, http://dx.doi.org/10.1680/geot.1996.46.2.313
» http://dx.doi.org/10.1680/geot.1996.46.2.313
¹⁹
O. A. Abdel-Azim, K. Abdel-Rahman, and Y. M. El-Mossallamy, "Numerical investigation of optimized piled raft foundation for high-rise building in Germany," Innov. Infrastruct. Solut., vol. 5, no. 1, pp. 11, Apr 2020., http://dx.doi.org/10.1007/s41062-019-0258-4
» http://dx.doi.org/10.1007/s41062-019-0258-4
²⁰
R. Katzenbach, U. Arslan, and C. Moormann, “13. Piled raft foundation projects in Germany,” in Design applications of raft foundations, Thomas Telford Publishing, 2000, pp. 323–391.
²¹
V. Fioravante, D. Giretti, and M. B. Jamiolkowski, “Physical modelling of piled raft,” in Deep Foundations on Bored and Auger Piles, W. F. Van Impe and P. O. Van Impe, Eds. Routledge, 2009.
²²
F. A. De Cock, “Sense and sensitivity of pile load-deformation behaviour,” in Deep Foundations on Bored and Auger Piles, W. F. Van Impe and P. O. Van Impe, Eds. 2009.
²³
V. Caputo, “Experimental evidence for the validation of load-settlement predictions,” 2003.
²⁴
M. W. O’Neill and L. C. Reese, Behavior of Axially Loaded Shafts in Beaumont Clay, Part Four Design Inferences and Conclusions, Center for Highway Research, the University of Texas at Austin, 1970.
²⁵
A. S. Vesic, “Design of pile fundations: National Cooperative Highway Research Program, Synthesis Highway Practice,” Report No. 42, Transportation Research Board National Academy of Sciences, 1977.
²⁶
Q.-Q. Zhang, Z.-M. Zhang, and S.-C. Li, "Investigation into Skin friction of bored pile including influence of soil strength at pile base," Mar. Georesour. Geotechnol., vol. 31, no. 1, pp. 1–16, Jan 2013., http://dx.doi.org/10.1080/1064119X.2011.626506
» http://dx.doi.org/10.1080/1064119X.2011.626506
²⁷
D. H. Ardiaca, “Mohr-Coulomb parameters for modelling of concrete structures,” Plaxis Bull., pp. 12–15, 2009.
²⁸
British Standard. Code of Practice for Foundations Foundations, BS 8004:1986, 2004.
²⁹
L. De Sanctis, A. Mandolini, G. Russo, and C. Viggiani, “Some remarks on the optimum design of piled rafts,” Deep Foundations, vol. 132, no. 12, pp. 405–425, Feb. 2002, http://dx.doi.org/10.1061/40601(256)30
» http://dx.doi.org/10.1061/40601(256)30
³⁰
Y. M. El-Mossallamy, B. Lutz, and R. Duerrwang, “Special aspects related to the behavior of piled raft foundation,” Proc. 17th Int. Conf. Soil Mech. Geotech. Eng. Acad. Pract. Geotech. Eng., vol. 2, pp. 1366–1369, 2009, http://dx.doi.org/10.3233/978-1-60750-031-5-1366
» http://dx.doi.org/10.3233/978-1-60750-031-5-1366

Edited by

Editors: José Marcio Calixto, Guilherme Aris Parsekian.

Publication Dates

Publication in this collection
18 Feb 2022
Date of issue
2022

History

Received
14 Jan 2021
Accepted
12 Jan 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Financial support: This work was supported through a FAPEMIG grant funded by the State of Minas Gerais and Coordination for the Improvement of Higher Education Personnel (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES) financing code 001.

[2] Data Availability: The data that support the findings of this study are available from the corresponding author, JRG, upon reasonable request.

Material	E (MPa)	ν	K₀	γ (kN/m³)	Model	ϕ (º)	c (kPa)
Soil	30.0	0.33	0.8	15	Elastoplastic	21	22
Soft material	5e-2	0.40	0.8	15	Elastoplastic	3	0
Concrete	30,100	0.20	-	25	Elastic	50	300

L/d	$α_{p r}$ (t=0.1m)	$\bar{X} (α_{p r})$ (t=0.2m;0.3m;0.4m)	Increasing % in the pile load $Δ α_{p r} (%)$	Total settlement reduction
12	0.44	0.28	16%	44%
16	0.56	0.33	23%	59%
20	0.67	0.40	27%	70%
24	0.76	0.45	31%	78%

Brasil

Brasil

Numerical analysis of piled rafts with short bored piles

Análise numérica de radier estaqueado com estaca escavada curta

Abstract

Resumo

1 INTRODUCTION

1.1 Previous works

1.2 Some concepts on piled rafts

1.3 Effect of rafts on skin friction and axial force

1.4 Bored piles

2 VALIDATION WITH EXPERIMENTAL STUDY

3 PARAMETRIC ANALYSIS

4 NUMERICAL ANALYSIS

5 RESULTS AND DISCUSSION

5.1 Load settlement curves

5.2 Influence of raft thickness on shaft resistance of piles

6 RESPONSE AND BEHAVIOR ANALYSES

6.1 Initial Stiffnesses of Piled Rafts

6.2 Settlement Reduction and Load Sharing

7 CONCLUSIONS

ACKNOWLEDGEMENTS

REFERENCES

Edited by

Publication Dates

History

Case	D_r (m)	t (m)	L (m)	d (m)	L/d	t/d	Stress applied (kPa)	Load applied (kN)
1	1.25	0.1	3	0.25	12	0.4	264	324.0
2		0.2		0.25		0.8	284	348.5
3		0.3		0.25		1.2	300	368.2
4		0.4		0.25		1.6	310	380.4
5	1.25	0.1	4	0.25	16	0.4	293	359.6
6		0.2		0.25		0.8	310	380.4
7		0.3		0.25		1.2	328	402.5
8		0.4		0.25		1.6	336	412.3
9	1.25	0.1	5	0.25	20	0.4	320	392.7
10		0.2		0.25		0.8	340	417.2
11		0.3		0.25		1.2	352	432.0
12		0.4		0.25		1.6	370	454.1
13	1.25	0.1	6	0.25	24	0.4	350	429.5
14		0.2		0.25		0.8	371	455.3
15		0.3		0.25		1.2	380	466.3
16		0.4		0.25		1.6	390	478.6