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| Study on Morphological Parameters of Hysteretic Curve of Dynamic Resilient Modulus |
| LIU Jing-yu1, YAN Yan-wu2, LIU Zhao-hui1, HUANG You1 |
1. School of Traffic and Transportation Engineering, Changsha University of Science and Technology, Changsha Hunan 410004, China;
2. China Railway Siyuan Survey and Design Group CO., LTD, Wuhan Hubei, 430063, China |
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Abstract The hysteresis curve of dynamic resilient modulus (DRM) is the load and deformation curve of asphalt mixture under dynamic loading, it can reflect the evolution rule of internal stress-train state with load and temperature. Based on viscoelastic theory, 3 morphological parameters could be determined:slope k of major axis, eccentricity e of ellipse, and area S of HC, which characterizes DRM, viscosity and energy dissipation capacity of asphalt mixture respectively. Thus the DRM test under various temperatures and loads are carried out. The result shows that there is a significant difference in the morphological parameters of SBS and asphalt mixture No.70 with the increase of temperature, and a inflection point exists at 15~20℃ in both hysteresis curves, the values of k and S change regularly but e keeps unchanged as load level increases. It indicates that (1) asphalt quality has more influence on the property than grade, and the viscosity is unrelated to load size; (2) between 15~20℃, the mechanical properties of asphalt mixture vary greatly, and their sensitivity to temperature are higher; (3) different values of morphological parameters of HC reflect the performance difference of asphalt mixture, and 3 morphological parameters could be used to evaluate the basic mechanical performance of asphalt mixture include viscosity, fatigue durability, etc. Finally, based on the changing rule of test curves, the stress dependence model of resilience modulus which reflects the response behaviors of asphalt mixture under various stress level conditions is established, and the prediction results are close to the real state. The variable load cumulative dissipation energy prediction equation is derived based on the Miner linear damage criterion, and the fatigue equation based on the theory of energy dissipation is established. The morphological parameters S obtained by the dynamic modulus test can be used to predict the fatigue performance of asphalt mixture.
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Received: 03 March 2020
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| Fund:Supported by the National Nature Science Foundation of China (Nos. 51678078,52008044) |
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Corresponding Authors:
LIU Jing-yu
E-mail: 365350073@qq.com
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2020, Vol. 14 
