Empirical Method for Evaluating Resilient Modulus of Saturated Silty Clay under Cyclic Loading

Zhang, Zhen; Chen, Yong; Ye, Guanbao; Xiang, Peilin; Xiao, Yan; Wang, Qiong

doi:https://doi.org/10.1155/2020/8846895

Advances in Civil Engineering

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Abstract Introduction Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 8846895 | https://doi.org/10.1155/2020/8846895

Empirical Method for Evaluating Resilient Modulus of Saturated Silty Clay under Cyclic Loading

Zhen Zhang,¹Yong Chen,¹Guanbao Ye,¹Peilin Xiang,²Yan Xiao,¹and Qiong Wang¹

Academic Editor: Chunshun Zhang

Received11 May 2020

Revised05 Sept 2020

Accepted05 Oct 2020

Published21 Oct 2020

Abstract

Resilient modulus of soil is crucial for the design of a structure on a foundation subjected to a cyclic loading (e.g., traffic load or machine vibration load). This paper conducted a series of dynamic triaxial tests of saturated silty clay, considering the influence of the factors of cyclic stress ratio (CSR), static deviatoric stress ratio (SDR), and overconsolidation ratio (OCR) on the resilient modulus and dynamic damping ratio of the soil. A cyclic loading with a form of half sine wave was used to model the traffic loading. The results showed that the soil was prone to failure under a higher SDR, even though the applied CSR was less than the critical CSR. The saturated silty clay performed a strain softening behavior and its dynamic properties deteriorated significantly when higher CSR and SDR and lower OCR were involved. Based on the test results, an empirical method with a form of exponential function was proposed to evaluate the resilient modulus of the soil, considering the combined effects of CSR and SDR and OCR. The proposed method was verified through a comparison with the test results in this study and from literatures, and some recommendations for its application were offered.

1. Introduction

Subgrade consisting of saturated soft soil would be softened after it goes through million times of traffic loading in service [1, 2]. Such mechanical feature would result in an additional roadway settlement and shortening the road serviceability life [3–5]. For example, Saga airport road built on Ariake clay in Japan suffered an astonishing settlement after it went into operation [6].

Thus, properly evaluating the dynamic properties of soil as well as its deterioration characteristics is crucial for the design of a structure on a foundation subjected to a cyclic loading (e.g., traffic load or machine vibration load). Previous studies indicated that the dynamic behavior of soil is influenced by many factors, including the amplitude and form of cyclic loading, initial static deviator stress, and overconsolidation ratio [7–10]. Zhao et al. [11] indicated that increasing the cyclic stress level and the initial deviatoric stress would accelerate the attenuation of the resilient modulus of soft soil. Thian and Lee [12] performed a series of cyclic constant-volume direct simple shear loading tests on Malaysia offshore clay and found that the overconsolidated specimen reached the cyclic shear strain at failure faster than the normally consolidated specimen. In addition to the laboratory researches, some empirical methods for predicting the resilient modulus of soil have been established [13–16]. However, they are still rarely used in practice due to the complexity of the combined effects of a few influence factors. Therefore, it is necessary to develop a simple method to evaluate the dynamic properties of soil involving the influence factors for practice.

In this paper, a series of dynamic triaxial tests were conducted to investigate the dynamic behavior of saturated silty clay. The influences of the factors cyclic stress ratio (CSR), static deviatoric stress ratio (SDR), and overconsolidation ratio (OCR) on the resilient modulus and dynamic damping ratio were considered in the study. Finally, an empirical model was proposed to calculate the deterioration characteristics in resilient modulus, involving the influence factors of CSR, SDR, and OCR. The feasibility of the proposed model was verified through a comparison with some reported test result, and some recommendations for its application were offered.

2. Test Preparation and Scheme

The saturated silty clay sampled at a depth from 8 m to 12 m in an area of the high-tech district in Suzhou, China, was prepared for this study. A half sine wave function considering cyclic stress ratio (CSR) and static deviatoric stress ratio (SDR) was used to better model the traffic loading.

2.1. Soil Sample Preparation

The in situ soil samples were obtained by a thin-walled sampling tube with an internal diameter of 101.6 mm and height of 508 mm. In the dynamic triaxial test, the soil was remolded and prepared, referred to ASTM D4220/D4220M [17]. Table 1 shows the main properties of the remolded soil.

The natural soil was dried and grinded, and then the soil powder was obtained through 2 mm sieve. According to the dry density and the water content of the natural soil, the corresponding water was added and thoroughly mixed with the dry soil powder. The mixture was filled into a saturator layer by layer. The soil specimen was saturated in a vacuum chamber for 1 hr by pumping vacuum and then sealed for 12 hr after saturation. The dynamic triaxial tests were performed using the GDS dynamic triaxial testing system. The cylindrical soil specimen had a diameter of 39.1 mm and a height of 76 mm. The specimen was enclosed by a thin rubber membrane and placed between two rigid plates inside the pressure chamber. The saturation process was executed until Skempton’s B-value greater than 0.97 was achieved.

2.2. Test Schemes

Karlstrom and Bostrom [18] experimentally found that the traffic loading had features of low amplitude, low frequency, and long wavelength. As compared with sine wave model [19], Lu and Jeng [20] indicated that the dynamic stress transmitted to the subgrade was mainly a low-frequency one-way pulse wave rather than a two-way sine wave. Therefore, a half sine wave function was used to model the traffic loading in this study, which is characterized by three factors: loading frequency, cyclic stress ratio (CSR), and static deviatoric stress ratio (SDR). The applied cyclic loading is expressed in the following form: where is the effective confining stress after K₀ consolidation; t is the loading time; ω is the angular frequency; σ_s is the static deviatoric stress; and is the vertical dynamic stress. Tang et al. [21] and Yang et al. [22] indicated that the loading frequency in the subgrade was typically in a range of 0.5 to 3 Hz, and Lu et al. [23] found that the lower one (e.g., less than 1 Hz) played a dominant effect. Thus, 0.5 Hz was selected in this study. CSR was determined as 0.125, 0.15, 0.25, and 0.3, and SDR was adopted as 0, 0.15, 0.2, and 0.25.

Figure 1 shows the schematic of the loading process used in this study. The soil specimen was consolidated under K₀ condition (K₀ = 0.606) to restore the initial stress state of the specimen. The effective confining stress was determined as 80 kPa to simulate the actual confining pressure. A static deviatoric stress corresponding to the desired SDR was applied first under an undrained condition. Then a dynamic stress that corresponded to the desired CSR was applied until reaching the termination condition. The dynamic stress was not terminated until the soil specimen failed or the dynamic strain became stable. The failure state was defined as the specimen reaching a dynamic axial strain of 10% as the soil specimen had an appreciable lateral swelling deformation. Table 2 lists all the dynamic triaxial tests conducted in this study.

2.3. Determination of Dynamic Parameters

Regarded as a viscoelastic material, soil has two key parameters, resilient modulus () and dynamic damping ratio (D), which can be commonly determined based on the hysteresis curves from the dynamic triaxial test. Figure 2 shows the schematic for determining the two dynamic parameters of soil from the dynamic triaxial test. By drawing a line connecting the lowest point and the vertex of a hysteresis loop in the curve of vertical strain versus vertical dynamic stress, and D can be obtained by the following expressions:where and are the axial dynamic stresses at the vertex and low point of a hysteresis loop, respectively; and are the corresponding dynamic axial strains at and , respectively; is the area of hysteresis loop, which represents the loss of energy in a cycle; and is the area of triangle ABC, which represents the maximum elastic strain energy.

3. Test Results and Discussion

This section mainly introduces the soil behaviors of the soil under the modeled traffic cyclic loading, and the influences of CSR, SDR, and OCR on the dynamic parameters of the soil are discussed.

3.1. Effect of CSR

Figure 3 shows the results of the triaxial tests at different CSR. As expected, the dynamic axial strain of the soil specimen increased with an increase in CSR as shown in Figure 3(a). At CSR = 0.125, the dynamic axial strain reached a constant about 0.87%, which was far less than the termination standard of 10%, while at CSR = 0.3, the dynamic axial strain of the soil specimen abruptly increased and exceeded 10% within limited cycles.

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(b)

Figure 3(b) shows that the soil specimens had a maximum increment in excess pore pressure of 18.5 kPa at CSR = 0.125 and approximately 36 kPa at CSR = 0.25 and 0.30. The higher increment in excess pore water pressure led to a larger reduction in effective stress. Consequently, the soil specimen easily failed under a high CSR. Based on the test results, CSR = 0.25 was defined as the critical CSR of the tested saturated silty clay.

Figure 4 shows the relation between the dynamic parameters (i.e., and D) and the dynamic axial strain at different CSR. Similar to other studies [24, 25], and D were strongly dependent on CSR. and D were almost kept constant when the saturated silty clay was subjected to a small CSR (i.e., CSR = 0.125), as it basically behaved in an elastic state. At CSR = 0.25 and 0.30, decreased and D increased with the increase of the dynamic axial strain, and they gradually approached the constant values. With the increase of CSR, the softening of and the increase of D become significant. This phenomenon could be explained by the fact that the large dynamic stress caused the large accumulated dynamic axial strain of the soil specimen, leading to a significant energy consumption between soil skeletons. As a result, D increased gradually with the increase of CSR.

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(b)

3.2. Effect of SDR

Figure 5 shows the results of the triaxial tests at different SDR. SDR had a significant effect on the dynamic behavior of the saturated silty clay. The soil specimen failed at CSR = 0.15 and SDR = 0.25. Although the CSR of 0.15 was less than the critical CSR without considering SDR effect (i.e., 0.25), the increase in SDR accelerated the soil specimen failure. Figure 5(b) shows that the maximum increment in excess pore pressure increased with the increase of SDR and the soil specimen easily failed under a high CDR. As a result, the coupling effect on the soil dynamic behavior shall be considered to determine the critical CSR in design.

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(b)

Figure 6 shows the relation between the dynamic parameters (i.e., and D) and the dynamic axial strain at different SDR. increased and D decreased rapidly with a small increase in dynamic axial strain, followed by a gradually reduced rate. There is no question that and D were strongly dependent on SDR. reduced and D increased with the increase of SDR, while the effects became less significant after SDR was greater than 0.20. This phenomenon might be explained by a fact that the soil reached the critical limit state under a large SDR.

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(b)

3.3. Effect of OCR

Figure 7(a) shows the variation of the dynamic axial strain with cyclic numbers at different OCR. When the soil specimen changed from a normally consolidated soil to a slightly overconsolidated soil (OCR = 1.5), the dynamic axial strain had an obvious reduction but the reduction was not such appreciable when OCR increased from 1.5 to 2.0. Figure 7(b) shows a similar regulation that the maximum increment of excess pore water pressure was similar when OCR increased from 1.5 to 2.0. It is interesting to note that the excess pore water pressure in test C-9 (OCR = 1.5) fluctuated periodically, approximating 1000 cycles; however, the wave of the measured pore pressures was not observed in other tests. The wave of the measured pore pressures in test C-9 (OCR = 1.5) could be due to the fluctuation of the axial dynamic stress.

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(b)

Figure 8 shows the relation between the dynamic parameters (i.e., and D) and the dynamic axial strain at different OCR. The softening of and the increase of D became significant when OCR changed from 1.5 to 1.0. From a practical point of view, proper compaction of subgrade has significant benefit on improving the soil dynamic behavior.

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4. Empirical Method for Determining Resilient Modulus

The empirical models of damping ratio are usually a polynomial function depending on the ratio of resilient modulus at current strain to the initial dynamic elastic modulus [26–29]. A damping ratio model is not established in this study as it is difficult to accurately determine the initial dynamic elastic modulus in the dynamic triaxial test. Considering that resilient modulus as well as its deterioration is an important parameter for subgrade design, only an empirical method of resilient modulus model considering the influence factors of CSR, SDR, and OCR is established in this section.

4.1. Proposed Empirical Method

Based on the above analyses, the resilient modulus of the soil is dependent on CSR, SDR, and OCR. Hardin and Drnevich [29] proposed an empirical model to exhibit the nonlinear variation of with the increase of dynamic axial strain. However, in this model, the initial dynamic elastic modulus of the soil should be determined first. Generally, there are three methods to determine the initial dynamic elastic modulus: (a) in-door laboratory test, including resonant column test and dynamic triaxial test; (b) dynamic filed test, including shear wave velocity test; and (c) empirical equation, including the methods by Mojezi et al. [26] and Shan et al. [30]. The initial dynamic elastic modulus of soil is obtained under a small strain less than 10⁻⁴. The initial dynamic elastic modulus obtained by the resonant column test is more accurate than that by the dynamic triaxial test, as this dynamic test yields the shear strain level from 10⁻⁶ to 10⁻⁴. Taking this study for instance, the initial dynamic strain of the soil samples was in a range of 10⁻³ to 10⁻² from the dynamic triaxial test, which was larger than the strain range for the initial elastic dynamic modulus by one to two orders of magnitude. Despite the fact that the in-door laboratory test is far from the real condition in the field, it is still important because the test condition can be better controlled in the laboratory. The empirical equation can be used to estimate initial dynamic elastic modulus in primary design, as the soil behavior of the soils under dynamic conditions has strong relations with the characteristics of regional soils.

Zhou and Gong [31] indicated that attenuated exponentially with the dynamic axial strain based on the stress-controlled triaxial tests of Hangzhou normally consolidated clay with a form aswhere α and β are the undetermined coefficients, which could be influenced by soil properties and loading characteristics. However, it is still not clear how the soil properties and loading characteristics affect α and β. In this study, this exponential model was improved by separating the influences of CSR, SDR, and OCR from the coefficients of α and β and establishing the empirical functions of α and β related to CSR, SDR, and OCR based on the test results. Thus, the improved model is more applicable in practice than the model proposed by Zhou and Gong [31].

After taking logarithm on both sides, equation (3) turns to

Thus, it is revealed that the relation between and can be fitted by linear equation in a logarithmic coordinate system, and lgα and β are the intercept and the slope of the linear equation. According to equation (4), α and β can be back-calculated based on the triaxial test results. Furthermore, their relations with the influence factors, including CSR, SDR, and OCR, can be unveiled.

Figure 9 includes the obtained lg () with lg () from the tests under different CSR. As expected, the data points distributed almost linearly. Based on the best fitting lines for each test, the intercept and the slope (i.e., lgα and β) of each line can be determined. Figure 10 shows the back-calculated α and β varying with CSR. It can be seen that α and β vary almost linearly with CSR. Based on the above analysis, the functions of α and β dependent on CSR can be established. Similarly, the functions of the parameters α and β dependent on SDR and OCR can be established based on the test results, respectively. Figures 11 and 12 show the back-calculated α and β varying with SDR and OCR. The functions dependent on SDR were fitted by linear equation and quadratic equation, while those dependent on OCR were modeled by exponential equation.

The above analyses unveil the relations of α and β dependent on CSR, SDR, and OCR, respectively. α and β varied almost linearly with CSR. The functions of α and β dependent on SDR were best fitted by linear equation and quadratic equation, respectively, while the functions of α and β dependent on OCR were best fitted by an exponential equation. Accordingly, the functions of α and β considering the combined effects of CSR, SDR, and OCR can be assumed to have the following forms by adopting the method of separation of variables:in which, a_i, b_i, and k_i (i = 1, 2, 3, 4, 5) are the undetermined coefficients, which can be determined based on the triaxial test.

When performing a dynamic triaxial test, in the first step, a_i can be obtained by changing different CSR, while keeping SDR = 0. Then, b_i can be determined by changing different SDR, while keeping CSR constant. The third step is to obtain k_i (i = 2, 4) by changing different OCR, while keeping CSR and SDR constant. Finally, k_i (i = 1, 3) is used to balance equations (5a) and (5b).

Figure 13 shows a comparison of the calculated and measured values of α and ß. The maximum deviation between the predicted α and ß from equations 5a and 5b and between the back-calculated α and ß from the triaxial test results is less than 10%, indicating that the developed functions can be used to well represent the combined effect of CSR, SDR, and OCR on the parameters α and ß.

(a)

(b)

4.2. Verification

In this section, some test results from literatures were selected to further verify the proposed empirical method. Cai et al. [32] conducted a series of dynamic triaxial tests to study the influences of CSR and SDR on resilient modulus of the soft soil from Xiaoshan, China. Cyclic loading of sine wave with frequency of 1 Hz was applied to the soil samples. In the test, the CSR was selected as 0.583, 0.749, and 0.825, and the SDR was taken as 0, 0.1, and 0.2. The soil sample was prepared by the saturated remolded soft clay with liquid limit of 44.5% and plasticity index of 15.0. The soil sample was preconsolidated isotropically under a confining pressure of 100 kPa. Then, the required initial deviator stress was applied to the top of sample under undrained condition, followed by applying a vertical cyclic load. In the dynamic triaxial test conducted by Zhuang et al. [33], the cyclic loading was achieved with a sine wave. The SDR was taken as zero, the OCR of the soil sample was prepared to 1, 2, 3, and 4. The soil sample was prepared using saturated remolded soft clay from Nanjing, China, with liquid limit of 36.4% and plasticity index of 15.0. Xiong et al. [34] studied the dynamic characteristics of saturated soft silty clay from Ningbo, China. The cyclic loading with a sine wave type at a frequency of 1 Hz was applied. The soil sample was saturated remolded soft clay with liquid limit of 42% and plasticity index of 19.7. The soil sample was consolidated isotropically under confining pressure of 50 and 100 kPa, respectively. The applied vertical cyclic load was 10 kPa and 20 kPa, respectively.

In the test by Cai et al. [32], as OCR was equal to 1 and only CSR and SDR were considered, equations 5a and 5b can be simplified as

In the test by Zhuang et al. [33], only OCR was considered; thus, equations 5a and 5b can be simplified as

In the test by Xiong et al. [34], as only CSR was changed, equations 5a and 5b can be simplified as

Figure 14 shows the calculated by the proposed method versus the measured ones. The determined α and β from equations 6a–(8b) are also included. In general, the calculated by the proposed method agreed well with the measured from the test results. The mean biases in the three cases were in a range of 1.0 to 1.13 with an average of 1.08. Small deviations between the calculated and measured still exist. As shown in Figures 4(a), 6(a), and 8(a), the measured fluctuated above and below the best fitting lines due to the complexity of the problem itself and the uncertainty associated with soil properties. The normal distributions of the residuals were checked as shown in Figure 15. The residuals approximate a normal distribution with an average of 0, indicating that the proposed method yields good agreements with the reported measurements.

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(b)

(c)

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4.3. Comparison with Other Models

Hicks and Monismith [35] proposed an empirical model called K-θ model, which is one of the widely used models:where θ is bulk stress and K and n are the regression parameters. In this study, the confining pressure σ₃ was kept constant at 80 kPa. θ can be rearranged by

Guo et al. 2013 [36] refined the K-θ model, further considering the effect of CSR: where k₁ and k₂ are regression parameters. These two models can be used to predict the long-term resilient modulus, whereas the proposed model describes the softening of resilient modulus with dynamic strain. To make a comparison of the proposed model with these two models, the resilient modulus at a dynamic strain of 5% was calculated, as the test results showed that the resilient modulus nearly approached a constant value after that strain.

Figure 16(a) shows the comparison of the proposed model and the K-θ model. The K-θ model obtained reasonable agreements with some test cases. However, as the K-θ model does not consider the effect of OCR, large deviations were noted for the tests Nos. C-8 to C-10. Figure 16(b) shows the comparison between the model proposed by Guo et al. [36] and the proposed model. The model proposed by Guo et al. [36] can reasonably reflect the effect of CSR, but large deviations were noticed if OCR and SDR changed. The proposed model yielded reasonable agreements with the test results, indicating that the primary advantage of the proposed model is that it can reasonably consider the combined effects of the influence factors of SCR, SDR, and OCR.

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The analyses confirmed the applicability of the proposed model, but it should be realized that there are still some factors not considered in this method, for example, form of cyclic loading. The form of cyclic loading is dependent on some factors, including vehicle types and pavement types. It will be interesting if the proposed empirical method can be verified by the use of other cyclic forms in the future.

5. Conclusions

In this paper, a series of dynamic triaxial tests were conducted to investigate the dynamic behavior of the saturated silty clay under cyclic loading, and an empirical method was proposed to evaluate resilient modulus of the soil. Based on the test results and discussion, the following conclusions can be drawn: (1)Under the cyclic loading, the dynamic axial strain of the soil increased faster when higher CSR and SDR and lower OCR were involved. The soil was prone to failure under a higher SDR, even though the applied CSR was less than the critical CSR. Proper compaction of subgrade has significant benefit on improving the soil dynamic behavior.(2)The saturated silty clay performed a strain softening characteristic. The resilient modulus gradually reduced to a constant with the increase of cyclic numbers, and the dynamic damping ratio showed the opposite trend. The dynamic properties deteriorated significantly when higher CSR and SDR and lower OCR were involved.(3)An empirical method was proposed considering the combined effects of CSR and SDR and OCR and verified through a comparison with the test results in this study and from literatures.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

The authors appreciate the financial support provided by the National Natural Science Foundation of China (NSFC) (Grants nos. 41772281 and 41972272) for this research.

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Copyright © 2020 Zhen Zhang et al. 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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