This paper proposes a numerical simulation of the mechanical behavior of a reinforced concrete pile foundation under an axial load. In fact, the foundation of a structure represents the essential structural part of it, because it ensures its bearing capacity. Among the types of foundation, deep foundation is the one for which from a mechanical point of view, the justification takes into account the isolated or combined effects of base resistance offered by the soil bed and lateral friction at the soil-pile interface; the latter being the consequence of a large contact surface with the surrounding soil; hence the need to study the interaction between the soil and the pile in service, in order to highlight the characteristics of soil which influence the mechanical behavior of pile and therefore the stability of the structure. In this study, the reinforced concrete pile is supposed to be elastic, and characterized by a young’s modulus (E) and a Poisson’s ratio ( ν ). The soil obeys to a Camclay model characterized by a cohesion (c), an initial voids ratio ( e 0 ), shearing resistance angle ( φ ) and a pre-consolidation pressure ( P 0 ). A joint model with a Mohr Coulomb behavior characterizes the soil-pile interface. The loading is carrying out by imposing a vertical monotonic displacement at the head of pile. The results in terms of stress and displacement show that the bearing capacity of the pile is influenced by various soils characteristics, it appears that the vertical stress and the force mobilized at rupture increase when the initial pre_consolidation pressure, the cohesion and the internal friction angle of soil increase; and when the initial soil voids index decreases.
The foundation is the interface between the structure and the soil. It aims to distribute the weight of the structure over a large area in order to avoid of the soil plasticization, to anchor the structure against horizontal forces, to prevent lateral and vertical movements of the structure. There are two types of reinforced concrete foundation: the shadow and deep foundation. The first class of foundation is embedded at a deep less than two meters and is used when the soil at this level has good properties to avoid mechanical overstress and inadmissible settlement. The second one is used when the conditions of the shadow foundation are not satisfied. In this case, the level of the appropriate soil is deeper. It consists of a pile embedded in the soil with a length, which can vary from three to more than fifty meters depending on the project. The bearing capacity of the pile depends on its diameter, its length together with lateral friction between the soil and the pile, and the base resistance offered by the soil bed. The aim of the present paper is to analyze the interaction between a reinforced concrete pile and the soil in which it is embedded. Several studies have been carried out in this area, especially to highlight the influence of soil characteristics on pile behavior. Kavitha and others [
The study of mechanical behavior of pile subjected to monotonous axial loading will be done with CASTEM, 2017 version, developed by CEA Saclay in DEN/DM2S/SEMT. This code has as particularity the fact that it makes use of an object-oriented meta-language called “GIBIANE”. The method is based on finites elements. It is considered as the most powerful tool in numerical modeling of soil-structure interaction, because of several advantage as: the possibility of using different boundaries conditions and combine loading, the versatility of the method which allows for modeling different pile and soil geometries, the possibility of finding solutions at each element and node in the mesh thanks to discretization of model into small entities, possibility to model different types of soil models and various material behavior for pile, and the continuity of the soil behavior can be taken into account. The method consists in defining an optimal geometry and mesh, a model of mechanical behavior for each component of the geometry, initial and boundary conditions, and finally mechanical loading.
The finite elements chosen are tri6 according to CASTEM software that means:
triangle with 6 nodes and 2 degrees of freedom per node (UX; UY), for the meshes of the soil and the pile. The resolution being performed at the nodes of the mesh, it thus makes it possible to densify the node in the geometric model and to approach as well as possible the real solution. The mesh is narrowed in the soil-pile contact zone as shown in
The soil has and elastoplastic behavior with modified Camclay’s plasticity criterion. This behavior model is based on two concepts, limit sate and critical state. It postulates the existence of a limit state curve and a critical state to describe the elastoplastic behavior with isotropic hardening of soils normally consolidated, under homogeneous solicitations [
F ( σ ) = q 2 + M 2 ( P ′ 2 − P ′ P ′ c ) (1)
P ′ and q represent the spherical and deviatoric parts of the stress tensor; and P ′ c the pre-consolidation pressure given according to Khemissa [
q = ( ( σ 1 − σ 2 ) 2 + ( σ 1 − σ 3 ) 2 + ( σ 2 − σ 3 ) 2 ) / 2 (2)
P ′ = t r a c e [ σ ¯ ] (3)
P ′ c = P ′ c 0 exp [ ( ( 1 + e i ) / ( λ − k ) ) ε v p ] (4)
e i represents the initial voids ratio of soil (which is replaced by the ratio of preexisting voids e 0 for structural computations). P ′ c 0 is the initial pre-consolidation pressure, λ the slope of the loading curve for a normally consolidated state and k the slope of the unloading-reloading curve for an over-consolidated state. ε v p the plastic components of strain. The slope of the critical state line M in the (p', q) plane or the coefficient of friction defined by Equation (5), where M is the ratio of the stress deviator q to the mean effective stress p' at the critical state. It is determined by a triaxial compression test and defined by Equation (6), according to Roscoe and Burland [
q = M P ′ (6)
M is also the line representing the critical shear behavior of the soil, where the deformations continue to develop without changing the state of stress.
M = 6 sin φ / ( 1 − sin φ ) (7)
φ is the internal friction angle of the soil.
The elastic law associated with this criterion is charactarized by the Young modulus E, and the poisson’s ratio υ (assumed constant). They are taken into account by non-linear volumic compressibility K and shear modulus G, given according to Roscoe and Burland [
K = ( ( 1 + e i ) / k ) P ′ (8)
G = [ 3 ( 1 − 2 υ ) / 2 ( 1 + υ ) ] K (9)
The numerical values associated to CamClay model parameters are taken into account as in Khemissa’s study [
The pile is considered very rigid with respect to the ground; it follows an isotropic linear elastic constitutive law, of constant parameters, defined by Equation (10).
σ = E ⋅ ε (10)
With E the Young’s modulus, ε the strain and the stress.
The zero-thickness element approach was used to model the joint at the soil-pile interface. This element follows the elastoplastic constitutive law, with Mohr-Coulomb’s plasticity criterion and associated flow (Coulomb model implemented in CASTEM). The scalar function associated with this model is given by the load function f such that:
f ( σ n , τ ) = | τ | − σ n tg ϕ + c (11)
With c, φ, respectively the cohesion and the internal friction angle at the soil-pile interface. σ n and τ the normal and shear stress.
Mechanical blockages are applied to the soil and pile geometries as shown in
Assuming that the embodiment of the concrete pile is not taken into account, the loading of the structure takes place at the pile head as shown in
Since the computation is stepwise, the displacement increment is defined by a monotonic curve as a function of the increment of time shown in
U i + 1 = U i + Δ U (12)
where Δ U is the displacement increment, following a monotonic curve; U i + 1 displacement imposed at i + 1 time index and U i + 1 displacement imposed at i time index.
The finite element calculation will be done step by step using the dgibi programming language of CASTEM. The results will be extracted at the nodes and elements of the mesh as located in
In order to highlight the influence of soil characteristics on mechanical pile behavior, graphs of Figures 6-11 respectively show the stress-displacement curves at the head of the pile and the overall force-displacement of the pile; these curves are qualitatively consistent with the results of Roméo Francis [
The evolutions of graphs of
Graphs of
The evolutions of the graphs as shown in
The numerical study of the mechanical behavior of a pile subjected to a monotonous axial loading was proposed in this paper, using the finite element method via CASTEM software. The influence of soil characteristics on the mechanical behavior of the pile in service has been highlighted, and it appears that the vertical stress and the force mobilized at rupture increase when the initial pre_consolidation pressure, cohesion and the angle of friction of soil increase; and when the initial soil voids ratio decreases. These results are important in the design and realization of piles, to ensure a good bearing capacity of the pile, and therefore a better resistance and stability of the structures.
The authors declare no conflicts of interest regarding the publication of this paper.
Nde, N.M., Fokwa, D., Mbessa, M., Tamo, T.T. and Pettang, C. (2020) Numerical Study of the Interaction between a Reinforced Concrete Pile and Soil. Open Journal of Civil Engineering, 10, 259-269. https://doi.org/10.4236/ojce.2020.103022