Uplift Capacity of Shallow Anchors Based on the Generalized Nonlinear Failure Criterion

Jin-feng, Zou; Ming-yao, Xia

doi:https://doi.org/10.1155/2016/3082047

Mathematical Problems in Engineering

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Research Article | Open Access

Volume 2016 | Article ID 3082047 | https://doi.org/10.1155/2016/3082047

Uplift Capacity of Shallow Anchors Based on the Generalized Nonlinear Failure Criterion

Zou Jin-feng¹and Xia Ming-yao¹

Academic Editor: Stefan Balint

Received23 Nov 2015

Revised28 Feb 2016

Accepted13 Mar 2016

Published17 Apr 2016

Abstract

The shape of rapture surface for shallow anchors was presented and the effects of parameters on the shape of rapture surface were analyzed. Based on the generalized nonlinear failure criterion and the limit equilibrium principle, an approach, which takes into account the shape of rapture surface, dip angle of shallow anchors, and varieties of rock and soil mass, is proposed. The effects of different parameters on ultimate uplift force of shallow anchors are discussed. In order to validate the practicability of the proposed formula, a comparison between the theoretical solutions and local test results is conducted. The agreement shows that the proposed formula is effective. The results of the proposed approach show that the ultimate uplift capacity of shallow anchor increases nonlinearly with the shape coefficient linearly increasing. The values of ultimate uplift force local test are in the range of the results of the proposed method with shape coefficient from 0 to 1.

1. Introduction

The design of shallow anchors is still empirical so far, especially the ultimate pullout capacity. A common method to verify partly the shallow anchor design is the pullout test but it is difficult and expensive; and the working conditions of the rock and soil mass around the shallow anchor are always unknowable. As the range of applications for shallow anchor expands, a greater understanding of their behaviors including the ultimate pullout capacity is required. In order to improve the shallow anchor design, it is necessary to have a good understanding about the calculation of the ultimate pullout capacity in the shallow anchor, especially for the important engineering applications. The ultimate pullout capacity of shallow anchor in rock and soil mass is helpful for the design because the ultimate pullout capacity provides the essential information related to the working status of the shallow anchor, which is a reasonable basis for the adjustment of the design.

Analysis of the ultimate pullout force of shallow anchors in rock and soil mass is required in a wide variation of geotechnical, petroleum, and mining engineering problems such as in the design of boreholes and mine shafts. Reviews of those contributions may be found in published journal [1–7]. In most of the past analyses reported, the rock and soil mass was conventionally assumed to be governed by a linear Mohr-Coulomb yield criterion. However, the experimental results show that the intermediate principal stress is the important characteristic of rock and soil mass. In many practical situations, for instance in a jointed rock mass and crash rock mass, such yield criteria may not be justified and a nonlinear yield criterion such as generalized nonlinear failure criterion would be more appropriate [8–13]. On the other hand, the interaction mechanism between the shallow anchors and the rock and soil mass is not well understood. The shallow anchor has been commonly determined based on local observations and on empirical approaches. In order to estimate the capacity and displacement of shallow anchor, most of reports presented by some scholars are based on the Mohr-Coulomb failure criterion and linear geometric failure surface in sand. For instance, Vanitha et al. proposed an analytical model to predict the net uplift capacity of pile group anchors with limit equilibrium method and truncated cone model based on the experiment investigations [6]. Hanna et al. presented an analytical model to predict the pullout capacity and the load-displacement relationship for shallow single vertical helical and plate anchors, with the assumption that failure mechanism consisted of logarithmic spiral rupture in sand [14]. Based on the failure surface of straight line originating from the edge of the strip anchor at an angle, Deshmukh et al. [15] proposed a theoretical analysis of net uplift capacity of horizontal strip anchor in cohesionless soil using Koiter’s equation. At the same time, he presented another model for the pile anchors with the failure surface of cone frustum in cohesionless soil. Choudhury and Subba Rao [16] proposed a semianalytical method for the net uplift capacity with the log-spiral failure surface and pseudostatic seismic forces. At the same time, various research methods have been used to study the bearing behavior of anchor, especially for the displacement and deformation of anchor. For example, Farmer [17] presented the engineering character of anchors instrumented in concrete, limestone, and chalk by using the theoretical and numerical methods and local test. Cai et al. [5] proposed a method for anchors to analyze the interaction behavior of the rock bolt and the surrounding rock mass based on an improved Shear-Lag Model. Abramento and Whittle [18] presented a new analysis method to predict the tensile stress distribution and load-elongation response for identifying four successive phases in the pullout response performed on thin, extensible, and planar soil reinforcements. Serrano and Olalla [19] proposed a method for the tensile resistance of rock anchors with the published rupture surface shape based on the Hoek-Brown failure criterion.

Besides those, although researches of failure surface shape have been presented by most published papers, the failure surface shape for shallow anchor is effective with certain conditions [20–22]. For instance, Mariupol’skii [23] proposed a method for calculating the ultimate capacity of anchor foundations based on the rapture surface deduced from test results. Deshmukh et al. [15] presented an analysis method for net uplift capacity of horizontal strip anchor in cohesionless soil with the Kotter’s equation based on the assumption that a plane failure surface inclined at a characteristic angle with the ground surface. Based on the failure rapture of laboratory test for shallow single vertical helical and plate anchors in sand, Hanna et al. [14] presented a model to predict the pullout capacity and the load-displacement relationship with the limit equilibrium technique.

In order to overcome the above defections, an analytical model based on an introduced model for shallow anchor is developed. The presented model is based on the proposed shape of failure rapture. A back analysis method was proposed to calculate the ultimate pullout capacity and the effect of parameters on the ultimate pullout capacity. The analysis of parameters for rapture surface shape and ultimate pullout capacity was conducted.

2. Analysis of Failure Mechanism for Uplift Piles

The failure surface shape and the failure mechanism in different rock and soil mass have been studied by many researchers and most of assumptions for rupture surface shape of shallow anchor subjected to limit load were presented. Published data and test results have been summarized and studied by Zou et al. [24]. A new rapture surface shape for shallow anchor subjected to a vertical force is developed considering the following boundary condition: at the surface failure outlet, the angle between the failure surface and the ground surface is ; and a parameter equation of failure surface shape for shallow anchor has been proposed as shown in Figure 1.

The parameter equation of failure surface shape for shallow anchor can be expressed aswhere is the radius of shallow anchor, is the friction angle of rock and soil mass, is the length of shallow anchor, and is parameters of failure surface shape.

As , , and , the failure surface in (1) is , , and in Figure 1, respectively.

The effect of parameters on failure surface shaped is shown in Figures 2–7 corresponding to m, m, °, and .

It can be seen from Figures 2–7 that (1) the failure surface shape will be narrowing with increasing and will be widening with or increasing; (2) the parameter has no significant effect on failure surface shape with increasing; (3) the failure surface shape will be widening with or increasing as m and °; and (4) the failure surface shape will be widening with or increasing as and °.

3. Generalized Nonlinear Failure Criterion

Although the Mohr-coulomb and Hoek-Brown failure criterion is adopted by most researchers [25–32], the intermediate principal stress is not considered. According to the literature [8], the generalized nonlinear failure criterion can be expressed as in Figure 8.

And the failure criterion is given:where is the three-dimensional extension strength and () is the failure stress ratio under a given reference pressure . For frictional materials, the range of frictional angle is 0°–90° and the corresponding range of is . is the material constant reflecting the influence of mean principal stress on strength, . and are the positive and shear stress on the cut surface, respectively.

4. Ultimate Pullout Capacity

Taking the shallow anchor as an example, the analysis model of shallow anchor subjected to pullout load is shown in Figure 9. The rock and soil mass is assumed to be homogeneous and isotropic and behaves as an elastic-plastic material and obeys the generalized nonlinear failure criterion.

The balance equilibrium of the infinitesimal element is scratched in Figure 9 in terms of the balance of the infinitesimal element for the anchor, the surrounding rock and soil mass, and the matrix together with the reinforcement in the Cartesian coordinate system, respectively; the equilibrium equation of vertical forces of the infinitesimal section in the failure region is expressed as follows based on the theory of limit equilibrium and the equation for rupture surface shape:where is the soil unit weight, is the depth of infinitesimal element, is the increment of vertical antipull load for the infinitesimal element, is the uniformly distributed load on the infinitesimal element, is the radius at the bottom of the infinitesimal element, is difference value of the radius between the upper and bottom surface of the infinitesimal element, is the tangential stress on the failure surface, and is the normal stress on the failure surface, which is expressed aswhere is the lateral pressure coefficient of the soil mass and is the vertical distance from the anchor plate to the infinitesimal section.

According to equilibrium conditions of vertical force for infinitesimal element, can be obtained as follows:

Ignoring the higher order terms of differentiation and taking limit equilibrium equation (3), the following expression is derived by :

According to Figure 9, and are obtained. Substituting (2) and (4) into (6), the vertical antipull load increment at an arbitrary depth can be given by the following equation:where , , and .

The above equation may be solved by integrating from 0 to , and the formulation of ultimate pullout load for shallow anchor can be expressed as

As , the shallow anchor will be destroyed along the contact surface between the slurry wall and the hole; its fracture surface will be the type as shown in Figure 1. According to (8), the ultimate pullout load of shallow anchor can be given aswhere is the ultimate pullout load, is the maximum between rock and soil pressure and the grouting pressure for calculation, and is the anchor diameter.

The effects of parameters on the characteristic of ultimate pullout load are shown in Figures 10–17 with respect to m, , , m, , , kPa, , kPa, and kPa.

It can be seen from Figure 10 that ultimate pullout load will increase nonlinearly with increasing and will increase with increasing.

Figure 11 shows that ultimate pullout load will decrease nonlinearly with increasing as , will be a constant as , and will increase linearly as .

It is shown from Figure 12 that ultimate pullout load will be increased nonlinearly with increasing and will be increased with increasing.

It can be found from Figure 13 that ultimate pullout load will increase nonlinearly with increasing and will be increasing with increasing.

It is revealed from Figure 14 that the ultimate pullout will increase with increasing, will decrease as °, and then will increase as °.

It can be found from Figure 15 that the ultimate pullout will increase with or increasing, especially for and m.

Figure 16 shows that the ultimate pullout load will increase nonlinearly with increasing, and there is no significant effect of on the ultimate pullout load.

It can be seen from Figure 17 that the ultimate pullout load will increase with and increasing as .

Generally speaking, there is a significant effect of , , , , and on ultimate pullout load from Figures 10–17.

5. Comparison of Theoretical and Local Test Results

In order to validate the reliability of the proposed method, a model and a pier uplift pile test data were taken as examples for comparison. The results of the proposed method and local test are shown in Table 1 corresponding to (1) m, m, °, kN/m³, , kPa, , and ; the experiment results of ultimate capacity are 332.5 kN and 341.7 kN. (2) m, m, °, kN/m³, , kPa, , and ; the experiment results of ultimate capacity are 400.5 kN and 411.3 kN. (3) m, m, °, kN/m³, , kPa, , and ; the experiment results of ultimate capacity are 194.6 kN and 188.2 kN.

It can be seen from Table 1 that the ultimate pullout capacity increases nonlinearly with parameter increasing. The surface shape cannot be determined because of disturbance when rock and soil mass is excavated. So, the parameter cannot be accurately determined and the values of ultimate uplift force are calculated with from 0 to 1. It is shown from Table 1 that the results of local test are all in the range of the results of the proposed method.

The comparison proves the theoretic reliability and validity in this work, so it can provide consultancy for shallow anchor design. The differences between the theoretical calculation and the local test data come from other factors such as the anchor length, the anchor diameter, and the strength of the soil around the anchor. The effects of these factors on the displacement and deformation of uplift piles demand more study.

6. Conclusions

(1)A new rapture surface shape is described in the present analysis. Based on the rapture surface equation and the limit equilibrium principle, rational calculation method for calculating the ultimate uplift capacity of the shallow anchor embedded in rock and soil mass is formulated.(2)The results of theoretical solutions and local tests show that the present method can provide a certain reasonable reference for designing of uplift capacity of shallow anchor.

Notations

:	Cohesion of rock and soil mass [FL⁻²]
:	The anchor diameter [L]
:	The lateral pressure coefficient of the soil mass [—]
:	The length of shallow anchor [L]
:	Material constant reflecting the influence of mean principal stress on strength [—]
:	The failure stress ratio under a given reference pressure [—]
:	Parameters of failure surface shape [—]
:	Internal pressure in the anchor hole [FL⁻²]
:	Ultimate pullout load [FL⁻²]
:	The uniformly distributed load on the infinitesimal element [FL⁻²]
:	Radius of shallow anchor [L]
:	The radius at the bottom of the infinitesimal element [L]
:	The vertical distance from the anchor plate to the infinitesimal section [L]
:	The tangential stress on the failure surface [FL⁻²]
:	Friction angle of rock and soil mass [—]
:	Soil unit weight [FM⁻¹]
:	The angle between the failure surface and horizon [—]
:	Normal stress on the failure surface [FL⁻²]
:	Three-dimensional extension strength [FL⁻²].

Competing Interests

The authors declare that they have no competing interests.

Acknowledgments

This work was supported by the National Basic Research Program of China (“973” Project) (Grant no. 2013CB036004) and the National Natural Science Foundation of China (Grant no. 51208523).

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Copyright

Copyright © 2016 Zou Jin-feng and Xia Ming-yao. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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