Your search keyword '"Degou Cai"' showing total 43 results

1. Nonlinear regression modeling of swelling characteristics in cracked expansive soil: integrating crack, moisture, density, and load effect

Author

Junkai Yao, Degou Cai, Ke Su, and Hongye Yan

Subjects

expansive soil, crack, nonlinear regression, model, swelling, prediction, Technology

Abstract

Expansive soils, known for their significant volume change with variations in moisture content, are widely distributed around the globe. Due to their swelling properties, expansive soils pose significant engineering challenges, especially in rapidly developing countries like China. This study aims to investigate the swelling mechanisms of expansive soils, focusing on the influence of crack characteristics on swelling behavior. The research methodology includes field investigations, laboratory experiments, and theoretical modeling. By comprehensively considering crack rate, dry density, initial moisture content, and overburden load, a nonlinear regression swelling model is proposed in this research. The degree of crack development in expansive soils is quantitatively characterized by the content of filling materials, leading to the establishment of a crack rate model for expansive soils. Swelling tests on expansive soils with different crack contents were conducted. The results show that the swelling rate is negatively correlated with the initial moisture content and positively correlated with dry density and crack rate. Additionally, the larger the crack rate, the more significant the change in the swelling rate. Furthermore, model validation confirms that this nonlinear regression model accurately describes the relationship between swelling rate and influencing factors. It offers a more precise prediction tool for infrastructure design and maintenance in expansive soil areas, advancing geotechnical engineering practices.

Published

2024

2. Current situation and development trend of design methods for subgrade structure of high speed railways

Author

Yangsheng Ye, Degou Cai, Qianli Zhang, Shaowei Wei, Hongye Yan, and Lin Geng

Subjects

High speed railway, Subgrade engineering, Subgrade bed structure, Design method, Existing research, Development trend, Transportation engineering, TA1001-1280, Railroad engineering and operation, TF1-1620

Abstract

Purpose – This method will become a new development trend in subgrade structure design for high speed railways. Design/methodology/approach – This paper summarizes the structural types and design methods of subgrade bed for high speed railways in China, Japan, France, Germany, the United States and other countries based on the study and analysis of existing literature and combined with the research results and practices of high speed railway subgrade engineering at home and abroad. Findings – It is found that in foreign countries, the layered reinforced structure is generally adopted for the subgrade bed of high speed railways, and the unified double-layer or multi-layer structure is adopted for the surface layer of subgrade bed, while the simple structure is adopted in China; in foreign countries, different inspection parameters are adopted to evaluate the compaction state of fillers according to their respective understanding and practice, while in China, compaction coefficient, subsoil coefficient and dynamic deformation modulus are adopted for such evaluation; in foreign countries, the subgrade top deformation control method, the subgrade bottom deformation control method, the subsurface fill strength control method are mainly adopted in subgrade bed structure design of high speed railways, while in China, dynamic deformation control of subgrade surface and dynamic strain control of subgrade bed bottom layer is adopted in the design. However, the cumulative deformation of subgrade caused by train cyclic vibration load is not considered in the existing design methods. Originality/value – This paper introduces a new subgrade structure design method based on whole-process dynamics analysis that meets subgrade functional requirements and is established on the basis of the existing research at home and abroad on prediction methods for cumulative deformation of subgrade soil.

Published

2023

3. Research on the Deformation Mechanism of Railway Subgrade under Buried Strike–Slip Fault Dislocation

Author

Jingwei Liang, Yangsheng Ye, Degou Cai, Hongye Yan, and Junkai Yao

Subjects

strike–slip fault, railway subgrade, deformation mechanism, S–shaped displacement, settlement, tension–shear crack, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

With the gradual densification of China’s railway network, more and more railways are inevitably crossing active fault zones. Creep dislocation and stick–slip dislocation of the fault zones can lead to uneven deformation and cracks in the railway subgrade, threatening the sustainability of the railway. Therefore, a model test and numerical simulation were used to analyze the deformation mechanism and sustainability of the subgrade and foundation induced by a strike–slip fault dislocation in a flat site under different angles between the subgrade and fault strikes. The test and simulation results show that (1) under the influence of strike–slip fault dislocation, the horizontal direction of the subgrade appeared to have an S–shaped displacement. The top surface of the subgrade appeared to have a vertical settlement. Further, tension–shear cracks and compression crush zones appeared on the subgrade’s surface. (2) When the angle between the fault and subgrade strikes increased, the subgrade’s uneven deformations induced by fault dislocation first decreased and then increased. The angle between the main tension–shear crack on the top surface of the subgrade and the fault strike showed a trend of increasing and then decreasing. In addition, the compressive stress along the subgrade strike decreased, while the tensile stress along the subgrade strike gradually increased. (3) The tension–shear cracks in the subgrade and foundation were spiral and converged to the basement strike–slip fault along the depth direction. This study provides a reference for the safe operation and sustainability of railways near faults.

Published

2024

4. A long term resilient modulus rate dependent model for coarse fine mixtures geomaterials under freezing and thawing cyclic

Author

Ke Wang, Liang Tang, Shuang Tian, XianZhang Ling, Yangsheng Ye, Degou Cai, and Min Liu

Subjects

Medicine, Science

Abstract

Abstract The cyclic loading frequency (f cyc) effects on the resilient modulus (M r) of freezing–thawing coarse–fine mixtures geomaterials (FTCFG) have always been a research hotspot. A series of long-term cyclic triaxial tests were conducted on FTCFG having different fines content (FC) under different number of freeze–thaw cycles (N FT) to investigate the effect of f cyc and deviator stress amplitude (q cyc) on the M r of FTCFG. The freezing–thawing cyclic was found to improve the M r of FTCFG. Additionally, M r of FTCFG shown an obviously rate-dependent characteristics. Then three kinetic effects (rate effect, piston effect, and fatigue effect) are discussed in systemically which are related to q cyc, f cyc and moisture holding capacity (w h). Finally, a rate dependent model of long-term resilient modulus was developed to predict FTCFG materials’ resilient moduli as a function of q cyc, f cyc and w h. The comparisons between the calculation and experimental results reveal that the present model describes the M r of FTCFG well.

Published

2022

5. A constitutive model for cyclic densification of coarse-grained soil filler for the high-speed railway subgrade considering particle breakage

Author

Yangsheng Ye, Degou Cai, Lin Geng, Hongye Yan, Junkai Yao, and Feng Chen

Subjects

High-speed railway, Subgrade, Coarse-grained soil filler, Particle breakage, Cumulative deformation, Stress ratio, Transportation engineering, TA1001-1280, Railroad engineering and operation, TF1-1620

Abstract

Purpose – This study aims to propose a semiempirical and semitheoretical cyclic compaction constitutive model of coarse-grained soil filler for the high-speed railway (HSR) subgrade under cyclic load. Design/methodology/approach – According to the basic framework of critical state soil mechanics and in view of the characteristics of the coarse-grained soil filler for the HSR subgrade to bear the train vibration load repeatedly for a long time, the hyperbolic empirical relationship between particle breakage and plastic work was derived. Considering the influence of cyclic vibration time and stress ratio, the particle breakage correction function of coarse-grained soil filler for the HSR subgrade under cyclic load was proposed. According to the classical theory of plastic mechanics, the shearing dilatation equation of the coarse-grained soil filler for the HSR subgrade considering particle breakage was modified and obtained. A semiempirical and semitheoretical cyclic compaction constitutive model of coarse-grained soil filler for the HSR subgrade under cyclic load was further established. The backward Euler method was used to discretize the constitutive equation, build a numerical algorithm of “elastic prediction and plastic modification” and make a secondary development of the program to solve the cyclic compaction model. Findings – Through the comparison with the result of laboratory triaxial test under the cyclic loading of coarse-grained soil filler for the HSR subgrade, the accuracy and applicability of the cyclic compaction model were verified. Results show that the model can accurately predict the cumulative deformation characteristics of coarse-grained soil filler for the HSR subgrade under the train vibration loading repeatedly for a long time. It considers the effects of particle breakage and stress ratio, which can be used to calculate and analyze the stress and deformation evolution law of the subgrade structure for HSR. Originality/value – The research can provide a simple and practical method for calculating deformation of railway under cyclic loading.

Published

2022

6. Calculation method for internal force and deformation of the prestressed I-beam on the elastic foundation

Author

Yangsheng Ye, Shaowei Wei, Degou Cai, Jianmin Yang, Peiyong Wei, Cuihong Yue, and Shangrui Wu

Subjects

internal force and deformation, prestressed I-beam, elastic foundation, calculation method, Winkler foundation, Pasternak foundation, Science

Abstract

The elastic foundation beam theory has been widely used in civil engineering, including railway, tunnel, and building foundations. With the development of fabricated structures, more elastic foundation beams need to be prestressed. In order to explore the frame foundation beam with the fabricated anchor-cable in the slope reinforcement project, in this article, prestress is applied to both ends of the beam. Then, according to the calculation method of internal force and deformation of the beam under concentrated force and the equivalent load theory of the prestressed structure, three new methods: the finite difference method (FDM) of the Euler–Bernoulli beam on the Winkler foundation, FDM of the Euler–Bernoulli beam on the Pasternak foundation, and theoretical analytical solution of the Timoshenko beam on the Winkler foundation, are deduced to calculate internal force and deformation under prestress force and concentrated force, respectively. Typical calculation parameters are selected for design and verification via the three new methods and GEO5, respectively. The results show that the calculated values of the three new methods are basically consistent with those calculated using GEO5 software, which verifies the feasibility of the three new methods.

Published

2023

7. Research on Cumulative Deformation Characteristics of Subgrade Filling under Cyclic Train Loading

Author

Junkai Yao, Yangsheng Ye, Degou Cai, Zongqi Bi, and Hongye Yan

Subjects

Physics, QC1-999

Abstract

The smoothness of high-speed railway is extremely strict. As an important part of the high-speed railway foundation, the subgrade structure has strict deformation requirements. It is necessary to ensure that the subgrade structure does not have plastic cumulative deformation under the long-term cyclic load of the train, which is the most critical geodynamic problem in high-speed railway subgrade. This paper studied the cumulative deformation characteristics of subgrade filling under cyclic train loading through the cyclic triaxial test, three types of accumulative plastic deformation trends, and the value of critical volume shear strain was discussed, which would provide the theoretical support for the dynamic design of high-speed railway.

Published

2022

8. Investigating Morphology and Breakage Evolution Characteristics of Railroad Ballasts over Distinct Supports Subjected to Impact Loading

Author

Yuanjie Xiao, Yu Jiang, Pan Tan, Kunfeng Kong, Joseph Ali, Ralina Mustafina, Hongwei Zhu, and Degou Cai

Subjects

railway ballast, ballast degradation, impact load, particle breakage, morphology, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The ballast bed constantly degrades under the repeated applications of impact loading exerted by passing trains in terms of the particle size, shape, breakage, fouling, etc., thus significantly jeopardizing the in-service performance and operational safety of ballasted tracks. In this study, the morphology and breakage evolution characteristics of railroad ballasts of single- and multiple-size ranges were investigated from laboratory impact-load tests. Both a concrete block and sand layer were placed to mimic the distinct under-ballast supports. The degradation trends of the typical shape and breakage indices were comparatively quantified for different combinations of ballast particle sizes and shapes, under-ballast supports, impact energies, and number of impact-load applications (N). The results show that both shape and size affect ballast particle breakage, with shape being more influential. The breakage severity of flake-like particles is about 1.5–1.66 times and 1.25–1.5 times higher than those of regular and needle-like particles, respectively. Under impact loading, large and small single-size ballasts degrade mainly by breakage and abrasion, respectively. The modified fouling index (FI) of flake-like particles within 31.5–40 mm is about 3.6 times that of regular particles within 50–63 mm. The shape indices of the ballast particles within 31.5–40 mm exhibit the most profound changes. The severities of the ballast breakage and fines generation (or modified FI) increased by 50% and 74%, respectively, due to the increase in the under-ballast support stiffness by 100 times and the drop height of 80 cm, respectively. The convexity and ballast breakage index (BBI) are promising for quantifying particle-degradation trends, and their statistical correlation found herein is potentially useful for the transition of ballast-bed-maintenance management from the current plan-based scheduling to condition-based upgrading.

Published

2022

9. Research on In Situ Stress Distribution of the Railway Tunnels in Southwest China Based on the Complete Temperature Compensation Technology

Author

Weibin Ma, Jinfei Chai, Degou Cai, Xiaoyan Du, Jie Dong, Siming Tian, Peng Zhao, Ziyuan Liu, and Wei Cui

Subjects

Physics, QC1-999

Abstract

In situ stress is the natural stress existing in the stratum without engineering disturbance, also known as initial stress, absolute stress, or original rock stress. In order to master the in situ stress of the Manmushu Tunnel and Mamo Tunnel in Southwest China, the casing stress solution method is adopted in this paper. Through the combination of field measurement and laboratory test, the basic data such as initial strain during stress relief are collected, and the in situ stress values are analyzed in combination with indoor temperature compensation test, confining pressure calibration, and relevant rock mechanics tests. The measured results show the following: (1) the maximum horizontal principal stress σh.max ranges from 6.44 MPa to 19.74 MPa; the vertical principal stress σv ranges from 4.11 MPa to 13.48 MPa; and the minimum horizontal principal stress ranges from 4.32 MPa to 11.22 MPa. (2) The maximum horizontal principal stress directions of the five measuring points are all located in the NW direction, which is basically consistent with the maximum principal stress direction of the regional tectonic stress field. The maximum horizontal principal stress (σh.max), the minimum horizontal principal stress (σh.min), and the vertical principal stress (σv) all increase with the increase of buried depth, and the relationship is approximately linear. It is suggested that, in the actual construction process, the construction method and construction parameters should be optimized scientifically and reasonably to reduce the disturbance of blasting on the tunnel surrounding rock. After tunnel excavation, support measures should be taken quickly, timely, and scientifically to reduce and control the deformation of the surrounding rock.

Published

2021

10. An Empirical Dilatancy Model for Coarse-Grained Soil under the Influence of Freeze–Thaw Cycles

Author

Yangsheng Ye, Degou Cai, Shuang Tian, Hongye Yan, Xianzhang Ling, Liang Tang, and Yike Wu

Subjects

freeze–thaw cycles, coarse-grained soil, dilatancy, empirical equations, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

In the era of high-speed trains, it is very important to ensure the safety and stability of rail tracks under adverse conditions including seasonal freezing and thawing. Freeze–thaw cycles (FTCs) affecting the engineering performance of coarse-grained soil (CGS) is one of the major reasons for track deterioration. The reported results of a number of static freeze–thaw triaxial tests on the shear behaviour of CGS are analysed herein. It was observed that confining pressure (σ3) and FTCs have a significant influence on the shear behaviour of CGS. In this paper, an empirical mathematical model has been proposed to capture the dilatancy of CGS subjected to FTCs during shearing. The empirical constants a, b, and c proposed in the model are a function of σ3 and FTCs. The results of the model have been compared with the laboratory experiments and are found to be in good agreement.

Published

2022

11. Characterizing and Predicting the Resilient Modulus of Recycled Aggregates from Building Demolition Waste with Breakage-Induced Gradation Variation

Author

Yuanjie Xiao, Kunfeng Kong, Umar Faruk Aminu, Zhiyong Li, Qiang Li, Hongwei Zhu, and Degou Cai

Subjects

building demolition waste, unbound granular materials, shear strength, resilient modulus, gradation, prediction model, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Building demolition waste (BDW) has been massively stockpiled due to increasingly rapid urbanization and modernization. The use of recycled BDW as unbound granular base/subbase materials is among the sustainable, cost-effective, and environmentally friendly pavement construction alternatives. The resilient modulus is an important mechanical property of BDW-derived aggregates and mechanistic design input of pavements incorporating BDW. This paper presents the results of a comprehensive laboratory study on the shear strength and resilient modulus characteristics of BDW-derived aggregate materials. A series of monotonic triaxial compression tests and repeated-load triaxial (RLT) tests were conducted with five different gradations representing particle breakage and different stress paths. The apparent cohesion and internal friction angle of recycled BDW aggregates under consolidated drained conditions ranged from 35.3 to 57.5 kPa and from 30.2° to 54.3°, respectively. The apparent cohesion and internal friction angle also increased and decreased non-linearly with the increasing relative content of fine particles, respectively. The resilient modulus of recycled BDW aggregates gradually decreased with increasing relative content of fine particles at the same stress level. Both the deviator stress and confining pressure exhibited significant influences on the resilient modulus, while the effect of confining pressure was more profound. Based on laboratory testing data, a mechanistic-empirical model was developed to predict the resilient modulus of recycled BDW aggregates from gradation and stress-state variables. The findings could be useful for extended engineering applications of BDW in unbound granular pavement base/subbase construction.

Published

2022

12. Evaluating the Effect of Rail Fastener Failure on Dynamic Responses of Train-Ballasted Track-Subgrade Coupling System for Smart Track Condition Assessment

Author

Yuanjie Xiao, Zhenxing Chang, Jianfeng Mao, Sijia Zhou, Xiaoming Wang, Weidong Wang, Degou Cai, Hongwei Zhu, and Yao Long

Subjects

high-speed railway, rail fastener failure, train-ballasted track-subgrade coupling system, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Rail fasteners are among the key components of ballasted track of high-speed railway due to their functionality of fixing rails to sleepers. The failure of rail fastening system hinders the transmission of train loads to underlying track substructure and therefore endangers the operation safety and longevity of ballasted track. This paper first established a three-dimensional (3D) numerical model of the train-ballasted track-subgrade coupling system by integrating multibody dynamics (MBD) and finite element method (FEM). Numerical simulations were then performed to investigate the effects of different patterns of rail fastener failure (i.e., consecutive single-side, alternate single-side, and consecutive double-side) on critical dynamic responses of track structures, train running stability, and operation safety. The results show that the resulting influences of different patterns of rail fastener failure descend in the order of consecutive double-side failure, consecutive single-side failure, and alternate single-side failure. As the number of failed fasteners increases, the range where dynamic responses of track structures are influenced extends, and the failure of two consecutive single-side fasteners exerts a similar influence as that of four alternate single-side fasteners. The failure of single-side fasteners affects dynamic responses of the intact side of track structures relatively insignificantly. The influence of rail fastener failure on track structures exhibits hysteresis, thus indicating that special attention needs to be paid to locations behind failed fasteners during track inspection and maintenance. The occurrence of the failure of two or more consecutive fasteners demands timely maintenance work in order to prevent aggravated deterioration of track structures. The findings of this study could provide useful reference and guidance to smart track condition assessment and condition-based track maintenance.

Published

2022

13. Study on Intelligent Compaction-Equipment Logistics Scheduling and Propagation Characteristics of Vibration Wave in Nonlinear Systems with Multistability Based on Field Test

Author

Yixuan Han, Changwei Yang, Degou Cai, Hongye Yan, and Hailing Zeng

Subjects

Electronic computers. Computer science, QA75.5-76.95

Abstract

The equipment scheduling and propagation characteristics of vibration wave from vibratory roller ⟶ filling material nonlinear systems with multistability are the core problems of subgrade intelligent construction technology, and the logistics scheduling of the equipment is directly related to the construction efficiency. Aiming at the shortages, one typical subgrade located at the Gu’an station of Beijing-Xiong’an city railway is selected to research and finish the field tests; some findings are shown as follows: first, some valuable suggestions about the logistics scheduling of intelligent equipment are proposed, which can break the barriers between the organizations and improve construction efficiency; second, when the vibration wave propagates from the vibratory roller ⟶ surface of filling material ⟶ different buried depths of filling material, the peak acceleration of vibration wave gradually decreases and is hyperbolic distribution approximately. At the same time, the sensitive of attenuation is shown as follows: Z0.9), and the concrete functional relationship among different amplitudes of harmonics can be summarized as y = Ae−BX; fourth, the vibration energy is mainly concentrated near 10–30 Hz in the vibratory roller, but when the vibration wave propagates from vibratory roller⟶filling material, the vibration energy gradually decreases with the increase in depth, and the marginal spectrum gradually changes from one peak to two peaks, that is, 30–50 Hz and 50–100 Hz; fifth, the vibration energy in the vibrational wheel is distributed averagely in the compaction process, and the effective compaction time is two seconds, which will be helpful for revealing the propagation characteristics of vibration wave, optimizing the compaction quality control models and providing some support for the development of intelligent compaction theory of railway subgrade.

Published

2020

14. Experimental Study on the Compaction Characteristics and Evaluation Method of Coarse-Grained Materials for Subgrade

Author

Shanzhen Li, Yangsheng Ye, Liang Tang, Degou Cai, Shuang Tian, and Xianzhang Ling

Subjects

coarse-grained materials, compaction characteristic, subgrade, CMV, quality evaluation, geostatistical analysis, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Coarse-grained materials are widely used in high-speed railway construction, and it is of great significance to research its compaction characteristics due to the high quality control requirements. In this regard, a field compaction experiment was conducted at a subgrade near Bazhou Station of Beijing-Xiong’an Intercity Railway. The test results of the compaction effect were presented in this study at first. The roller-integrated compaction measurements (i.e., compaction meter value, CMV) were compared with several traditional in-situ tests (i.e., plate load test, light falling weight deflectometer test, and shear wave velocity test). Then the stability of CMV was evaluated by the proposed δ criterion. The spatial uniformity of compaction was further investigated. Based on the analysis, the target value of CMV was preliminarily determined. It showed that Evd was more variable than CMV. The results convincingly indicated that the compaction parameters increased with the increasing number of roller passes at first. A further increase in compaction effort could result in the decompaction of material when the compaction number up to a certain value. The stability analysis method proposed in this study showed its potency of quantifying the percentage of areas with acceptable compaction. The geostatistical analysis could reflect the spatial uniformity of compaction. Overall, the conducted study could provide a useful reference for geo-material compaction control in the transportation engineering.

Published

2021

15. Performance Test and Stability Analysis of Jute Ecological Bag on Subgrade Slope

Author

Shaowei Wei, Degou Cai, Song Lv, and Jianping Yao

Subjects

Environmental sciences, GE1-350

Abstract

Ecological bags have been gradually adopted for ecological protection on the subgrade slope because of their good soil fixation effect, strong water retention performance, fast construction and other advantages. Ecological bags made of natural jute have obvious attributes in environmental protection and economic efficiency. In this study, the tensile and the tearing strength of the common-used jute cloth have been tested. The result shows that the strength meet the requirements of the standards. Compared with current frequently-used ecological bag made of non-woven cloth, the jute ecological bag has large apertures, which is suitable for the growth of dicotyledon plants. Moreover, its high friction coefficient with the soil is beneficial to the structure stability on the slope. On the other hand, a stability evaluation method has been established for the jute ecological bags on the subgrade slope under natural and heavy rainfall conditions. Then the steel wire mesh fixed by the anchor rods is used to enhance the stability of the jute ecological bags, which constitute the ecological protection system for the subgrade slope. Also, the stability of the protection system is analyzed and calculated.

Published

2021

16. Mechanical Characteristics and Failure Mode of Asphalt Concrete for Ballastless Track Substructure Based on In Situ Tests

Author

Qinghong Fu, Xianhua Chen, Degou Cai, and Liangwei Lou

Subjects

asphalt concrete, ballastless track substructure, cyclic train load, ambient temperature, in situ test, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Asphalt concrete paved on the surface of a roadbed as a ballastless track substructure has an excellent waterproofing and vibration attenuation performance. However, the mechanical characteristics and the failure mode of this structure under the actions of a cyclic train load and ambient air temperature changes are still unclear. Therefore, a test section of an asphalt concrete substructure was constructed based on a high-speed railway ballastless track project in north China. In situ forced vibration tests and temperature-induced deformation monitoring tests were performed to investigate the mechanical responses of the asphalt concrete, respectively. Test results show that the bottom of the asphalt concrete layer is in the tensile state under the action of the cyclic train load. The surface of the asphalt concrete in contact with the base plate is subjected to tensile stress near the expansion joint under the action of the negative temperature gradient. Changes in the ambient temperature lead to more significant mechanical responses of the asphalt concrete substructure than the cyclic train load, especially near the expansion joint of the base plate. Therefore, the passive tensile failure mode may occur near the expansion joint of the base plate. However, it has also proved that setting isolation layers under the base plate near the expansion joint is an effective method to significantly reduce responses near the expansion joint in this research.

Published

2020

17. Investigation on Interface Damage between Cement Concrete Base Plate and Asphalt Concrete Waterproofing Layer under Temperature Load in Ballastless Track

Author

Xianhua Chen, Yu Zhu, Degou Cai, Gang Xu, and Tao Dong

Subjects

ballastless track, asphalt concrete waterproofing layer, interface damage, CZM, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The interfacial bond between cement concrete base plate (CCBP) and asphalt concrete waterproofing layer (ACWL) is a weak portion in the newly developed Chinese high-speed railway ballastless track. The interface damage caused due to fluctuating temperature load and dynamic train load is one of the most critical problems in Northern China. This paper aims to investigate the interface damage evolution process under temperature load via experimental and simulation analysis. Full-scale transverse shear tests were performed to explore the interface bond-slip mode of the adjacent ACWL and CCBP. Then, a finite element model of a ballastless track structure was built and a cohesive zone model (CZM) was utilized to model the interface damage initiation, crack propagation, and delamination process under uniform/gradient temperature load. Furthermore, the dynamic response of the ballastless track where CCBP and ACWL were partly/totally debonded was investigated and compared with the perfectly bonded structure. The results demonstrate that bilinear CZM is capable of revealing the interface damage initiation, crack propagation, and delamination process under temperature load. The interface state between the adjacent CCBP and ACWL was greatly affected by temperature changes and the interface bonding state had a great impact on the dynamic response of ballastless track.

Published

2020

18. Study on the Transmission and Evolution Characteristics of Vibration Wave from Vibratory Roller to Filling Materials Based on the Field Test

Author

Changwei Yang, Liang Zhang, Yixuan Han, Degou Cai, and Shaowei Wei

Subjects

high-speed railway, subgrade compaction, field test, nonlinear transmission mechanism, time–frequency characteristics, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Compaction quality of railroad subgrade relates directly to the stability and safety of train operation, and the core problem of the Intelligent Compaction of railroads is the transmission and evolution characteristics of vibration wave. Aiming at the shortages in exploring the transmission and evolution characteristics of the vibration signal, the typical subgrade compaction project of Jingxiong Intercity Railway Gu’an Station was selected to carry out the field prototypes tests, and the dynamic response from the vibratory roller to filling materials was monitored in the whole compaction process, and some efficient field tests data will be obtained. Based on this, the transmission and evolution characteristics of the vibration wave from the vibratory roller to filling materials in the compaction process are studied from the time domain, frequency domain, jointed time−frequency domain and energy domain by using one new signal analysis technology—Hilbert−Huang Transform. Some conclusions are shown as follows: first, the vibration acceleration peak gradually decreases with the increase of buried depth, and when the buried depth reaches 1.8 m, the vibration acceleration peak is closed to zero. At the same time, when the vibration wave propagates from the wheel to the surface of filling, the attenuation rate of acceleration gradually increases with the increase of rolling compaction times, while the attenuation rate of other layers in different buried depths gradually decreases. Second, the vibration wave contains fundamental wave and multiple harmonics, and the dominant frequency of the fundamental wave is nearly 21 Hz. With the increase of buried depth, the amplitude of fundamental, primary, secondary, until fifth harmonics decreases exponentially and the concrete functional relationship among different amplitudes of harmonics can be summarized as y = Ae−BX. Third, the vibration energy focuses on the fundamental wave and primary wave, which can increase with the increase of rolling compaction times, and when the rolling compaction time reaches five, their energy reaches maximum. However, when the filling reaches a dense situation, the energy of the primary wave gradually decreases. Therefore, the maximum rolling compaction time is five in the practical engineering applications, which will be helpful for optimizing the compaction quality control models and providing some support for the development of the Intelligent Compaction theory of railway subgrade.

Published

2020

19. Evolution of Rheological Behaviors of Styrene-Butadiene-Styrene/Crumb Rubber Composite Modified Bitumen after Different Long-Term Aging Processes

Author

Yangsheng Ye, Gang Xu, Liangwei Lou, Xianhua Chen, Degou Cai, and Yuefeng Shi

Subjects

high speed railway, SBS/CR modified asphalt, long-term aging, anti-aging, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

In this study, a new type of composite modified bitumen was developed by blending styrene-butadiene-styrene (SBS) and crumb rubber (CR) with a chemical method to satisfy the durability requirements of waterproofing material in the waterproofing layer of high-speed railway subgrade. A pressure-aging-vessel test for 20, 40 and 80 h were conducted to obtain bitumen samples in different long-term aging conditions. Multiple stress creep recovery (MSCR) tests, linear amplitude scanning tests and bending beam rheometer tests were conducted on three kinds of asphalt binders (SBS modified asphalt, CR modified asphalt and SBS/CR composite modified asphalt) after different long-term aging processes, including high temperature permanent deformation performance, resistance to low temperature thermal and fatigue crack. Meanwhile, aging sensitivities were compared by different rheological indices. Results showed that SBS/CR composite modified asphalt possessed the best properties before and after aging. The elastic property of CR in SBS/CR composite modified asphalt improved the ability to resist low temperature thermal and fatigue cracks at a range of low and middle temperatures. Simultaneously, the copolymer network of SBS and CR significantly improved the elastic response of the asphalt SBS/CR modified asphalt at a range of high temperatures. Furthermore, all test results indicated that the SBS/CR modified asphalt possesses the outstanding ability to anti-aging. SBS/CR is an ideal kind of asphalt to satisfy the demand of 60 years of service life in the subgrade of high speed railway.

Published

2019

20. Dynamic Responses of Asphalt Concrete Waterproofing Layer in Ballastless Track

Author

Jie Zhou, Xianhua Chen, Qinghong Fu, Gang Xu, and Degou Cai

Subjects

ballastless track, asphalt concrete, dynamic modulus, linear viscoelasticity, dynamic response, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The application of asphalt concrete waterproofing layer (ACWL) for the subgrade has been a trend in Chinese high-speed railway. The purpose of this research is to discuss the dynamic characteristics of full cross-section ACWL in the ballastless track structure under the train loads. The laboratory tests were conducted to evaluate the performance of the asphalt mixtures for the ACWL and a test section of ACWL was constructed on the high-speed railway in north China. The linear viscoelastic behavior of the asphalt concrete obtained from the test section was characterized by the generalized Maxwell model according to the results of dynamic modulus test. Then a 3D finite element model for the interaction system of vehicle and ballastless track structure was presented and validated by field measured data. The results indicated that the tensile strain at the bottom of the ACWL was at a relatively low level and the vertical dynamic responses of each structural layer are obviously reduced due to the application of ACWL. Therefore, the full cross-section ACWL helps to reduce the vibration of the track structure and maintain the long-term stability of the subgrade.

Published

2019

21. Application of Mastic Asphalt Waterproofing Layer in High-Speed Railway Track in Cold Regions

Author

Song Liu, Jun Yang, Xianhua Chen, Guotao Yang, and Degou Cai

Subjects

high-speed railway, cold region, waterproofing layer, mastic asphalt, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Freeze-thaw damage is a typical distress incurred in road and railway engineering in cold regions. Concrete waterproofing layer is commonly used in high-speed railway tracks to prevent the penetration of surface water, however, it cracks easily under thermal stress, especially in cold regions. Recently solutions have been proposed to increase the waterproofing layer’s cracking resistance by using asphalt layers. Nonetheless, the use of emulsified asphalt as well as dense-graded asphalt mixture were not effective enough. To improve the effectiveness, in this study, mastic asphalt was designed for application as the waterproofing layer on the subgrade surface of high-speed railway tracks in cold regions. The overall performance of mastic asphalt was preliminarily evaluated by laboratory tests, then a 200-m test section was constructed for field validation in northeastern China as part of a new high-speed railway line, and water content sensors were placed inside the subgrade to monitor the performance of the mastic asphalt waterproofing layer (MAWL). The subsequent field investigation and monitoring data during the two years operation showed that MAWL dramatically outperformed the conventional concrete waterproofing layer in terms of waterproof performance. Plenty of serious cracks were found in the conventional concrete waterproofing layer, but only a limited number of local cracks were observed in MAWL. As a result, MAWL keeps the water content of subgrade at a stable level. In addition, MAWL showed relatively high stability during the two years investigation period, and no obvious deterioration was observed in the test section.

Published

2018

22. Experimental Study on Engineering Characteristics of High-Speed Railway Subgrade Filler in Island Permafrost Regions

Author

Xiaohe Liu, Degou Cai, Hongye Yan, Zongqi Bi, and Zhuqing Li

Subjects

improved subgrade filler, Materials Chemistry, high-speed railway, permeability characteristics, Surfaces and Interfaces, frost heave rate, island permafrost, Surfaces, Coatings and Films

Abstract

The high-speed railway (HSR) subgrade has a strict settlement-control standard at the mm level, but its deformation stability is significantly threatened on permafrost with poor thermal stability and in susceptible-to-thawing settlements. Therefore, the filler suitable for permafrost regions needs to be explored and determined. In this study, the frost heaves, permeabilities and static strength characteristics of three coarse fillers were experimentally investigated, and the optimal subgrade filler was determined for the certain HSR, the first HSR in permafrost regions around the world. The test fillers include pure fillers, 5% cement improved fillers and 5% cement + 3% modifier improved fillers, and the effects of curing time, modifier content and freeze–thaw cycles were analyzed. The test results show that: (1) the frost heave rate and permeability coefficient decrease with the increase of curing time and modifier content, while increasing with the freeze-thaw cycles; (2) After six freeze–thaw cycles, the cement + modifier improved filler’s frost heave rate and permeability coefficient are 0.51 and 0.00331 cm/s, a larger decrease in the frost heave rate (more than 50%) and the permeability coefficient (about one order of magnitude) than that of pure filler; (3) The cement + modifier improved filler shares the highest compressive strength under different curing times and freeze-thaw cycles. In summary, the modifier has a more significant influence on the engineering characteristics than the curing time or freeze-thaw cycles, and the cement + modifier improved filler has the best comprehensive performance. This study will provide a technical reference for the foundation-treatment and disease-prevention of HSRs in island permafrost regions.

Published

2023

23. Recent advances in subgrade engineering for high-speed railway

Author

Xianfeng Liu, Junhua Xiao, Degou Cai, Qian Su, Guangqing Yang, Shengyang Yuan, and Guanlu Jiang

Abstract

In the last decade, the design and construction technologies of subgrade in high-speed railway (HSR) developed significantly. This article reviews corresponding development in five aspects, including mechanical properties of fill materials, dynamic performance of subgrade, foundation treatment, retaining structure, and smart construction technologies. It shows that for unbonded granular materials, it is acceptable to use static strength for subgrade design, but for clayey soil it would be more appropriate to base on shakedown theory. The mechanism for lime modified clay has been thoroughly reviewed, and the effect of lime content, curing age, and curing conditions on the behavior of lime-treated clay is discussed. The dynamic response of subgrade, especially the long-term deformation and dynamic stability analysis are important to understanding the behavior of HSR subgrade. The effect of track types, operation speed, etc. on the dynamic response of subgrade are reviewed first. Then, the prediction methods, influencing factors, and corresponding issue for long-term deformation of subgrade are presented, followed by the methods used for dynamic stability analysis. Three types of foundation treatment methods, including geosynthetic-reinforced pile-supported (GRPS) embankment, pile-raft structure, and pile-plate structure are reviewed for the corresponding load transmission mechanism, and application scenario. The static and dynamic behavior of four types of retaining structures are presented, including cantilever retaining wall, geosynthetic reinforced soil retaining wall, anchored retaining structure, and retaining wall reinforced by soil nailing. Finally, a series of new technologies correlated to smart construction are introduced, relating to the survey, design, construction, detection, and management of subgrade.

Published

2023

24. A Long-term Resilient Modulus Rate Dependent Model for Freezing–Thawing Coarse-Fine Mixtures Geomaterials

Author

Ke Wang, Liang Tang, Shuang Tian, XianZhang Ling, Yangsheng Ye, Degou Cai, and Min Liu

Abstract

The cyclic loading frequency (fcyc) effects on the resilient modulus (Mr) of freezing–thawing coarse–fine mixtures geomaterials (FTCFG) have always been a research hotspot. A series of long–term cyclic triaxial tests were conducted on FTCFG having different fines content (FC) under different number of freeze–thaw cycles (NFT) to investigate the effect of fcyc and deviator stress amplitude (qcyc) on the Mr of FTCFG. The freezing–thawing cyclic was found to improve the Mr of FTCFG. Additionally, Mr of FTCFG shown an obviously rate–dependent characteristics. Then three kinetic effects (rate effect, piston effect, and fatigue effect) are discussed in systemically which are related to qcyc, fcyc and moisture holding capacity (wh). Finally, a rate dependent model of long–term resilient modulus was developed to predict FTCFG materials’ resilient moduli as a function of qcyc, fcyc and wh. The comparisons between the calculation and experimental results reveal that the present model describes the Mr of FTCFG well.

Published

2022

25. Low-temperature cracking resistance of asphalt concretes for railway substructure exposed to repeated freeze-thaw cycles

Author

Xin Xiao, Jin Li, Degou Cai, Liangwei Lou, Yuefeng Shi, and Feipeng Xiao

Subjects

General Earth and Planetary Sciences, Geotechnical Engineering and Engineering Geology

Published

2023

26. Experimental Study on the Compaction Characteristics and Evaluation Method of Coarse-Grained Materials for Subgrade

Author

Shuang Tian, Yangsheng Ye, Xianzhang Ling, Liang Tang, Degou Cai, and Shanzhen Li

Subjects

Technology, compaction characteristic, geostatistical analysis, Compaction, CMV, Stability (probability), subgrade, Plate load test, Article, Evaluation methods, General Materials Science, Geotechnical engineering, Microscopy, QC120-168.85, Wave velocity, QH201-278.5, Subgrade, Engineering (General). Civil engineering (General), quality evaluation, TK1-9971, Shear (sheet metal), coarse-grained materials, Falling weight deflectometer, Descriptive and experimental mechanics, Environmental science, Electrical engineering. Electronics. Nuclear engineering, TA1-2040

Abstract

Coarse-grained materials are widely used in high-speed railway construction, and it is of great significance to research its compaction characteristics due to the high quality control requirements. In this regard, a field compaction experiment was conducted at a subgrade near Bazhou Station of Beijing-Xiong’an Intercity Railway. The test results of the compaction effect were presented in this study at first. The roller-integrated compaction measurements (i.e., compaction meter value, CMV) were compared with several traditional in-situ tests (i.e., plate load test, light falling weight deflectometer test, and shear wave velocity test). Then the stability of CMV was evaluated by the proposed δ criterion. The spatial uniformity of compaction was further investigated. Based on the analysis, the target value of CMV was preliminarily determined. It showed that Evd was more variable than CMV. The results convincingly indicated that the compaction parameters increased with the increasing number of roller passes at first. A further increase in compaction effort could result in the decompaction of material when the compaction number up to a certain value. The stability analysis method proposed in this study showed its potency of quantifying the percentage of areas with acceptable compaction. The geostatistical analysis could reflect the spatial uniformity of compaction. Overall, the conducted study could provide a useful reference for geo-material compaction control in the transportation engineering.

Published

2021

27. Mechanical properties of lightweight foam concrete filler for roadbed of high-speed railway

Author

Qian-Li Zhang, Yangsheng Ye, Degou Cai, Si Li, Wei Shaowei, and Li Zhongguo

Subjects

Cement, Materials science, Settlement (structural), 0211 other engineering and technologies, Foundation (engineering), 02 engineering and technology, Subgrade, engineering.material, 021001 nanoscience & nanotechnology, Foam concrete, Residual strength, Compressive strength, Fly ash, 021105 building & construction, engineering, General Earth and Planetary Sciences, Composite material, 0210 nano-technology, General Environmental Science

Abstract

A high-speed railway has high requirements for line smoothness, and uneven settlement control is the primary factor considered in the design and operation of the subgrade. The emergence of lightweight subgrade structures meets the needs of the development of the high-speed railway. As a kind of filling material with good performance, lightweight foam concrete can effectively reduce the load and excessive settlement of subgrade and effectively reduce the cost of foundation treatment. This paper studied the dynamic characteristics of lightweight foam concrete with different wet densities and water-bearing states under train loading. The effects of wet density and fly ash content on the compressibility, impermeability, and frost resistance of lightweight foam concrete were analyzed in detail. The results show that the lightweight foam concrete still has high residual strength after compression, which is about 60% of its peak strength. Under different mix ratios, the critical dynamic stress of the lightweight foam concrete is generally 0.2–0.3 times the unconfined compressive strength, and the dynamic elastic modulus increases with the increase of wet density and cyclic stress amplitude. With the fly ash content increasing, the volume water absorption of lightweight foam concrete decreases first and then increases, and the critical value of fly ash content is 40%. The frost resistance of lightweight foam concrete gradually increases with the increase of wet density, and the dynamic elastic modulus of the sample with 279 kg·m−3 density lost 41.1% after 20 freeze–thaw cycles. When the content of fly ash is 20%, the frost resistance of lightweight foam concrete is equivalent to that of pure cement.

Published

2021

28. Mechanical Modeling of Frozen Coarse-Grained Materials Incorporating Microscale Investigation

Author

Shuang Tian, Yangsheng Ye, Shanzhen Li, Liang Tang, Degou Cai, and Xianzhang Ling

Subjects

Shearing (physics), Dilatant, Materials science, 010504 meteorology & atmospheric sciences, Article Subject, 0211 other engineering and technologies, General Engineering, 02 engineering and technology, Microstructure, Overburden pressure, 01 natural sciences, Volume (thermodynamics), Hardening (metallurgy), TA401-492, General Materials Science, Geotechnical engineering, Elastic modulus, Materials of engineering and construction. Mechanics of materials, Microscale chemistry, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

In the cold regions of China, coarse-grained materials are frequently encountered or used as backfilling materials in infrastructure construction, such as dams, highways, railways, and mineral engineering structures. Effects of confining pressure (0.2, 0.5, and 1 MPa) and frozen temperature (−2, −5, −10, and −15°C) on the stress-strain response and elastic modulus were investigated using triaxial compression tests. Moreover, the microscale structures of a coarse-grained material were obtained by X-ray computed tomography. The coarse-grained material specimens exhibited strain-softening and significant dilatancy behaviors during shearing. A modified model considering microstructures of the material was proposed to describe these phenomena. The predicted values coincided well with the experimental results obtained in this study and other literatures. The sensitivity analysis of parameters indicated that the model can simulate the initial hardening and post-peak strain-softening behavior of soils. And the transition of volume strain from contraction to dilatancy can also be described using this model. The results obtained in this study can provide a helpful reference for the analysis of frozen coarse-grained materials in geotechnical engineering.

Published

2021

29. Mechanical Characteristics and Failure Mode of Asphalt Concrete for Ballastless Track Substructure Based on in Situ Tests

Author

Lou Liangwei, Qinghong Fu, Degou Cai, and Xianhua Chen

Subjects

Waterproofing, Materials science, ambient temperature, 0211 other engineering and technologies, 02 engineering and technology, Expansion joint, Track (rail transport), lcsh:Technology, lcsh:Chemistry, 0203 mechanical engineering, 021105 building & construction, Ultimate tensile strength, General Materials Science, asphalt concrete, ballastless track substructure, lcsh:QH301-705.5, Instrumentation, Fluid Flow and Transfer Processes, lcsh:T, business.industry, Process Chemistry and Technology, General Engineering, in situ test, Structural engineering, lcsh:QC1-999, Computer Science Applications, Vibration, Asphalt concrete, 020303 mechanical engineering & transports, lcsh:Biology (General), lcsh:QD1-999, cyclic train load, lcsh:TA1-2040, Substructure, lcsh:Engineering (General). Civil engineering (General), business, Failure mode and effects analysis, lcsh:Physics

Abstract

Asphalt concrete paved on the surface of a roadbed as a ballastless track substructure has an excellent waterproofing and vibration attenuation performance. However, the mechanical characteristics and the failure mode of this structure under the actions of a cyclic train load and ambient air temperature changes are still unclear. Therefore, a test section of an asphalt concrete substructure was constructed based on a high-speed railway ballastless track project in north China. In situ forced vibration tests and temperature-induced deformation monitoring tests were performed to investigate the mechanical responses of the asphalt concrete, respectively. Test results show that the bottom of the asphalt concrete layer is in the tensile state under the action of the cyclic train load. The surface of the asphalt concrete in contact with the base plate is subjected to tensile stress near the expansion joint under the action of the negative temperature gradient. Changes in the ambient temperature lead to more significant mechanical responses of the asphalt concrete substructure than the cyclic train load, especially near the expansion joint of the base plate. Therefore, the passive tensile failure mode may occur near the expansion joint of the base plate. However, it has also proved that setting isolation layers under the base plate near the expansion joint is an effective method to significantly reduce responses near the expansion joint in this research.

Published

2020

30. Investigation on Interface Damage between Cement Concrete Base Plate and Asphalt Concrete Waterproofing Layer under Temperature Load in Ballastless Track

Author

Tao Dong, Yu Zhu, Degou Cai, Xianhua Chen, and Gang Xu

Subjects

Waterproofing, Materials science, asphalt concrete waterproofing layer, 0211 other engineering and technologies, Base (geometry), 02 engineering and technology, interface damage, Track (rail transport), ballastless track, lcsh:Technology, lcsh:Chemistry, 021105 building & construction, General Materials Science, Composite material, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, Cement, business.industry, lcsh:T, Process Chemistry and Technology, General Engineering, Fracture mechanics, CZM, 021001 nanoscience & nanotechnology, Finite element method, lcsh:QC1-999, Computer Science Applications, Asphalt concrete, Cohesive zone model, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, 0210 nano-technology, business, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

The interfacial bond between cement concrete base plate (CCBP) and asphalt concrete waterproofing layer (ACWL) is a weak portion in the newly developed Chinese high-speed railway ballastless track. The interface damage caused due to fluctuating temperature load and dynamic train load is one of the most critical problems in Northern China. This paper aims to investigate the interface damage evolution process under temperature load via experimental and simulation analysis. Full-scale transverse shear tests were performed to explore the interface bond-slip mode of the adjacent ACWL and CCBP. Then, a finite element model of a ballastless track structure was built and a cohesive zone model (CZM) was utilized to model the interface damage initiation, crack propagation, and delamination process under uniform/gradient temperature load. Furthermore, the dynamic response of the ballastless track where CCBP and ACWL were partly/totally debonded was investigated and compared with the perfectly bonded structure. The results demonstrate that bilinear CZM is capable of revealing the interface damage initiation, crack propagation, and delamination process under temperature load. The interface state between the adjacent CCBP and ACWL was greatly affected by temperature changes and the interface bonding state had a great impact on the dynamic response of ballastless track.

Published

2020

31. Study on Intelligent Compaction-Equipment Logistics Scheduling and Propagation Characteristics of Vibration Wave in Nonlinear Systems with Multistability Based on Field Test

Author

Hailing Zeng, Hongye Yan, Yixuan Han, Changwei Yang, and Degou Cai

Subjects

Multidisciplinary, General Computer Science, Article Subject, Computer science, business.industry, 0211 other engineering and technologies, Scheduling (production processes), Compaction, 02 engineering and technology, Subgrade, Structural engineering, QA75.5-76.95, Vibration, Nonlinear system, Acceleration, Harmonics, Electronic computers. Computer science, 021105 building & construction, business, Energy (signal processing), 021101 geological & geomatics engineering

Abstract

The equipment scheduling and propagation characteristics of vibration wave from vibratory roller ⟶ filling material nonlinear systems with multistability are the core problems of subgrade intelligent construction technology, and the logistics scheduling of the equipment is directly related to the construction efficiency. Aiming at the shortages, one typical subgrade located at the Gu’an station of Beijing-Xiong’an city railway is selected to research and finish the field tests; some findings are shown as follows: first, some valuable suggestions about the logistics scheduling of intelligent equipment are proposed, which can break the barriers between the organizations and improve construction efficiency; second, when the vibration wave propagates from the vibratory roller ⟶ surface of filling material ⟶ different buried depths of filling material, the peak acceleration of vibration wave gradually decreases and is hyperbolic distribution approximately. At the same time, the sensitive of attenuation is shown as follows: ZR2>0.9), and the concrete functional relationship among different amplitudes of harmonics can be summarized as y = Ae−BX; fourth, the vibration energy is mainly concentrated near 10–30 Hz in the vibratory roller, but when the vibration wave propagates from vibratory roller⟶filling material, the vibration energy gradually decreases with the increase in depth, and the marginal spectrum gradually changes from one peak to two peaks, that is, 30–50 Hz and 50–100 Hz; fifth, the vibration energy in the vibrational wheel is distributed averagely in the compaction process, and the effective compaction time is two seconds, which will be helpful for revealing the propagation characteristics of vibration wave, optimizing the compaction quality control models and providing some support for the development of intelligent compaction theory of railway subgrade.

Published

2020

32. Experimental and numerical investigation of the effect of soil type and fineness on soil frost heave behavior

Author

Xiaoyu Cao, Wei She, Hu Xiangyu, Degou Cai, Guotang Zhao, and Jinyang Jiang

Subjects

010504 meteorology & atmospheric sciences, Fineness, 0211 other engineering and technologies, Foundation (engineering), Frost heaving, 02 engineering and technology, Geotechnical Engineering and Engineering Geology, Microstructure, Soil type, 01 natural sciences, chemistry.chemical_compound, Montmorillonite, chemistry, Hydraulic conductivity, Soil water, General Earth and Planetary Sciences, Geotechnical engineering, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

The type and fineness of soil are commonly recognized as the two major factors affecting the frost heave behavior of foundation. This paper aims to study the effect of soil type and fineness on frost heave behavior by experimental and numerical methods. Optical and scanning electron microscopes were employed to study the microstructure of kaolin and montmorillonite soils. A finite volume method, considering the changes of thermal and water fields simultaneously, was used to model the frost heave behavior of finely grained soil. By coupling the rigid ice model with the modified Kozeny–Carman equation and estimating the hydraulic conductivity, the relationship between the frost heave ratio and specific surface area of fines was established. Based on the modeling results, a region of proportion range of three typical soil (silty, clay and sandy soil) was proposed based on the ternary plot of frost heave values. Microscopic test results show that the multilayer microstructure of kaolin results in high content of bonded water compared with that of montmorillonite, leading to higher frost heave value. This model is proved to be reliable by a good agreement between the predicted and measured frost heave values.

Published

2018

33. In-situ test and analysis of subgrade vibration with ballasted track in deep seasonally frozen regions

Author

Shuang Tian, Liang Tang, Yangsheng Ye, Ke Wang, Shanzhen Li, Degou Cai, and Xianzhang Ling

Subjects

Vibration, Ballast, Amplitude, Attenuation, Slab, Transportation, Natural frequency, Geotechnical engineering, Subgrade, Geotechnical Engineering and Engineering Geology, Track (rail transport), Geology, Civil and Structural Engineering

Abstract

The effect of seasons on the vibration characteristics of subgrade has been a worldwide problem with the rapid development of high-speed railways, especially in Northeast China. To this end, field investigations were carried out on the Harbin–Jiamusi rapid railway during unfrozen and frozen periods. The vertical acceleration responses in time and frequency domains were studied in detail. To explain the influence of track structure on the vibration responses of subgrade, the authors also conducted a comparison between ballasted and ballastless tracks. The results showed that the amplitude of vertical acceleration increased with the increasing train speed and attenuated with increasing distance from the track centreline. The attenuation rate in the unfrozen period was greater due to the soil's damping properties. It was also found that the peak frequencies in the ballast layer were generated by resonance at its natural frequency, which increased from about 80 Hz to around 100 Hz as the subgrade was frozen. The comparisons between ballasted and ballastless tracks revealed that the acceleration amplitude of the subgrade with ballasted track was higher than that of the subgrade with ballastless track. Furthermore, the wide high-frequency range in the ballasted track is mainly generated by the short-wave track irregularities (i.e., 0.01–0.5 m). The frequencies induced by the short-wave track irregularities were not significant in the subgrade with ballastless track due to the different properties of ballast and concrete track slab. Overall, the study provides a helpful reference for the construction and operation of high-speed railways, particularly in seasonally frozen regions.

Published

2021

34. Evolution of Rheological Behaviors of Styrene-Butadiene-Styrene/Crumb Rubber Composite Modified Bitumen after Different Long-Term Aging Processes

Author

Ye Yangsheng, Gang Xu, Shi Yuefeng, Lou Liangwei, Xianhua Chen, and Degou Cai

Subjects

Waterproofing, Styrene-butadiene, Materials science, Composite number, 0211 other engineering and technologies, 02 engineering and technology, long-term aging, lcsh:Technology, Article, chemistry.chemical_compound, 021105 building & construction, SBS/CR modified asphalt, General Materials Science, Crumb rubber, Composite material, lcsh:Microscopy, lcsh:QC120-168.85, lcsh:QH201-278.5, lcsh:T, anti-aging, high speed railway, Subgrade, 021001 nanoscience & nanotechnology, Durability, Creep, chemistry, Asphalt, lcsh:TA1-2040, lcsh:Descriptive and experimental mechanics, lcsh:Electrical engineering. Electronics. Nuclear engineering, 0210 nano-technology, lcsh:Engineering (General). Civil engineering (General), lcsh:TK1-9971

Abstract

In this study, a new type of composite modified bitumen was developed by blending styrene-butadiene-styrene (SBS) and crumb rubber (CR) with a chemical method to satisfy the durability requirements of waterproofing material in the waterproofing layer of high-speed railway subgrade. A pressure-aging-vessel test for 20, 40 and 80 h were conducted to obtain bitumen samples in different long-term aging conditions. Multiple stress creep recovery (MSCR) tests, linear amplitude scanning tests and bending beam rheometer tests were conducted on three kinds of asphalt binders (SBS modified asphalt, CR modified asphalt and SBS/CR composite modified asphalt) after different long-term aging processes, including high temperature permanent deformation performance, resistance to low temperature thermal and fatigue crack. Meanwhile, aging sensitivities were compared by different rheological indices. Results showed that SBS/CR composite modified asphalt possessed the best properties before and after aging. The elastic property of CR in SBS/CR composite modified asphalt improved the ability to resist low temperature thermal and fatigue cracks at a range of low and middle temperatures. Simultaneously, the copolymer network of SBS and CR significantly improved the elastic response of the asphalt SBS/CR modified asphalt at a range of high temperatures. Furthermore, all test results indicated that the SBS/CR modified asphalt possesses the outstanding ability to anti-aging. SBS/CR is an ideal kind of asphalt to satisfy the demand of 60 years of service life in the subgrade of high speed railway.

Published

2019

35. Dynamic Responses of Asphalt Concrete Waterproofing Layer in Ballastless Track

Author

Degou Cai, Qinghong Fu, Jie Zhou, Xianhua Chen, and Gang Xu

Subjects

Waterproofing, 0211 other engineering and technologies, 02 engineering and technology, Track (rail transport), ballastless track, lcsh:Technology, lcsh:Chemistry, 021105 building & construction, Dynamic modulus, General Materials Science, asphalt concrete, Instrumentation, lcsh:QH301-705.5, 021101 geological & geomatics engineering, dynamic response, Fluid Flow and Transfer Processes, business.industry, Generalized Maxwell model, lcsh:T, Process Chemistry and Technology, General Engineering, Subgrade, Structural engineering, linear viscoelasticity, Finite element method, lcsh:QC1-999, Computer Science Applications, Asphalt concrete, lcsh:Biology (General), lcsh:QD1-999, Asphalt, lcsh:TA1-2040, dynamic modulus, business, lcsh:Engineering (General). Civil engineering (General), Geology, lcsh:Physics

Abstract

The application of asphalt concrete waterproofing layer (ACWL) for the subgrade has been a trend in Chinese high-speed railway. The purpose of this research is to discuss the dynamic characteristics of full cross-section ACWL in the ballastless track structure under the train loads. The laboratory tests were conducted to evaluate the performance of the asphalt mixtures for the ACWL and a test section of ACWL was constructed on the high-speed railway in north China. The linear viscoelastic behavior of the asphalt concrete obtained from the test section was characterized by the generalized Maxwell model according to the results of dynamic modulus test. Then a 3D finite element model for the interaction system of vehicle and ballastless track structure was presented and validated by field measured data. The results indicated that the tensile strain at the bottom of the ACWL was at a relatively low level and the vertical dynamic responses of each structural layer are obviously reduced due to the application of ACWL. Therefore, the full cross-section ACWL helps to reduce the vibration of the track structure and maintain the long-term stability of the subgrade.

Published

2019

36. Review on dynamic modulus of coarse-grained soil filling for high-speed railway subgrade

Author

Degou Cai, Chen Feng, Wei Shaowei, Junkai Yao, Yangsheng Ye, and Hongye Yan

Subjects

Attenuation, 0211 other engineering and technologies, Modulus, Transportation, 02 engineering and technology, Subgrade, Geotechnical Engineering and Engineering Geology, Overburden pressure, Track (rail transport), 021105 building & construction, Dynamic modulus, Geotechnical engineering, Deformation (engineering), Water content, Geology, 021101 geological & geomatics engineering, Civil and Structural Engineering

Abstract

The attenuation of dynamic modulus of coarse-grained soil filling with the increase of the strain should be considered in the refined design of the high-speed railway subgrade. On the basis of a large number of past investigations by other researchers on dynamic modulus of coarse-grained soil at home and abroad, this paper analyzes the mechanical properties of coarse-grained soil filling in high-speed railway subgrade under cyclic train load, with characteristics of small confining pressure, high density, low water content and weak structural property. By summarizing the empirical models of dynamic modulus and the range of attenuation curves, a method to determine the value of dynamic modulus of coarse-grained soil filling in high-speed railway subgrade has been proposed, with the reasonable range of the working dynamic modulus ratio being discussed. According to the measured dynamic deformation of ballastless track subgrade for a number of high-speed railway lines in China, the average working dynamic modulus of graded gravel in the surface layer and class A&B filling material in the bottom layer of the subgrade are 0.60–0.80 times and 0.73–0.90 times of the maximum modulus, respectively.

Published

2021

37. Performance Test and Stability Analysis of Jute Ecological Bag on Subgrade Slope.

Author

Zhang, L., Defilla, S., Chu, W., Shaowei, Wei, Degou, Cai, Song, Lv, and Jianping, Yao

Published

2021

38. Experimental study on frost heave of high-speed railway subgrade in the seasonally frozen region

Author

Zhao Guotang, Chen Feng, DeGou Cai, HongYe Yan, Yang Guotao, and JianPing Yao

Subjects

010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Frost heaving, Geotechnical engineering, 02 engineering and technology, Subgrade, 01 natural sciences, Geology, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Published

2016

39. Dynamic behavior of coarse-grained materials with different fines contents after freeze-thaw cycles under multi-stage dynamic loading: Experimental study and empirical model

Author

Degou Cai, Liang Tang, Xianzhang Ling, Xiangxun Kong, Shanzhen Li, and Shuang Tian

Subjects

Damping ratio, Materials science, 010504 meteorology & atmospheric sciences, Seismic loading, 0211 other engineering and technologies, 02 engineering and technology, Subgrade, Geotechnical Engineering and Engineering Geology, 01 natural sciences, Base course, Shear modulus, Multi stage, Dynamic loading, Shear stress, General Earth and Planetary Sciences, Geotechnical engineering, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

The effect of freeze-thaw (F-T) cycles on dynamic behavior of coarse-grained materials (CGMs) (i.e., coarse-grained materials used in railway subgrade named as base course materials) is critical to ensure the service status of railway subgrade in seasonally frozen regions. In this study, a series of stress-controlled dynamic triaxial tests were conducted on CGMs with various fines contents (FCs) exposed to F-T cycles. Typical test results were then analysed and discussed, highlighting the environmental effect on the dynamic properties. The results demonstrated that the dynamic shear modulus decreased with the increase of FC or the number of freeze-thaw cycles (NFT), but the damping ratio (D) results indicated just the reverse characteristic. In this regard, a modified empirical model was determined to describe the relationship between dynamic shear modulus (Gd) and dynamic shear strain amplitude ( γ ¯ d ). Meanwhile, a unified mathematical formula was proposed to characterize D. Furthermore, the two proposed empirical equations were found to be severely inconsistent with the previous ranges suit for seismic loading. The study provides a useful reference for preliminary evaluation of the response to train loading for CGMs subjected to F-T cycles.

Published

2020

40. Multi-scale damage characterization of asphalt mixture subject to freeze-thaw cycles

Author

Xianhua Chen, Guanyu Xie, Degou Cai, Yunhong Yu, Gang Xu, and Jun Yang

Subjects

Imagination, Void (astronomy), Mesoscopic physics, Materials science, Chemical substance, Scanning electron microscope, media_common.quotation_subject, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Building and Construction, 0201 civil engineering, Asphalt, 021105 building & construction, Ultimate tensile strength, General Materials Science, Composite material, Civil and Structural Engineering, media_common, Tensile testing

Abstract

This paper summarizes the results of laboratory tests including scanning electron microscopy (SEM), X-ray computed tomography (CT), a developed interfacial shear test and the indirect tensile test. These tests were performed to characterize the damage of dense-graded asphalt mixture under freeze-thaw cycles from different length scales. SEM was utilized to observe the surface of asphalt mixture samples and showed that micro-cracks occurred at the contact interface between asphalt and aggregate after cyclic freeze-thaw exposure, indicating the loss of adhesion bonds at the aggregate-mastic interface. Meanwhile, X-ray CT and a set of image processing techniques were employed to capture the evolution of three-dimensional internal structure within samples under freeze-thaw cycles from a mesoscopic-view. Three-dimensional images reconstructed from X-ray CT images illustrated that the diversification in internal structure was observed to occur mainly in three ways: (1) expansion of existing individual voids, (2) combination of two separated air voids, and (3) generation of new voids. Furthermore, a developed interfacial shear test was conducted to quantify shear bond properties between asphalt and aggregate, which revealed that the interfacial shear strength decreases with the increase of the number of freeze-thaw cycles and declines rapidly at the initial stage of freeze-thaw cycles. Finally, the indirect tensile test (IDT) was applied to evaluate the loss of tensile strength within the samples on a macro-scale. The evolution of IDT strength consisted with the variations of mesoscopic parameters such as interfacial shear strength, three-dimensional void content and void number, and then a systematic evaluation of moisture damage of asphalt mixture could be done.

Published

2020

41. Study on the Transmission and Evolution Characteristics of Vibration Wave from Vibratory Roller to Filling Materials Based on the Field Test

Author

Yixuan Han, Shaowei Wei, Degou Cai, Liang Zhang, and Changwei Yang

Subjects

Materials science, Acoustics, subgrade compaction, 0211 other engineering and technologies, Compaction, high-speed railway, 02 engineering and technology, lcsh:Technology, lcsh:Chemistry, Acceleration, Quality (physics), 021105 building & construction, General Materials Science, Time domain, lcsh:QH301-705.5, Instrumentation, 021101 geological & geomatics engineering, Fluid Flow and Transfer Processes, field test, lcsh:T, Process Chemistry and Technology, time–frequency characteristics, General Engineering, Subgrade, lcsh:QC1-999, Computer Science Applications, Vibration, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Frequency domain, Harmonics, lcsh:Engineering (General). Civil engineering (General), nonlinear transmission mechanism, lcsh:Physics

Abstract

Compaction quality of railroad subgrade relates directly to the stability and safety of train operation, and the core problem of the Intelligent Compaction of railroads is the transmission and evolution characteristics of vibration wave. Aiming at the shortages in exploring the transmission and evolution characteristics of the vibration signal, the typical subgrade compaction project of Jingxiong Intercity Railway Gu&rsquo, an Station was selected to carry out the field prototypes tests, and the dynamic response from the vibratory roller to filling materials was monitored in the whole compaction process, and some efficient field tests data will be obtained. Based on this, the transmission and evolution characteristics of the vibration wave from the vibratory roller to filling materials in the compaction process are studied from the time domain, frequency domain, jointed time&ndash, frequency domain and energy domain by using one new signal analysis technology&mdash, Hilbert&ndash, Huang Transform. Some conclusions are shown as follows: first, the vibration acceleration peak gradually decreases with the increase of buried depth, and when the buried depth reaches 1.8 m, the vibration acceleration peak is closed to zero. At the same time, when the vibration wave propagates from the wheel to the surface of filling, the attenuation rate of acceleration gradually increases with the increase of rolling compaction times, while the attenuation rate of other layers in different buried depths gradually decreases. Second, the vibration wave contains fundamental wave and multiple harmonics, and the dominant frequency of the fundamental wave is nearly 21 Hz. With the increase of buried depth, the amplitude of fundamental, primary, secondary, until fifth harmonics decreases exponentially and the concrete functional relationship among different amplitudes of harmonics can be summarized as y = Ae&minus, BX. Third, the vibration energy focuses on the fundamental wave and primary wave, which can increase with the increase of rolling compaction times, and when the rolling compaction time reaches five, their energy reaches maximum. However, when the filling reaches a dense situation, the energy of the primary wave gradually decreases. Therefore, the maximum rolling compaction time is five in the practical engineering applications, which will be helpful for optimizing the compaction quality control models and providing some support for the development of the Intelligent Compaction theory of railway subgrade.

Published

2020

42. Interaction Mechanism of the Frost Heaving of the Filler and Skeleton Particles in a Micro-Frost-Heaving Filling Material

Author

Qian-Li Zhang, Yangsheng Ye, Du Xiaoyan, and Degou Cai

Subjects

Materials science, Filling ratio, Frost heaving, General Earth and Planetary Sciences, High stiffness, Composite material, General Environmental Science

Abstract

To address the adverse effects of the frost heaving of subgrades in regions with seasonal frozen soil on the smoothness of high-speed railway tracks, the effects of several factors—including filler, water content and external loading—on a micro-frost-heaving (MFH) filling material were studied through laboratory experiments and theoretical analysis. In addition, the interaction mechanism between the filler and skeleton particles during the frost heaving process was analyzed. The results show the following: The MFH filling material was composed of a coarse-grained skeleton, a filler between skeleton particles and the remaining unfilled voids. When the filling ratio of the filler was 0.25, the filling material underwent initial macroscopic frost heaving. An overlying load could inhibit the filling material from frost heaving. During the frost heaving process, the volume of coarse skeleton particles with high stiffness remained almost unchanged, whereas the filler expanded in volume and thus filled the remaining voids between skeleton particles and lifted the skeleton particles, resulting in macroscopic frost heaving of the filling material. When their ratio was relatively high, the remaining voids between skeleton particles had a strong absorptivity and weakened the capacity of the filler to lift the skeleton particles. The filler raised the skeleton particles, resulting in an increase in the gaps between them, which in turn facilitated the filling action of the filler. When the skeleton structure was stable, the filling action of the filler was more pronounced. The frost heaving of an MFH filling material is in fact a dynamic equilibrium process between the filling and lifting actions of the filler.

Published

2018

43. Engineering Test Research of XPS Insulation Structure Applied in High Speed Railway of Seasonal Frozen Soil Roadbed

Author

JianPing Yao, Cui Yinghui, HongYe Yan, Chen Feng, and DeGou Cai

Subjects

Engineering, Field monitoring, Field tests, 010501 environmental sciences, 01 natural sciences, Insulation layer, X-ray photoelectron spectroscopy, 0502 economics and business, Thermal, Geotechnical engineering, Engineering(all), 0105 earth and related environmental sciences, business.industry, Insulation materials, 05 social sciences, General Medicine, Structural engineering, Subgrade, High-speed railway, Dynamic test, Condensed Matter::Strongly Correlated Electrons, Deformation (engineering), business, 050203 business & management, Dynamic testing

Abstract

Dynamic performance and thermal properties of insulation materials are the key parameters during the insulation application for high-speed railway subgrade. This paper conducted field tests and field monitoring for the materials, especially for thermal performance, elastic deformation, and accumulated deformation of insulation materials. Experiment results show that mechanical properties of full section insulation layer structure is stable, which satisfies the requirements of the high speed railway.