Your search keyword '"Hongduo Zhao"' showing total 71 results

1. Tire-pavement friction modeling considering pavement texture and water film

Author

Lanruo Zhao, Hongduo Zhao, and Juewei Cai

Subjects

Pavement engineering, LuGre friction model, Friction coefficient, Pavement texture, Water film thickness, Transportation engineering, TA1001-1280

Abstract

The accurate estimation of tire-pavement friction, especially under wet conditions, is critical to ensure pavement safety. For this purpose, this paper develops a modified tire-pavement friction model which takes the effect of pavement texture and water film into consideration. The influence of pavement texture is quantified by a newly proposed parameter called texture influence coefficient, which is related to the real contact patch of tire-pavement. The water effect is calculated from two parts, namely lubrication effect and hydrodynamic effect. Based on these two steps, a modified average lumped LuGre (ALL) model is developed. The proposed model is calibrated and verified by GripTester data collected under different vehicle velocities and water film thicknesses. The root mean square error between the calculated value of the model and the measured value is 0.023. In addition, the effects of vehicle velocity, slip rate, water film thickness, and pavement type on the friction coefficient are analyzed by numerical calculation. The results show that the friction coefficient reaches the maximum when the slip rate is in the range of [0.15, 0.20]. The increases in the vehicle speed and water film thickness will lead to the decrease in the friction coefficient. Besides, in thin water film (

Published

2024

2. Structural optimization and performance evaluation of precast concrete pavement with composite base layer

Author

Hongduo Zhao, Haoyu Chen, Chenchen Li, and Lukuan Ma

Subjects

Precast concrete pavement, Composite base layer, Structural optimization, Performance evaluation, Transportation engineering, TA1001-1280

Abstract

This paper proposed a precast concrete pavement structure with the composite base layer comprised of the concrete beam and the filling low strength materials (B-PCP). The mechanical responses of the B-PCP induced by moving wheel loads coupled with temperature loads were analysed using the finite element method. Then the optimal geometry of the concrete beam was determined based on the sensitivity analysis, considering the tensile stress of both the slab and the beam of the base layer, the slab curling, and the faulting. Furthermore, the performance evaluation of the B-PCP was conducted by the numerical analysis and the scale experiment testing, respectively. The results showed that the optical concrete beam was 0.8 ∼ 1.0 m wide and 0.2 ∼ 0.3 m thick. The numerical results showed that the optimal B-PCP structure had a good fatigue resistance performance, and the corresponding slab curling decreased by almost 40% compared with that of the traditional precast concrete pavement. Meanwhile, the scale experiment testing verified that the optimal B-PCP structure exhibited an excellent ability to resist the deformation. The results also showed that the bearing capacity of the optimal B-PCP structure was larger than 350kN, indicating a good bearing capacity.

Published

2023

3. Temporal Convolutional Network-Based Axle Load Estimation from Pavement Vibration Data

Author

Zeying Bian, Mengyuan Zeng, Hongduo Zhao, Mu Guo, and Juewei Cai

Subjects

weigh in motion, axle load estimation, pavement vibration, temporal convolutional networks, distributed optical vibration sensing, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Measuring the axle loads of vehicles with more accuracy is a crucial step in weight enforcement and pavement condition assessment. This paper proposed a vibration-based method, which has an extended sensing range, high temporal sampling rate, and dense spatial sampling rate, to estimate axle loads in concrete pavement using distributed optical vibration sensing (DOVS) technology. Temporal convolutional networks (TCN), which consist of non-causal convolutional layers and a concatenate layer, were proposed and trained by over 6000 samples of vibration data and ground truth of axle loads. Moreover, the TCN could learn the complex inverse mapping between pavement structure inputs and outputs. The performance of the proposed method was calibrated in two field tests with various conditions. The results demonstrate that the proposed method obtained estimated axle loads within 11.5% error, under diverse circumstances that consisted of different pavement types and loads moving at speeds ranging from 0~35 m/s. The proposed method demonstrates significant promise in the field of axle load reconstruction and estimation. Its error, closely approaching the 10% threshold specified by LTPP, underscores its efficacy. Additionally, the method aligns with the standards set by Cost-323, with an error level-up to category C. This indicates its capability to provide valuable support in the assessment and decision-making processes related to pavement structure conditions.

Published

2023

4. Load Transfer Efficiency Assessment of Concrete Pavement Joints Using Distributed Optical Vibration Sensor

Author

Mengyuan Zeng, Hongduo Zhao, Kedi Peng, Zeying Bian, and Difei Wu

Subjects

load transfer efficiency, concrete pavement, joint, distributed optical vibration, power spectral density, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper presents a method to assess the load transfer efficiency (LTE) of concrete pavement joints using distributed optical vibration sensors. First, a theoretical analysis of concrete pavement vibration was conducted to investigate how to reflect LTE by spectral amplitude. Second, distributed optical vibration sensor (DOVS) was applied to measure vibration around joints distributedly. Third, the corresponding processing method for DOVS data was proposed to calculate the ratio of spectral amplitude from different slabs through power spectral density (PSD) analysis. Then, field tests were conducted on nine concrete pavement slabs with three different types of joints (dummy joint, rabbet joint, and dowel bars). The deflection-based method as well as the proposed vibration-based method were employed to assess the LTE of eleven joints on two different dates. The comparative analysis results indicate the deflection-based LTE (DLTE) and the ratio of PSD (RPSD) have a strong correlation (0.871) and a slight difference (

Published

2022

5. Effects of temperature variations on the deflections of airfield jointed plain concrete pavements

Author

Hongduo Zhao, Lukuan Ma, and Jiake Zhang

Subjects

Transportation engineering, TA1001-1280

Abstract

This paper aims to study the influences of temperature variations on airfield jointed plain concrete pavement (JPCP) deflections. The maximum deflection at the transverse joint (D0j), the maximum deflection at the corner of a slab (D0c), and the deflection basin at the centre of a slab were considered. The in-situ deflection measurements at three civil airports were conducted over a 24-hour period and numerical simulations for JPCP at a civil airport were performed as well. The results indicate that the temperature change slightly affects the deflection basin at the centre of a slab unless the positive temperature gradient in the slab increases to exceed a certain critical value. But both D0j and D0c are significantly affected by temperature variations. The results of in-situ tests show that D0j (or D0c) is almost stable from 1 pm and 5 pm in a day. At other times of one day, there is a strong negative liner correlation between D0j (or D0c) and the pavement surface temperature during the heating period and the cooling period, respectively. The results of numerical simulations reveal that both D0j and D0c gradually increase with the increase of the average temperature. The results of numerical simulations also suggest that a critical negative/positive temperature gradient exists at the transverse joint while there is a critical positive temperature gradient at the slab corner. Besides, all the critical temperature gradients are seldom affected by the average temperature. When the temperature gradient exceeds the critical value, D0j, D0c and all values of the deflection basin have a strong positive linear correlation with the temperature gradient. Keywords: Jointed plain concrete pavement, Falling weight deflectometer, Numerical simulations, Temperature variations, Deflections

Published

2018

6. Development and Piezoelectric Properties of a Stack Units-Based Piezoelectric Device for Roadway Application

Author

Chenchen Li, Fan Yang, Pengfei Liu, Chaoliang Fu, Quan Liu, Hongduo Zhao, and Peng Lin

Subjects

pavement engineering, energy harvesting, piezoelectric device, stacked piezoelectric unit, piezoelectric properties, roadway application, Chemical technology, TP1-1185

Abstract

To improve the energy harvesting efficiency of the piezoelectric device, a stack units-based structure was developed and verified. Factors such as stress distribution, load resistance, loads, and loading times influencing the piezoelectric properties were investigated using theoretical analysis and experimental tests. The results show that the unit number has a negative relationship with the generated energy and the stress distribution has no influence on the power generation of the piezoelectric unit array. However, with a small stress difference, units in a parallel connection can obtain high energy conversion efficiency. Additionally, loaded with the matched impedance of 275.0 kΩ at 10.0 kN and 10.0 Hz, the proposed device reached a maximum output power of 84.3 mW, which is enough to supply the low-power sensors. Moreover, the indoor load test illustrates that the electrical performance of the piezoelectric device was positively correlated with the simulated loads when loaded with matched resistance. Furthermore, the electrical property remained stable after the fatigue test of 100,000 cyclic loads. Subsequently, the field study confirmed that the developed piezoelectric device had novel piezoelectric properties with an open-circuit voltage of 190 V under an actual tire load, and the traffic parameters can be extracted from the voltage waveform.

Published

2021

7. Test and Analysis of Bridge Transducers for Harvesting Energy from Asphalt Pavement

Author

Hongduo ZHAO, Luyao QIN, and Jianming LING

Subjects

Energy harvesting, Piezoelectric, Bridge transducer, Asphalt pavement, Finite element analysis, Transportation engineering, TA1001-1280

Abstract

Part of energies in asphalt pavement caused by vehicle can be converted into electric energy by piezoelectric transducer. A bridge-shaped transducer is selected to harvest energy because of its reasonable efficiency and moderate stiffness close to asphalt pavement. This paper is to compare the performance of Bridge transducers with trapezoidal, arc and arch structure through finite element analysis (FEA) and laboratory test. Results show that the arch Bridge has higher energy conversion efficiency and the trapezoidal Bridge has stronger ability to resist pressure. For arc and trapezoidal Bridge, the maximum tensile stress and shear stress are both in the inner corner of contact area between cap and PZT (lead zirconate titanate) disk. They were broken because of the cracking of PZT at the stress concentrations area. For arch Bridge, the maximum tensile stress increases with thickness of metal cap but decrease with modulus, and maximum shear stress decreases first and increases later with increasing thickness and modulus of metal cap. In laboratory test, its cracking area is shifted from edge to inner corner of contact area between cap and PZT disk with increasing thickness of metal cap. The electric potential generated by arch Bridge decreased with increasing thickness and modulus of metal cap. Under the load of 0.7 MPa, the electric potential is about 286 V for an arch Bridge transducer with 0.4mm thickness of stainless steel cap, and its storage electric energy is 0.6 mJ. The designed arch Bridge transducer is suggested as the optimum one for harvesting energy from asphalt pavement.

Published

2015

8. Special issue: Safer road infrastructure and operation management

Author

Hongduo Zhao and Feng Chen

Subjects

Transportation engineering, TA1001-1280

Published

2017

9. Characterization of Moisture Diffusion in Cured Concrete Slabs at Early Ages

Author

Xiao Zhang and Hongduo Zhao

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The objective of this paper is to investigate the characterization of moisture diffusion inside early-age concrete slabs subjected to curing. Time-dependent relative humidity (RH) distributions of three mixture proportions subjected to three different curing methods (i.e., air curing, water curing, and membrane-forming compounds curing) and sealed condition were measured for 28 days. A one-dimensional nonlinear moisture diffusion partial differential equation (PDE) based on Fick’s second law, which incorporates the effect of curing in the Dirichlet boundary condition using a concept of curing factor, is developed to simulate the diffusion process. Model parameters are calibrated by a genetic algorithm (GA). Experimental results show that the RH reducing rate inside concrete under air curing is greater than the rates under membrane-forming compound curing and water curing. It is shown that the effect of water-to-cement (w/c) ratio on self-desiccation is significant. Lower w/c ratio tends to result in larger RH reduction. RH reduction considering both effect of diffusion and self-desiccation in early-age concrete is not sensitive to w/c ratio, but to curing method. Comparison between model simulation and experimental results indicates that the improved model is able to reflect the effect of curing on moisture diffusion in early-age concrete slabs.

Published

2015

10. Reconstruction of Vehicle-Induced Vibration on Concrete Pavement Using Distributed Fiber Optic.

Author

Mengyuan Zeng, Hongduo Zhao, Dachen Gao, Zeying Bian, and Difei Wu

Published

2022

11. Tire-pavement friction modeling considering pavement texture and water film

Author

Lanruo Zhao, Hongduo Zhao, and Juewei Cai

Subjects

Automotive Engineering, Transportation, Management, Monitoring, Policy and Law, Civil and Structural Engineering

Published

2023

12. Experimental Investigation of Piezoelectric Energy Harvesters Applied in Concrete Pavement

Author

Chenchen Li, Hongduo Zhao, Yu Tian, and Zhongpu Lin

Subjects

Mechanical Engineering, Civil and Structural Engineering

Abstract

This paper proposes the application and manufacturing of piezoelectric devices based on pile and arc-bridge transducers to harvest mechanical energy from concrete pavement. Multi-scale experiments are conducted to clarify the influence of electrical connection, load resistance, traffic speed, and loading times on the electrical properties of the harvesters. The reduced-scale test shows that the transducers should be connected to rectifiers before being connected as an array. Moreover, the output power of the arc-bridge transducer with resistance variations is unstable compared with that of the pile transducer. Accelerated pavement testing illustrates that the output power of the half pile array device increases to 1.7 mW with an optimal resistance of 10.0 MΩ; reducing the internal equivalent resistance is a potential way to increase the energy output. The results also show that the load speeds significantly influence the profile of the voltage and have a minor effect on the generated electric energy in the tested conditions. Furthermore, the electrical properties of the piezoelectric device exhibit no statistical degradation after the electrical fatigue test of 100,000 tire loads, indicating a novel electrical fatigue performance. The findings in this paper can further guide the application of such piezoelectric devices in concrete pavement.

Published

2022

13. A 3D virtual prototype-finite element co-simulation of aircraft hydroplaning on a wet rough runway

Author

Xingyi Zhu, Ming Yang, Hongduo Zhao, and Shunjie Bai

Subjects

050210 logistics & transportation, 05 social sciences, 0211 other engineering and technologies, 02 engineering and technology, Co-simulation, Finite element method, Aquaplaning, Aircraft landing, Skid (automobile), Mechanics of Materials, 021105 building & construction, 0502 economics and business, Environmental science, Runway, Civil and Structural Engineering, Marine engineering

Abstract

Skid-resistance performance of a runway greatly influences aircraft landing safety. A wet runway significantly increases the incidence rates of aircraft overrun. To study the influence of the skid-...

Published

2021

14. Structural optimization and performance evaluation of precast concrete pavement with composite base layer

Author

Hongduo Zhao, Haoyu Chen, Chenchen Li, and Lukuan Ma

Subjects

Automotive Engineering, Transportation, Management, Monitoring, Policy and Law, Civil and Structural Engineering

Published

2022

15. A novel distributed sensing method for support condition monitoring under concrete pavement

Author

Mengyuan Zeng, Sheng Zhong, Jianming Ling, Hongduo Zhao, and Difei Wu

Subjects

050210 logistics & transportation, Optical fiber, Computer science, 05 social sciences, 0211 other engineering and technologies, Pavement maintenance, 02 engineering and technology, law.invention, Reliability engineering, Mechanics of Materials, law, 021105 building & construction, 0502 economics and business, Support condition, Monitoring methods, Structural health monitoring, Civil and Structural Engineering

Abstract

Accurate monitoring of concrete pavement support condition is critical for pavement maintenance. This paper proposed a novel support condition monitoring method using distributed optical fiber sens...

Published

2020

16. Investigating the Effect of Prestress Force on Cross-Tensioned Concrete Pavement Vibration

Author

Hongduo Zhao, Difei Wu, Hui Chen, Mengyuan Zeng, and Jianming Ling

Subjects

Vibration, Materials science, business.industry, Mechanical Engineering, 021105 building & construction, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Structural engineering, business, 0201 civil engineering, Civil and Structural Engineering

Abstract

Prestress force loss is crucial to the structural performance of cross-tensioned concrete pavement (CTCP). Severe loss in prestress force will reduce the constricting-cracking capacity of the CTCP, resulting in damage with load and temperature applied. Vibration-based methods are commonly used in prestress force monitoring, but few relative studies are reported into CTCP and the relationship between prestress force and CTCP vibration is still unclear. The purpose of this paper is to investigate the effect of prestress force on CTCP vibration. The vibration characteristics of CTCP subjected to different prestress forces were studied through field testing and finite element (FE) analysis. Impulse load was applied as excitation at the anchorage zone and dynamic responses were measured in the time domain. A signal processing method was employed to obtain short-time power spectral from original vibration signals, which was utilized to extract vibration characteristics in time and frequency. As shown in both the field testing and the FE analysis, the prestress force has a more significant effect on frequency spectral distribution, rather than the dominant frequency. Integrated frequency is proved to be a reliable index for describing frequency spectral distribution and has a good correlation with prestress force, which suggests it can be used to reflect the change in prestress force. Overall, these findings indicate that vibration testing has potential in prestress force monitoring in CTCP, though the practicality of this method requires further demonstration.

Published

2020

17. Numerical analysis of hydroplaning behaviour by using a tire–water-film–runway model

Author

Yafeng Pang, Xingyi Zhu, Jian Yang, and Hongduo Zhao

Subjects

Field (physics), Fluid solid coupling, Mechanics of Materials, Aviation, business.industry, Numerical analysis, Environmental science, Runway, Stage (hydrology), business, Aquaplaning, Civil and Structural Engineering, Marine engineering

Abstract

Studying the hydroplaning behaviour is crucial for enhancing the safety of aviation during the landing stage. Due to the special nature of the aviation field, such as high aircraft velocity, wheel ...

Published

2020

18. Novel Assessment Method for Support Conditions of Concrete Pavement under Traffic Loads using Distributed Optical Sensing Technology

Author

Mengyuan Zeng, Hongduo Zhao, Difei Wu, Hui Chen, and Bian Zeying

Subjects

020303 mechanical engineering & transports, 0203 mechanical engineering, Optical sensing, Computer science, Mechanical Engineering, 021105 building & construction, Assessment methods, 0211 other engineering and technologies, 02 engineering and technology, Civil and Structural Engineering, Reliability engineering

Abstract

Loss of support is a common concrete pavement distress that may affect pavement performance directly. Previous studies have proved that vibration-based methods have the potential for detecting loss of support in a more efficient way but this is limited by loading conditions. This paper presents a further study concerning the effects of moving loads and proposes a novel method for assessing support conditions of concrete pavement under traffic loads using distributed optical vibration sensing technology. First, finite element analysis and laboratory tests were conducted to investigate the impact of loss of support on pavement vibration induced by moving loads with reference to the frequency spectrum. The impact of loading conditions, including loading position and speed, was also studied using the same methods. The results indicate that both loss of support and loading characteristics have a considerable effect on the distribution of the frequency spectrum. It is proved that weighted frequency can be utilized for assessment of support conditions under a specific loading condition. It is suggested the loading position needs to be close to the measurement point (distance < 0.3 m) to obtain stable and reliable data for assessment of support conditions. In addition, the loading speed should be adequately fast and steady (4 to 5 m/s) to ensure the significance of the effect of loss of support. A field test was conducted in an airport, and the novel assessment method was validated by comparing it with a conventional deflection-based method. The novel method proved to be reliable for implementation in practice.

Published

2020

19. Identification of Moving Load Characteristic on Pavement Using F-P Cavity Fiber Optical Technology

Author

Cai Zhao, Zeying Bian, Hongduo Zhao, Lukuan Ma, Mu Guo, Kedi Peng, and Erli Gao

Subjects

weigh-in-motion (WIM) system, traffic load identification, Fabry–Pérot (F-P) cavity fiber optical, Renewable Energy, Sustainability and the Environment, Geography, Planning and Development, Management, Monitoring, Policy and Law

Abstract

The weigh-in-motion (WIM) system is a necessary piece of equipment for an intelligent road. It can provide real-time vehicle weight and lateral distribution data on wheel load to effectively support pavement structure design and service life analysis for autonomous driving. This paper proposed an enhanced weigh-in-motion sensors system using Fabry–Pérot (F-P) cavity fiber optical technology. Laboratory testing was performed to evaluate the feasibility of the proposed system and field application was conducted as well. The laboratory results show that the traffic loads could be obtained by measuring the center wavelength changes in the embedded F-P Cavity tunable filter. The laboratory results also show that the vehicle load and the number of vehicle axles can be estimated based on the system transfer function between the dynamic loading and the wavelength variation. The field application indicates that the weighting accuracy of the proposed system could reach 94.46% for moving vehicles, and the vehicle passing speed is the potentially relevant factor. The proposed system also has the ability to estimate the number of vehicle axles and the loading position, and the precision could reach 97.1% and 300 mm, respectively.

Published

2022

20. Performance Assessment and Comparison of Two Piezoelectric Energy Harvesters Developed for Pavement Application: Case Study

Author

Chenchen Li, Shifu Liu, Hongduo Zhao, and Yu Tian

Subjects

energy harvesting, piezoelectric device, Environmental effects of industries and plants, electromechanical coupling performance, Renewable Energy, Sustainability and the Environment, Geography, Planning and Development, TJ807-830, Management, Monitoring, Policy and Law, TD194-195, mechanical performance, Renewable energy sources, road engineering, Environmental sciences, ddc:690, electrical performance, GE1-350

Abstract

Sustainability 14(2), 863 (2022). doi:10.3390/su14020863 special issue: "Special Issue "Traffic Infrastructure Sustainability in Autonomous Driving and Smart Pavement Environments" / Special Issue Editors: Dr. Young-Ji Byon, Guest Editor; Dr. Feng Chen, Guest Editor; Prof. Meng Guo, Guest Editor", Published by MDPI, Basel

Published

2022

21. Smart road: concept and architecture

Author

Jianming Ling and Hongduo Zhao

Published

2021

22. Monitoring of prestressing forces in cross-tensioned concrete pavements during construction and maintenance based on distributed optical fiber sensing

Author

Mengyuan Zeng, Hui Chen, Jianming Ling, Hongduo Zhao, and Difei Wu

Subjects

Control and Systems Engineering, Building and Construction, Civil and Structural Engineering

Published

2022

23. Assessment of concrete pavement support conditions using distributed optical vibration sensing fiber and a neural network

Author

Hongduo Zhao, Difei Wu, Jianming Ling, Mengyuan Zeng, and Yu Tian

Subjects

Artificial neural network, Vibration sensing, Computer science, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Building and Construction, Field tests, 0201 civil engineering, Wavelet packet decomposition, Vibration, Probabilistic neural network, 021105 building & construction, Electronic engineering, General Materials Science, Lower cost, Grading (engineering), Civil and Structural Engineering

Abstract

This paper presents a new method that uses distributed optical vibration sensing (DOVS) technology and a neural network, which can access the concrete pavement support condition with lower cost and higher efficiency. This method relies on the vibration properties of the concrete pavement slabs, which was captured by an embedded DOVS system and extracted using the wavelet packet transform. Based on the extracted properties, a grading method that using probabilistic neural network (PNN) to assess the support condition was proposed. Through field tests, the accuracy of this method can reach 92.8% for 2-grade assessment and 81.4% for 3-grade assessment, respectively.

Published

2019

24. Analysis of airfield composite pavement responses using full-scale accelerated pavement testing and finite element method

Author

Jianming Ling, Fulu Wei, Hongduo Zhao, Yu Tian, Bingye Han, and Zhi'ang Chen

Subjects

Materials science, Rut, business.industry, Composite number, 0211 other engineering and technologies, Full scale, 020101 civil engineering, 02 engineering and technology, Building and Construction, Overlay, Structural engineering, Finite element method, 0201 civil engineering, Compressive strength, Asphalt, 021105 building & construction, General Materials Science, business, Strain gauge, Civil and Structural Engineering

Abstract

This study focuses on the critical responses of airfield composite pavements that are composed of hot-mix asphalt (HMA) overlay and Portland cement concrete (PCC) pavement. Accelerated pavement testing (APT) and a finite element (FE) method were employed to investigate the effects of three influential factors: temperature, interface bonding, and load level. A full-scale test field was constructed for this study and instrumented with 20 strain gauges and 32 temperature sensors. A finite element model was developed based on the parameters derived from laboratory and field tests and the model was then validated through measurements. The results indicate that longitudinal strain is more critical than transverse strain in an HMA overlay when subjected to moving loads. Moreover, the results underscore that temperature significantly affects the responses of HMA overlays and that the relationship between temperature and pavement responses is sigmoidal. Furthermore, a good interface bonding is able to significantly reduce the critical strain in an HMA overlay and the interface bonding strength is very sensitive to the amount of tack coat. The positive strain near to the surface of HMA overlay is due to high compressive stress, which is different from the tensile strain used in fatigue testing.

Published

2019

25. Laboratory Investigation on the Interface Bonding between Portland Cement Concrete Pavement and Asphalt Overlay

Author

Bingye Han, Hongduo Zhao, Fulu Wei, and Jianfeng Cao

Subjects

Materials science, Article Subject, General Mathematics, Composite number, 0211 other engineering and technologies, General Engineering, 02 engineering and technology, Overlay, Engineering (General). Civil engineering (General), law.invention, Portland cement, law, Asphalt, 021105 building & construction, QA1-939, Shear stress, Coupling (piping), Direct shear test, TA1-2040, Composite material, Failure mode and effects analysis, Mathematics, 021101 geological & geomatics engineering

Abstract

The interface bonding between Portland cement concrete (PCC) pavement and hot-mix asphalt (HMA) overlay plays an important role in the performance of the composite pavement. This research conducted a series of comprehensive laboratory studies to investigate the influence factors of the interface bonding strength using a self-designed direct shear test apparatus that can simultaneously apply normal stress and shear stress on a specimen. Four kinds of commonly used tack coat materials were systematically tested and compared under various combinations of normal stress and temperature. Then, coupling effects of the normal stress and temperature on the interface bonding between PCC and HMA were analyzed. The test results show that temperature has a significant impact on the adhesion of the tack coat. Emulsified asphalt was considered the optimal tack coat material because of its simple construction method. In addition, it was found that a damaged interface could still provide considerable bonding strength. Normal stress generated by traffic loads was beneficial to the interface bonding strength, especially at lower temperatures. The temperature had a significant effect on interface bonding and played a leading role in the failure mode of interface bonding.

Published

2021

26. Critical Stress Analysis in Airfield Jointed Plain Concrete Pavements with Voids underneath Slabs

Author

Jiake Zhang, Hongduo Zhao, Jufei Zhao, and Lukuan Ma

Subjects

Critical stress, Air voids, Geotechnical engineering, Finite element method, Geology

Published

2020

27. Effects of temperature variations on the deflections of airfield jointed plain concrete pavements

Author

Jiake Zhang, Hongduo Zhao, and Lukuan Ma

Subjects

Materials science, lcsh:TA1001-1280, 0211 other engineering and technologies, 020101 civil engineering, Transportation, 02 engineering and technology, Management, Monitoring, Policy and Law, Critical value, 0201 civil engineering, Transverse plane, Temperature gradient, Deflection (engineering), 021105 building & construction, Automotive Engineering, Slab, Positive temperature, Geotechnical engineering, lcsh:Transportation engineering, Linear correlation, Civil and Structural Engineering

Abstract

This paper aims to study the influences of temperature variations on airfield jointed plain concrete pavement (JPCP) deflections. The maximum deflection at the transverse joint ( D 0 j ), the maximum deflection at the corner of a slab ( D 0 c ), and the deflection basin at the centre of a slab were considered. The in-situ deflection measurements at three civil airports were conducted over a 24-hour period and numerical simulations for JPCP at a civil airport were performed as well. The results indicate that the temperature change slightly affects the deflection basin at the centre of a slab unless the positive temperature gradient in the slab increases to exceed a certain critical value. But both D 0 j and D 0 c are significantly affected by temperature variations. The results of in-situ tests show that D 0 j (or D 0 c ) is almost stable from 1 pm and 5 pm in a day. At other times of one day, there is a strong negative liner correlation between D 0 j (or D 0 c ) and the pavement surface temperature during the heating period and the cooling period, respectively. The results of numerical simulations reveal that both D 0 j and D 0 c gradually increase with the increase of the average temperature. The results of numerical simulations also suggest that a critical negative/positive temperature gradient exists at the transverse joint while there is a critical positive temperature gradient at the slab corner. Besides, all the critical temperature gradients are seldom affected by the average temperature. When the temperature gradient exceeds the critical value, D 0 j , D 0 c and all values of the deflection basin have a strong positive linear correlation with the temperature gradient.

Published

2018

28. Estimating the remaining life of airfield flexible pavements considering environmental factors

Author

Jiake Zhang, Hongduo Zhao, and Lukuan Ma

Subjects

Moisture, 0211 other engineering and technologies, General Engineering, Modulus, Resilient modulus, 02 engineering and technology, Subgrade, Remaining life, Asphalt, 021105 building & construction, Frost, Environmental science, Geotechnical engineering, 021101 geological & geomatics engineering

Abstract

The mechanistic-empirical analysis approach assumes a fixed environmental condition in estimating the remaining life of airfield flexible pavements, which may introduce some errors with the real situation. This paper investigated the influences of moisture and frost on resilient modulus of subgrade soil and unbound materials, as well as the influences of temperature on modulus and Poisson’s ratio of asphalt mixture. A time-sharing damage accumulation method, which considered the environmental factors in pavement damage calculation, was provided in this research. Based on the method, this paper proposed a methodology to predict the remaining life of in-service airfield flexible pavements, and a case study was conducted using this methodology. The result shows that environmental factors significantly affect the damage calculation of airfield flexible pavements. Besides, it has been found from the case study that the methodology is applicable for estimating the remaining life of airfield flexible pav...

Published

2018

29. Synergistic performance of piezoelectric transducers and asphalt pavement

Author

Luyao Qin, Jianming Ling, and Hongduo Zhao

Subjects

Materials science, lcsh:TE1-450, business.industry, 020209 energy, Modulus, Stiffness, 02 engineering and technology, Structural engineering, 021001 nanoscience & nanotechnology, Durability, Piezoelectricity, Transducer, Mechanics of Materials, Deflection (engineering), Asphalt, 0202 electrical engineering, electronic engineering, information engineering, Shear stress, medicine, Composite material, medicine.symptom, 0210 nano-technology, business, lcsh:Highway engineering. Roads and pavements, Civil and Structural Engineering

Abstract

The deformation of piezoelectric transducer and asphalt pavement differs because of their different stiffness. As the piezoelectric transducer is embedded in asphalt pavement, the differential deformation may cause a non-uniform stress and degrade their performance. In this paper, the synergistic performance of piezoelectric transducer and asphalt pavement is studied through finite element analysis. Results show that the energy conversion efficiency of the transducers decreases with increasing burial depth and modulus of surface course. Under the vehicle loading, the piezoelectric transducer and asphalt pavement are easily separated by shear stress. For the asphalt pavement, the change in the stress of pavement structure and surface deflection is very small, which means that the differential deformation has no effect on fatigue cracking. Furthermore, an energy harvesting system composed of transducers array and asphalt plate is made and evaluated in a laboratory. Results show that the transducers within asphalt pavement have acceptable efficiency and high durability. Keywords: Synergistic performance, Piezoelectric transducer, Asphalt pavement, Energy harvesting, Cymbal, Differential deformation

Published

2018

30. A Vibration-Based Vehicle Classification System using Distributed Optical Sensing Technology

Author

Difei Wu, Hongduo Zhao, Mengyuan Zeng, and Sheng Zhong

Subjects

050210 logistics & transportation, Signal processing, Computer science, Mechanical Engineering, Acoustics, 05 social sciences, 0211 other engineering and technologies, 02 engineering and technology, Vibration, Axle, symbols.namesake, Fourier transform, Optical sensing, Vibration based, Frequency domain, 021105 building & construction, 0502 economics and business, symbols, Civil and Structural Engineering

Abstract

This paper presents a vibration-based vehicle classification system using distributed optical vibration sensing (DOVS) technology and describes a comprehensive classification method including signal processing and feature extraction. With low maintenance costs, this system can collect vehicle classification data in a larger scale. At first, it utilizes an embedded sensing fiber as a distributed sensor to collect traffic-induced vibration signals, and then extracts several features from the raw signals to estimate axle configurations and identify vehicle categories. At the same time, an empirical mode decomposition (EMD)-based method is applied to reconstruct signals for features extraction, and then several extraction algorithms are proposed to obtain the axle configuration, moving speed, and frequency-domain feature of each vehicle. When all features are extracted, a multi-step classifier is designed to categorize vehicles into different classes. In addition, to evaluate the classification performance of this system, a prototype system was installed on a relief road in Shanghai, China using precast concrete pavement technology. With an overall accuracy of 89%, the test results show a good performance of this classification system.

Published

2018

31. Support conditions assessment of concrete pavement slab using distributed optical fiber sensor

Author

Mengyuan Zeng, Jianming Ling, Hongduo Zhao, and Difei Wu

Subjects

Contact matrix, Materials science, Acoustics, 0211 other engineering and technologies, General Engineering, Transportation, 02 engineering and technology, 021001 nanoscience & nanotechnology, Compression (physics), Brillouin zone, Fiber optic sensor, 021105 building & construction, Slab, Time domain, 0210 nano-technology, Sensing system

Abstract

In this study, a Brillouin Optical Time Domain Analysis (BOTDA)-based compression sensing system is developed to assess the support conditions of concrete pavement slab. The system is implemented b...

Published

2018

32. Detection and localization of debonding beneath concrete pavement using transmissibility function analysis

Author

Yang Wang, Yuchuan Du, Difei Wu, Hongduo Zhao, and Mengyuan Zeng

Subjects

0209 industrial biotechnology, Signal processing, business.industry, Noise (signal processing), Computer science, Mechanical Engineering, Aerospace Engineering, 02 engineering and technology, Structural engineering, Accelerometer, 01 natural sciences, Finite element method, Transmissibility (vibration), Computer Science Applications, 020901 industrial engineering & automation, Control and Systems Engineering, Precast concrete, 0103 physical sciences, Signal Processing, Range (statistics), Node (circuits), business, 010301 acoustics, Civil and Structural Engineering

Abstract

This paper proposes a novel method to detect and localize debonding beneath the concrete pavement using transmissibility function (TF) analysis. The layout of the measurement node array, the signal processing approach, and the testing procedures are proposed. Two matrices of transmissibility damage indicator (TDI) are proposed to describe the distribution of debonding. This method is a response-only approach and can offer advantages in easy and low-cost implementation. The theoretical deduction, finite element analysis (FEA), and field tests are conducted to demonstrate and verify detection and localization performance. It is first observed that the arrangement of measurement nodes and the frequency range are crucial to TF analysis. TFs at higher frequencies range are more sensitive to the debonding but may result in higher errors. The density of the measurement node array and the noise’s effect are investigated in the FEA. Using a denser node array and maintaining a lower noise level helps localize the debonding more precisely. Field tests are conducted on a precast concrete pavement plate using a specially designed accelerometer array. The test results demonstrate the feasibility of the TF-based method for debonding detection and localization.

Published

2021

33. Investigation of the interface bonding between concrete slab and asphalt overlay

Author

Yi Zheng, Jianfeng Cao, and Hongduo Zhao

Subjects

Cement, 050210 logistics & transportation, Materials science, 05 social sciences, 0211 other engineering and technologies, 02 engineering and technology, Surface finish, Asphalt, 021105 building & construction, 0502 economics and business, Slab, Shear strength, Geotechnical engineering, Texture (crystalline), Direct shear test, Adhesive, Composite material, Civil and Structural Engineering

Abstract

Interface bonding between the cement slab and asphalt overlay is a significant point affecting mechanical behaviour and service life of the pavement. Many factors may influence the interfacial adhesive capacity, including asphalt mixture type, tack coat type and dosage, surface texture on layer below, temperature and moisture conditions. The aim of this study is to determine the most influential factors at the interlayer and evaluate their significant levels. An apparatus is designed to apply the direct shear test with normal load. Specimen is prepared by drilling cores from asphalt overlay over cement concrete pavement, which is constructed in laboratory. Six parameters with three values are examined by orthogonal test. Effects of these factors on interlayer performance are validated by boxplot. The test results conclude that surface texture on cement slab has the most significant influence on interlayer shear strength, and tack coat type, moisture and temperature come next. Rough surface texture like ti...

Published

2017

34. Self-healing efficiency of ferrite-filled asphalt mixture after microwave irradiation

Author

Xingyi Zhu, Sheng Zhong, Hongduo Zhao, Jun Zhu, and Yongsheng Cai

Subjects

Materials science, 0211 other engineering and technologies, Healing time, 02 engineering and technology, Building and Construction, 021001 nanoscience & nanotechnology, Asphalt, Self-healing, 021105 building & construction, Heating temperature, Microwave irradiation, Volume fraction, Ferrite (magnet), General Materials Science, Composite material, 0210 nano-technology, Microwave, Civil and Structural Engineering

Abstract

Asphalt-based composites have the ability to heal themselves. Under certain conditions, strength and stiffness modulus can be restored so that the fatigue life can be extended. However, without the aid of external influences (energy supply or material supplement), the self-healing ability of asphalt mixture is quite limited. In this paper, the efficiency of self-healing of asphalt mixture with Ni-Zn ferrite powders was analyzed based on the concept of microwave heating. The recovery rate of stiffness modulus and the fatigue life extension ratio were adopted to evaluate the self-healing efficiency of asphalt mixture. Different influence factors, such as heating temperature, healing time and damage level, were analyzed in this study. The analysis results proved that Ni-Zn ferrite powders can promote the self-healing ability of asphalt mixture significantly. It is found that when the asphalt mixture is filled with 80% ferrite powders (volume fraction of mineral powders), under the condition of healing for 3 h after heating to 55 °C by microwave, the fatigue life extension ratio of 50% damaged ferrite-filled asphalt mixture can reach 1.33.

Published

2017

35. Effects of surface texture deterioration and wet surface conditions on asphalt runway skid resistance

Author

Feng Chen, Alvaro Guarin, Xingyi Zhu, F.A. Gilabert, Hongduo Zhao, Yang Yang, and Denis Jelagin

Subjects

hydroplaning, Technology and Engineering, Materials science, pavement reconstruction, 02 engineering and technology, Surface finish, Aquaplaning, 0203 mechanical engineering, Natural rubber, Geotechnical engineering, Texture (crystalline), Mechanical Engineering, Finite element analysis, friction deterioration, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, pavement surface texture, 020303 mechanical engineering & transports, Skid (automobile), Mechanics of Materials, visual_art, Service life, visual_art.visual_art_medium, Runway, Slip ratio, 0210 nano-technology

Abstract

The friction force for aircraft landing is mainly provided by the texture of runway surfaces. The mechanism underlying friction force generation is the energy dissipation of tire rubber materials during random excitation induced by asperities. However, the runway surface texture is deteriorated by cyclic loading and environmental effects during the service life of a runway, leading to loss of braking force and extension of landing distance. Additionally, when an aircraft lands on a wet runway at a high velocity, the hydrodynamic force causes the tires to detach from the runway surface, which is risky and may lead to the loss of aircraft control and runway excursion. Worn-out surfaces along with wet conditions increase the risk of poor control during aircraft landing. Accordingly, this study investigated three types of asphalt runways (SMA-13, AC-13, and OGFC-13). Surface texture deterioration was simulated using a surface texture wear algorithm. Kinematic friction models were established based on the viscoelastic property of rubber materials, power spectrum density, and statistics of surface textures. A finite element model was developed by considering a real rough runway surface and different water film depths (3, 7, and 10 mm). A comparison of hydroplaning speed was conducted between numerical simulation and former experiments. The effects of different factors, such as velocity, wear ratio, runway type, water film depth, and slip ratio, on the skid resistance of the runway were analyzed.

Published

2021

36. Band gap structures for viscoelastic phononic crystals based on numerical and experimental investigation

Author

Sheng Zhong, Xingyi Zhu, and Hongduo Zhao

Subjects

Materials science, Acoustics and Ultrasonics, Condensed matter physics, Computer simulation, business.industry, Wave propagation, Band gap, 02 engineering and technology, 021001 nanoscience & nanotechnology, Viscoelasticity, 020303 mechanical engineering & transports, Quality (physics), Optics, 0203 mechanical engineering, Condensed Matter::Superconductivity, Volume fraction, 0210 nano-technology, Electronic band structure, business, Boundary element method

Abstract

Many materials used as phononic crystals (PCs) are viscoelastic one. It is believed that viscosity results in damping to attenuate wave propagation, which may help to tune the defect modes or band gaps of viscoelastic phononic crystals. To investigate above phenomenon, firstly, we have extended the application of boundary element method (BEM) to the study of viscoelastic phononic crystals with and without a point defect. A new developed BEM within the framework of Bloch theory can easily deal with viscoelastic phononic crystals with arbitrary shapes of the scatterers. Experimental methods have been put forward based on the self-made viscoelastic phononic crystals. Verified by the experimental results, systematic comprehensive parametric studies on the band structure of viscoelastic phononic crystals with varying factors (final–initial value ratio, relaxation time, volume fraction of scatterers, shapes of scatterers) have been discussed by the numerical simulation. To further address the possibility to change the defect modes, the band structure of viscoelastic phononic crystals with a point defect has been studied based on the numerical and experimental methods. From present research work, it can be found that by adjusting the two viscous parameters combined with considering the effect of volume fraction and shapes, a wider and lower initial forbidden frequency or lower and higher quality factor resonant frequency can be obtained.

Published

2016

37. Simple Empirical Temperature Gradient Prediction Model for Jointed Plain Concrete Pavements: Development and Validation

Author

Jianming Ling, Lukuan Ma, Chenchen Li, Yu Tian, and Hongduo Zhao

Subjects

Temperature gradient, business.industry, Simple (abstract algebra), Field data, Linear regression, Transportation, Development (differential geometry), Structural engineering, business, Geology, Civil and Structural Engineering

Abstract

The aim of this paper is to propose a simple empirical prediction model for temperature gradients within concrete slabs of jointed plain concrete pavements (JPCPs) based on data collected b...

Published

2020

38. Accelerated Pavement Testing for Rutting Evaluation of Hot-Mix Asphalt Overlay under High Tire Pressure

Author

Jianming Ling, Hui Chen, Yu Tian, Hongduo Zhao, Fulu Wei, and Bingye Han

Subjects

Materials science, Accelerated pavement testing, business.industry, Rut, Composite number, Transportation, Overlay, Tire pressure, Asphalt concrete, Asphalt pavement, Asphalt, Geotechnical engineering, business, Civil and Structural Engineering

Abstract

This study focused on the rutting characteristics of two typical hot-mix asphalt (HMA) overlays in airfield composite pavement under high tire pressure: asphalt concrete (AC) and stone mast...

Published

2020

39. Prototype Modeling of Pile-Type Piezoelectric Transducer for Harvesting Energy from Vehicle Load

Author

Xueqian Fang, Tao Yujie, Yanliang Niu, and Hongduo Zhao

Subjects

Materials science, 0205 materials engineering, 020502 materials, Acoustics, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, Pile, Piezoelectricity, Energy (signal processing)

Published

2018

40. Environmental Impacts of Different Maintenance and Rehabilitation Strategies for Asphalt Pavement

Author

Hongduo Zhao, Jianming Ling, and Bingye Han

Subjects

Rehabilitation, Asphalt pavement, medicine.medical_treatment, medicine, Forensic engineering, Environmental science

Published

2018

41. Test and Analysis of Bridge Transducers for Harvesting Energy from Asphalt Pavement

Author

Jianming Ling, Hongduo Zhao, and Luyao Qin

Subjects

Engineering, Energy harvesting, business.industry, Finite element analysis, lcsh:TA1001-1280, Modulus, Transportation, Structural engineering, Management, Monitoring, Policy and Law, Lead zirconate titanate, Piezoelectricity, Bridge transducer, chemistry.chemical_compound, Transducer, chemistry, Automotive Engineering, Shear stress, Asphalt pavement, Piezoelectric, lcsh:Transportation engineering, Arch, business, Contact area, Civil and Structural Engineering, Stress concentration

Abstract

Part of energies in asphalt pavement caused by vehicle can be converted into electric energy by piezoelectric transducer. A bridge-shaped transducer is selected to harvest energy because of its reasonable efficiency and moderate stiffness close to asphalt pavement. This paper is to compare the performance of Bridge transducers with trapezoidal, arc and arch structure through finite element analysis (FEA) and laboratory test. Results show that the arch Bridge has higher energy conversion efficiency and the trapezoidal Bridge has stronger ability to resist pressure. For arc and trapezoidal Bridge, the maximum tensile stress and shear stress are both in the inner corner of contact area between cap and PZT (lead zirconate titanate) disk. They were broken because of the cracking of PZT at the stress concentrations area. For arch Bridge, the maximum tensile stress increases with thickness of metal cap but decrease with modulus, and maximum shear stress decreases first and increases later with increasing thickness and modulus of metal cap. In laboratory test, its cracking area is shifted from edge to inner corner of contact area between cap and PZT disk with increasing thickness of metal cap. The electric potential generated by arch Bridge decreased with increasing thickness and modulus of metal cap. Under the load of 0.7 MPa, the electric potential is about 286 V for an arch Bridge transducer with 0.4mm thickness of stainless steel cap, and its storage electric energy is 0.6 mJ. The designed arch Bridge transducer is suggested as the optimum one for harvesting energy from asphalt pavement.

Published

2015

42. Special issue: Safer road infrastructure and operation management

Author

Feng Chen and Hongduo Zhao

Subjects

Engineering, business.industry, SAFER, Automotive Engineering, lcsh:TA1001-1280, Transportation, Management, Monitoring, Policy and Law, lcsh:Transportation engineering, business, Construction engineering, Civil and Structural Engineering

Published

2017

43. High-Efficiency Heating Characteristics of Ferrite-Filled Asphalt-Based Composites under Microwave Irradiation

Author

Hongduo Zhao, Xingyi Zhu, Sheng Zhong, and Huaqing Chen

Subjects

Materials science, business.industry, 0211 other engineering and technologies, 02 engineering and technology, Building and Construction, 021001 nanoscience & nanotechnology, Asphalt concrete, Mechanics of Materials, Asphalt, Self-healing, 021105 building & construction, Service life, Microwave irradiation, Ferrite (magnet), General Materials Science, Irradiation, Composite material, 0210 nano-technology, business, Microwave, Civil and Structural Engineering

Abstract

Asphalt concrete is a typical self-healing material, and its self-healing rate is influenced by the temperature. Since microwave irradiation is an efficient way of heating, its use could be...

Published

2017

44. Harvesting energy from asphalt pavement by piezoelectric generator

Author

Yanliang Niu, Hongduo Zhao, Tao Yujie, and Jianming Ling

Subjects

Stress (mechanics), Generator (circuit theory), Materials science, Transducer, business.industry, General Materials Science, Structural engineering, business, Energy harvesting, Potential energy, Piezoelectricity, Finite element method, Mechanical energy

Abstract

This paper presents the way to harvest mechanical energy from asphalt pavement by piezoelectric generator. Results show that the potential energy in asphalt pavement can be up to 150 kW/h per lane per kilometre. Part of the mechanical energy can be harvested by piezoelectric transducers. The performance of seven typical transducers is examined through finite element analysis. Results show that PZT piles and multilayer, cymbal and bridge can work in asphalt pavement environment. PZT piles and multilayer have higher energy converting rate. However, the total harvested energy is small if these transducers are embedded directly in pavement. A prototype pavement generator is developed using PZT piles to increase the harvested energy. The generator can harvest more than 50 kW/h energy from the pavement under heavy traffic. 8–16 PZT piles are recommended for one generator. Round shape is suggested for the PZT piles to reduce the concentration of stress. And multilayer structure is recommended for PZT piles to decrease the electric potential of generator. The generator can be extended as sensor in the asphalt pavement, which can be used to monitor the traffic, pavement stress and temperature.

Published

2014

45. The Smart Road: Practice and Concept

Author

Yu Tian, Hongduo Zhao, Huizhao Tu, and Lijun Sun

Subjects

050210 logistics & transportation, Environmental Engineering, General Computer Science, Computer science, 020209 energy, Materials Science (miscellaneous), General Chemical Engineering, 0502 economics and business, 05 social sciences, 0202 electrical engineering, electronic engineering, information engineering, General Engineering, Energy Engineering and Power Technology, 02 engineering and technology

Published

2018

46. A Vibration-Based Traffic Monitoring System Using Distributed Optical Sensing Technology

Author

Mengyuan Zeng, Difei Wu, Cai Juewei, Hongduo Zhao, and Hui Chen

Subjects

Signal processing, Optical fiber, Computer science, Mechanical Engineering, Optical engineering, Real-time computing, Wavelet transform, 02 engineering and technology, law.invention, Vibration, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, law, Position (vector), Frequency domain, General Materials Science, Energy (signal processing)

Abstract

Effective traffic management requires use of monitoring technologies to extract traffic parameters that describe the characteristics of vehicles. This article presents a vibration-based traffic monitoring system to detect traffic parameters comprehensively, including the three major desired characteristics of vehicles: position, speed, and category. Using distributed optical technology, this system can monitor traffic parameters on a large scale. Firstly, distributed optical fiber was embedded into pavement as a series of vibration sensors to collect pavement vibration information. Then, a signal processing method, based on wavelet transform and short-time energy, was applied to reconstruct vibration signals for vibration features extraction. Estimation methods of traffic parameters were proposed based on the vibration characteristics in time, space and frequency domain. To evaluate the performance of this traffic monitoring system, a prototype system was installed on a highway in Shanghai, China. This system shows good accuracy in position locating (± 14.639 cm), category classification (86.98 %), and speed estimation (± 3.046 km/h). Meanwhile, results indicate this system provides a better monitoring performance at high speed.

Published

2019

47. Wide-Area Dynamic Sensing Method of Water Film Thickness on Asphalt Runway

Author

Cai Juewei, Hongduo Zhao, Xingyi Zhu, and Cao Jianfeng

Subjects

Wide area, Skid (automobile), Mechanics of Materials, Asphalt, Intelligent decision making, Mechanical Engineering, Environmental science, General Materials Science, Runway, Precipitation, Temporal information, Rainfall simulation, Marine engineering

Abstract

Water film thickness is of great significance to the skid-resistant performance of an asphalt runway. Obtaining the precise information of water film thickness can help to assess the skid resistance with higher accuracy. This article proposes a wide-area dynamic sensing method of water film thickness on asphalt runway. The model, considering precipitation time-variability, runway geometry, and runway surface characteristics, is established to extract spatial temporal information of water film thickness dynamics on runway during intense rainfall. The model optimization is further conducted to deal with the problems of slope change, singularity issue, and time-spatial evolution of water film, which extends the single-point water film sensing to the large-area sensing. In order to evaluate the developed method, the calculations of water film thickness from the model are compared with the results obtained from a laboratory rainfall simulation experiment. The results show that the method has high accuracy in sensing the water film thickness and can realize a dynamic and whole-area acquisition of runway wet surface condition information. This method can provide data support for intelligent decision making of landing safety under rainfall conditions.

Published

2019

48. Wide-Area Dynamic Sensing Method of Water Film Thickness on Asphalt Runway.

Author

Juewei Cai, Hongduo Zhao, Xingyi Zhu, and Jianfeng Cao

Abstract

Water film thickness is of great significance to the skid-resistant performance of an asphalt runway. Obtaining the precise information of water film thickness can help to assess the skid resistance with higher accuracy. This article proposes a wide-area dynamic sensing method of water film thickness on asphalt runway. The model, considering precipitation time-variability, runway geometry, and runway surface characteristics, is established to extract spatial temporal information of water film thickness dynamics on runway during intense rainfall. The model optimization is further conducted to deal with the problems of slope change, singularity issue, and time-spatial evolution of water film, which extends the single-point water film sensing to the large-area sensing. In order to evaluate the developed method, the calculations of water film thickness from the model are compared with the results obtained from a laboratory rainfall simulation experiment. The results show that the method has high accuracy in sensing the water film thickness and can realize a dynamic and whole-area acquisition of runway wet surface condition information. This method can provide data support for intelligent decision making of landing safety under rainfall conditions. [ABSTRACT FROM AUTHOR]

Published

2020

49. A Vibration-Based Traffic Monitoring System Using Distributed Optical Sensing Technology.

Author

Mengyuan Zeng, Hongduo Zhao, Difei Wu, Hui Chen, and Juewei Cai

Abstract

Effective traffic management requires use of monitoring technologies to extract traffic parameters that describe the characteristics of vehicles. This article presents a vibration-based traffic monitoring system to detect traffic parameters comprehensively, including the three major desired characteristics of vehicles: position, speed, and category. Using distributed optical technology, this system can monitor traffic parameters on a large scale. Firstly, distributed optical fiber was embedded into pavement as a series of vibration sensors to collect pavement vibration information. Then, a signal processing method, based on wavelet transform and short-time energy, was applied to reconstruct vibration signals for vibration features extraction. Estimation methods of traffic parameters were proposed based on the vibration characteristics in time, space and frequency domain. To evaluate the performance of this traffic monitoring system, a prototype system was installed on a highway in Shanghai, China. This system shows good accuracy in position locating (± 14.639 cm), category classification (86.98%), and speed estimation (± 3.046 km/h). Meanwhile, results indicate this system provides a better monitoring performance at high speed. [ABSTRACT FROM AUTHOR]

Published

2020

50. A Review of Harvesting Green Energy from Road

Author

Hongduo Zhao, Pengcheng Fu, and Jiang Ming Ling

Subjects

Engineering, Thermoelectric generator, Thermoelectric cooling, business.industry, Photovoltaic system, General Engineering, Electric power, Electricity, business, Energy harvesting, Civil engineering, Thermal energy, Renewable energy

Abstract

This paper presents a review of harvesting green energy from road. There are three forms of green energy exist in road: light, thermal and mechanical energy. Photovoltaic technology, thermoelectric technology, directly heat transferring and piezoelectric technology are discussed in this paper, as well as the cases studied in Europe, USA, Japan, Israel and China. Solar panels installed along road are current available to harvest light energy from the roadside land. Alternatively, the solar panels can be installed on the road instead of pavement structures, such as the Solar RoadwayTM. This technology is rather conceptual at this moment, and the main challenge is to design and build durable materials and structures that can withstand traffic at a reasonable maintenance and replacement cost. Thermoelectric generators can potentially be embedded in pavements, and generate electric power from the temperature gradient existing in pavements. However, instrument capable of efficiently generate electricity from the relatively small temperature gradient in pavement is still under development. Directly heat transfer solution is to have fluid flow through pavement, and the fluid is heated (in summer) by the pavement. An extra benefit in addition to energy collection is that this method can reduce pavement temperature as well as the associated negative effects on pavement performance and the environment. However how the heated fluid can be utilized was not clear. Electricity can be generated by piezoelectric ceramic generators embedded in pavement, as a result of the compressive stress and deformation induced by moving vehicles. Trials have been reported in Israel and China, and it was estimated that one lane-mile of highway can potentially general electricity of 200 kW.

Published

2013