Dynamic Response of Airport Concrete Pavement to Impact Loading

Jing Cai; Louis Ngai Yuen Wong; Hua Wei Yan

doi:10.4028/www.scientific.net/AMR.594-597.1395

Paper Titles

Stress Characteristic Analysis of Repaving Asphalt Pavement Structure on Old Cement Road
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Analysis of Equivalent Static Method for Subway Station
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Experimental Analysis of Failure Modes and Pavement Strength Control Parameters to Existing Cement Concrete Pavement
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Poisson Log-Linear Regression Model for Rural Signalized Intersection
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Dynamic Response of Airport Concrete Pavement to Impact Loading
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The Study on Road Performance and Pavement Structure Analysis for the Base Layer Material Stabilized by SRX
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Experiment Data Analysis of Comparative Test Research on Expressway Asphalt and Asphalt Mixture
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High-Grade Highway Safety Evaluation Method Based on Grey Clustering
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Construction Technology of Airfield Pavement Gravelly Substructure under Saline Soil Condition
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 594-597Dynamic Response of Airport Concrete Pavement to...

Dynamic Response of Airport Concrete Pavement to Impact Loading

Abstract:

The pavement-subgrade interaction is an important issue in the concrete pavement design.The present study focuses on the analysis of the dynamic deflection and the velocity response of airport concrete pavements to impact loading. The pavement-subgrade interaction is simplified as a linear viscoelastic model, in which the subgrade is composed of two layers (a base layer and a soil layer). The subgrade’s synthetical modulus and damping coefficient are obtained by the method of weighed mean. Through the Fourier and the Laplace transform the solution of the equilibrium equation of the pavement-subgrade system is deduced and the dynamic deflection solution of the pavement-subgrade system is obtained. In this study, an impact aircraft landing load increasing proportional to the aircraft vertical landing acceleration is considered. A Matlab program is compiled based on the solution to assess the influence of various system parameters (slab thickness h, slab size, subgrade reaction modulus Ks and subgrade damping factor C0) on the dynamic deflections of the pavement slab. The influence of h and Ks on the dynamic velocity response of the slab is also discussed. The results show that changing the damping factor and the subgrade reaction modulus has only a small influence on the deflection of the slab and the deflection, while the amplitude of velocity response and the frequency of velocity responses all decrease with the increase of the slab thickness. If the pavement slab size is decreased, the deflection at the center of the slab will decrease. A nonlinear relationship can be established between h and the maximum deflection, while linear relationships exist between C0 and the maximum deflection, as well as Ks and the maximum deflection.

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Periodical:

Advanced Materials Research (Volumes 594-597)

Pages:

1395-1401

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.594-597.1395

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Online since:

November 2012

Authors:

Jing Cai*, Louis Ngai Yuen Wong, Hua Wei Yan

Keywords:

Concrete Pavement, Dynamic Deflection, Dynamic Design, Impact Load

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