01124383

Component

https://doi.org/10.3141/2127-07

http://scholar.google.com...llen&publication_year=2009

This study presents a simple method to define the representative volume elements (RVEs) of asphalt concrete mixtures without damage. Three currently used asphalt concrete mixtures (two dense-graded Superpave® mixtures with different nominal maximum aggregate sizes of 9.5 and 12.5 mm and one stone matrix asphalt mixture with a nominal maximum aggregate size of 19.0 mm) were selected and evaluated. To address the significant heterogeneity of asphalt concrete mixtures properly in defining RVEs, several geometrical factors, such as area fraction, gradation, orientation, and the distribution of aggregate particles in asphalt concrete mixtures, were all considered together by using two-dimensional images of actual asphalt concrete inner structures produced by digital-image processing. Geometrically defined RVEs were then supported by finite element simulations to check whether effective nondamage material properties obtained from the RVEs, such as the linear viscoelastic dynamic modulus, were representative of the corresponding bulk asphalt concrete mixture. Analysis results indicated that typical dense-graded Superpave asphalt concrete mixtures can be characterized by their effective nondamage properties with an approximate RVE size of 50 mm. However, the properties of stone matrix asphalt mixtures, which contain larger aggregates, should be measured on a larger scale for improved accuracy. Findings from this study were generally consistent with results of other studies performed on the basis of extensive laboratory tests, which implies that the simple geometrical–numerical method here can be a potentially efficient approach to define the RVEs of asphalt mixtures with much less time and effort.

01147872

09-1521

English

pp 52-59

2009

Transportation Research Record: Journal of the Transportation Research Board

9780309142687

Print

Figures (10) ; References (19) ; Tables (3)

Aggregate gradation; Asphalt concrete; Finite element method; Image processing; Microstructure; Numerical analysis; Stone matrix asphalt; Superpave

Aggregate shape; Nominal maximum aggregate size

Highways; Materials; I31: Bituminous Binders and Materials

TRIS, TRB, ATRI

Jan 30 2009 5:45PM

• Application of Artificial Neural Networks for Estimating Dynamic Modulus of Asphalt Concrete
• Application of Generalized J-Integral to Crack Propagation Modeling of Asphalt Concrete Under Repeated Loading
• Comparison of Low-Temperature Field Performance and Laboratory Testing of 10 Test Sections in the Midwestern United States
• Effective Temperature for Analysis of Permanent Deformation and Fatigue Distress on Asphalt Mixtures
• Evaluation and Application of Long-Lasting Asphalt Mixture
• Evaluation of Aspects of E* Test Using Hot-Mix Asphalt Specimens with Varying Void Contents
• Evaluation of Embedded Discontinuity Method for Finite Element Analysis of Cracking of Hot-Mix Asphalt Concrete
• Evaluation of Fatigue Models of Hot-Mix Asphalt Through Laboratory Testing
• Field and Laboratory Evaluation of Fracture Resistance of Illinois Hot-Mix Asphalt Overlay Mixtures
• Forensic Investigation and Validation of Energy Ratio Concept
• Identification of Parameters Related to Moisture Conditioning That Cause Variability in Modified Lottman Test
• Interface Bonding Between Hot-Mix Asphalt and Various Portland Cement Concrete Surfaces: Assessment of Accelerated Pavement Testing and Measurement of Interface Strain
• Long-Term Monitoring of Noise and Frictional Properties of Three Pavements: Dense-Graded Asphalt, Stone Matrix Asphalt, and Porous Friction Course
• Low Design Temperatures of Asphalt Pavements in Dry–Freeze Regions: Predicting by Means of Solar Radiation, Transient Heat Transfer, and Finite Element Method
• Micromechanical Modeling of Hot-Mix Asphalt Mixtures by Imaging and Discrete Element Methods
• Precision of AASHTO TP62-07 for Use in Mechanistic-Empirical Pavement Design Guide for Flexible Pavements
• Refinement of Flow Number as Determined by Asphalt Mixture Performance Tester: Use in Routine Quality Control–Quality Assurance Practice
• Using Dynamic Modulus Test to Evaluate Moisture Susceptibility of Asphalt Mixtures
• Utilizing Small Samples to Predict Fatigue Lives of Field Cores: Newly Developed Formulation Based on Viscoelastic Continuum Damage Theory