Compaction Quality Inspection Method of Soil-Rock Filled Embankment Based on Continuous Compaction Control Technology

He, Zhuoling; Zhang, Junyun

doi:https://doi.org/10.1155/2021/8894042

Advances in Civil Engineering

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Abstract Introduction Materials and Methods Results and Discussion Conclusion Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 8894042 | https://doi.org/10.1155/2021/8894042

Compaction Quality Inspection Method of Soil-Rock Filled Embankment Based on Continuous Compaction Control Technology

Zhuoling He¹and Junyun Zhang¹

Academic Editor: Paolo Castaldo

Received30 May 2020

Revised14 Dec 2020

Accepted22 Dec 2020

Published09 Jan 2021

Abstract

Affected by the site construction conditions, the measurement passes of the Taihang Expressway K8 + 105 ∼ K8 + 341 (K8 worksite) in the Taihang Expressway did not meet the requirements of data analysis, and the quantity of the control points was insufficient so that the linear correlation between the dynamic deformation modulus () and the vibratory compaction value (VCV) was not strong. Therefore, the target value of VCV cannot be used to diagnose the compaction quality of soil-rock filler. This paper analyzes the roller measurement VCV value and in situ measurements value separately. Results reveal the difference between the VCV mean measured in the last two passes and the standard deviation of the measured VCV mean in the last pass are used as the main basis for the actual compaction quality. In addition, the mean in the last rolling can be used as an auxiliary judgment basis for the quality control of the compaction.

1. Introduction

Compaction quality is vital in water conservancy and hydroelectric power engineering and highway engineering. Whether it reaches the index is a vital factor to ensure compaction quality control. Based on the relationship between wave propagation and electrical resistivity characteristics of filler and compaction status, such as dry density, the water content, and electrical resistivity, the compaction quality can be analyzed by a wave seismic refraction survey [1, 2]. But these methods are not able to use for controlling the compaction quality quantitatively.

Many highway pavements deploy field inspectors to conduct in situ measurements of embankment properties, such as portable falling weight deflectometer (PFWD) and light weight deflectometer (LWD) [3–9]. The traditional quality inspection method relies primarily on testing randomly sampled spots in site, which may cause unreliable representation of the compaction quality of the entire work and lead to delays not only in performing construction work but also in identifying and rectifying quality issues [10]. Following several years of use of intelligent compaction (IC) technology in Europe [11, 12], the United States started using it in highway engineering. White et al. [13] credited the TH-64 construction project in Minnesota as the first earthwork project to require IC technology. More states in the US have been involved in researches exploring IC for compaction quality control [14–18]. Through the research of the relationship between sedimentation quantity and compaction quality, Mei et al. [19] settled the problems of construction technology and quality control of embankment. But the sedimentation difference method also has a shortage, and it does not directly demonstrate the technique index such as density and water content, only indirectly indicates the compaction quality of the compaction layer. In recent years, continuous compaction control technology has appeared in the compaction quality inspection of highway and railway subgrades in China. In well-graded coarse-grained soil or fine-grained soil near the optimal moisture content, there is a good linear correlation between roller measurement values and in situ measurements, and the compaction quality can be detected and controlled by target values, such as compaction meter value, compaction control value, machine drive power, acceleration amplitude, sound compaction value, and compaction value [20–26]. Therefore, IC can quickly monitor the compaction quality based on the measurements of the roller vibration in contact with the ground.

However, in fillers with large differences in the filler particle size, it is difficult to establish the linear correlation between roller measurement values and in situ measurements due to the large discreteness [27]. It is not convenient to diagnose the compaction quality by the target value. Based on the field compaction test at the Taihang K8 + 105 to K8 + 341 (K8 work point), an in site inspection evaluation method and evaluation standard for the compaction quality of soil-rock filled embankment are proposed based on continuous compaction control technology.

2. Materials and Methods

The source of the Taihang Expressway K8 + 105 to K8 + 341 (K8 work point) site filled material is the excavated soil-rock excavation of adjacent roads. There are mainly two types of fillers with different weathering degrees, the strongly weathered to fully weathered granite gneiss soil-rock mixed filler, type A filler, and the medium-weathered to strongly weathered granite gneiss soil-rock mixed filler, type B filler (Figure 1).

2.1. Test Bed Construction and Testing

The Liugong CLG6126 vibratory roller was used in the field test. The specific model data are shown in Table 1. To guarantee the compaction quality, each test strip was checked by the settlement difference method. Before the vibration rolling, the test strip was precompacted to obtain a flat surface. The length of the wheel track selected at the site was basically 20 m, and then, the PFWD test point was set at a spacing of 2 m or 3 m. The VCV test was carried out with the roller compaction first, and then, the PFWD test was carried.

2.2. In Situ Point Tests

Xu [24] described an index, vibratory compaction value (VCV), which is based on the embankment compaction status established by vertical vibration response signal of the vibration wheel in rolling. The VCV can reflect the change of the embankment resistance and the compaction status, and there is a good relation between embankment resistance and its incrementwhere represents function of vibration wheel acceleration, vibratory frequency, and the function needs monitoring data to define; is comprehensive correction function, and it is a dynamic quantity.

Using the PFWD for testing on the subgrade and the ground, the dynamic deformation modulus () can be acquired. The equipment has several advantages such as higher efficiency, less operators, nondestructive, and longer service life as well as the FWD, and it also has the advantages as follows: lightweight, objective tested data, high precision, easy operation, and less costing [28].

The loading equipment used a vibratory roller with a dead weight of not less than 16 t, and the fluctuation range of the vibration frequency did not exceed ±0.5 Hz of the specified value. Detection equipment was composed of vibration sensor, signal conditioning (amplification and filtering), data acquisition and analysis processing, data recording, display device, and system control software. The vibration sensor adopted an acceleration sensor, the sensitivity was not less than 10 mV/(m s⁻²), and the range was not less than 10 g, and it was installed vertically, as shown in Figure 2.

3. Results and Discussion

3.1. Data Processing

From the 16 sets of field test data, 8 comparatively complete and representative working conditions (WCs) were selected for analysis, as shown in Table 2. The quantity of the test passes for each group of the selected WCs was more than 3, and the number of points controlled by was more than 10. The selected data are shown in Figures 3 and 4.

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3.2. Correlations between Roller Measurement Values and Point Measurements

According to the in site test, the linear correlation analysis is performed on the data obtained in each working condition, and the linear correlation coefficient and regression equation corresponding to the VCV and the in each working condition are calculated. In this paper, when the linear correlation coefficient R > 0.7, it is considered that there is a strong linear correlation between the two indicators [10], and a linear regression equation is given. Otherwise, the linear correlation between the two indicators is considered weak, and no regression equation is given.

This paper considers the linear correlation between the and the VCV among all the measurement points, the different compaction degrees, and their mean.

Figure 5 illustrates the linear correlation coefficient between the value and the VCV value in all working conditions. During the rolling process, the change trend of the value and the VCV value is not completely consistent, and the value has a large dispersion, and the correlation is poor.

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Three compaction conditions, mild, moderate, and severe, are considered in this paper, and selection of data is shown in Table 3. Figure 6 shows the linear correlation results of the value and the VCV value. The correlation considering different compaction degrees in the K8 work point is poor, unless the WC 7.

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Using the mean and the VCV mean for analysis, the relationship between the VCV mean and the mean measured during a certain rolling can be partly reflected to avoid large errors caused by the large dispersion of values. As shown in Figure 7 and Table 4, the result reveals that the linear correlation between the mean and the VCV mean is poor, when the lift thickness is 70 cm, but the linear correlation coefficient between the mean and the VCV mean is strong when the lift thickness is 60 cm.

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3.3. Compaction Quality Inspection Method of Soil-Rock Filled Embankment

Due to various factors such as filler properties, rolling machinery, and technology, the linear correlation between the VCV and the for soil-rock mixed fillers is not generally strong. However, the measured data are insufficient, and its reliability needs further verification. Therefore, the method of using the VCV target value has limitations for the compaction quality detection of the soil-rock filled embankment.

According to the analysis of the continuous compaction test results of the field compaction test, it is found that, overall, the VCV value increases with the increase of the vibration time and finally stabilizes. Therefore, this paper considers the difference between the mean value of VCV from the last two times of rolling and the standard deviation of the VCV value of each measurement point from the last time of rolling to determine whether the compaction quality of the soil-rock filled embankment meets the requirements.

It is shown in Table 5 that the difference between the VCV mean values obtained from the last two roller passes under each working condition does not exceed 5 kN/m; in other words, the relative difference between the VCV mean values obtained from the last two roller passes is less than 1%. And the maximum of the VCV standard deviation from the last rolling is 3.59 kN/m, which does not exceed 1% of the average VCV, indicating that the rolling uniformity is also good. Therefore, this method can be used to quickly determine whether the compaction quality meets the requirements for the soil-rock mixed filler at the K8 working point.

Since the VCV value measured by continuous compaction does not correlate with the in situ measurement used in the test of the compaction quality of the subgrade, the above-mentioned determination method merely reflects the compaction degree of the subgrade indirectly. From the perspective of ensuring that the detection method is more reliable, the test results of can be considered to further judge the embankment compaction quality. The test results of each working condition at the K8 station are analyzed. The analysis results are shown in Table 6.

Generally, in the soil-rock mixed filler, when the number of rolling passes is enough, the hard rock block content is higher, the lift thickness is thinner, and the value is higher. The maximum standard deviation of the value of each measurement point after the last rolling is 2.44 MPa, which also indicates that the value is relatively discrete. Most are larger than 20 MPa except WC 8, and the range is 20.70 to 27 MPa, which indicates that whether mean of the last rolling is more than 20 MPa can be the auxiliary evaluation standard.

4. Conclusion

When it is difficult to establish a linear correlation between roller measurement values and in situ measurements due to discrete data, roller measurement values, and in situ measurements can be separately analyzed to detect the compaction quality of soil-rock filled embankment. Based on the field compaction test and test of Taihang Expressway K8, this paper proposes a rapid diagnostic method for compaction quality of soil-rock filled embankment based on continuous compaction control technology as follows:(1)The difference between the average value of VCV measured during the last two passes (ΔVCV ≤ 5kN/m) and the standard deviation of the value of VCV measured during the last two passes (σVCV ≤ 5kN/m) are used as the main basis of soil-rock filled embankment compaction quality(2)Whether the average of the last rolling is greater than or equal to 20 MPa is used as the auxiliary evaluation standard for the quality control of the embankment compaction in this site

Data Availability

The test data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

This research was supported by the Science and Technology Department of Sichuan Province (Grant no. 2018JY0076 and Grant no. 21ZDYF2108). The work was also carried out under the subgrade filled Engineering Research and Development Project of the Chengdu East Road Technology Co., Ltd.

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Copyright © 2021 Zhuoling He and Junyun Zhang. 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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