01025979

Component

https://doi.org/10.3141/1970-17

http://scholar.google.com...iams&publication_year=2006

There has been a continuous evolutionary process in hot-mix asphalt (HMA) pavement design. In the beginning it was primarily based on past experience. Through research, empirical methods were developed on the basis of the materials’ response to specific loading in the AASHO Road Test. Today pavement design has progressed to a mechanistic– empirical method. This methodology takes into account the mechanical properties of the individual layers and uses empirical relationships to relate material properties to performance. The mechanical tests that are used as part of the current methodology include dynamic modulus and flow number, which have been shown to correlate with field pavement performance. The use of the dynamic modulus test and its impact on pavement design with the current design guide (2002) and its associated software are examined here. The three pavement structures that are examined were derived from the 1972 AASHTO design guide approach and were constructed in Wisconsin during the 2004 construction season. Through iterative changes in the HMA layer thickness, the major distresses of permanent deformation and fatigue were examined. Included in the examination were changes in air voids and asphalt binder content over ranges that were believed to be typical of HMA production and paving. All three pavements were predicted to perform well in terms of permanent deformation for the as-designed layer thicknesses. The 2002 design guide software, however, indicates that two of the three pavements considered may be prone to fatigue cracking, specifically at higher air void contents (+7.0%).

01038330

English

pp 143-150

2006

Transportation Research Record: Journal of the Transportation Research Board

030909979X

Print

Figures (3) ; References (12) ; Tables (4)

Air voids; Asphalt pavements; Binder content; Deformation; Dynamic modulus of elasticity; Fatigue (Mechanics); Hot mix asphalt; Pavement design; Rutting; Software

AASHTO Design Guide; Mechanistic-Empirical Pavement Design Guide

Design; Highways; Materials; Pavements; I22: Design of Pavements, Railways and Guideways; I31: Bituminous Binders and Materials

PRP, TRIS, TRB, ATRI

Mar 3 2006 10:45AM

• Comparing Resilient Modulus and Dynamic Modulus of Hot-Mix Asphalt as Material Properties for Flexible Pavement Design
• Computational Model to Predict Fatigue Damage Behavior of Asphalt Mixtures Under Cyclic Loading
• Determination of Asphalt Concrete Complex Modulus with Impact Resonance Test
• Dissipated Energy Approach to Study Hot-Mix Asphalt Healing in Fatigue
• Establishment of Precision of Dynamic Angle Validation Kit with Hot-Mix Simulator for Superpave Gyratory Compactors
• Evaluation of Effect of Heat-Adhesive Emulsions for Tack Coats with Shear Test: From the Road Research Laboratory of Barcelona
• Evaluation of Hamburg Wheel-Tracking Device Test with Laboratory and Field Performance Data (With Discussion and Closure)
• Evaluation of Healing Property of Asphalt Mixtures
• Evaluation of Testing Protocols for Dynamic Modulus of Hot-Mix Asphalt
• Investigating Pavement Cracking: Evolutionary Modular Neural Network Approach
• Limits on Adhesive Bond Energy for Improved Resistance of Hot-Mix Asphalt to Moisture Damage
• Long-Term Effectiveness of Antistripping Additives: Laboratory Evaluation
• Measurements of Moisture Suction and Diffusion Coefficient in Hot-Mix Asphalt and Their Relationships to Moisture Damage
• Mechanical Mixture Simulation Devices for Determining and Calibrating Internal Angle of Gyration in Superpave Gyratory Compactor
• Micromechanical Analyses for Measurement and Prediction of Hot-Mix Asphalt Fracture Energy
• Micromechanical Modeling Approach to Predict Compressive Dynamic Moduli of Asphalt Mixtures Using the Distinct Element Method
• New Laboratory Equipment for Study of Reflective Cracking in Asphalt Overlays
• Observation of Crack Propagation in Asphalt Mixtures Using Acoustic Emission
• Permanent Deformation Analysis of Hot-Mix Asphalt Mixtures Using Simple Performance Tests and 2002 Mechanistic-Empirical Pavement Design Software
• Simple Method for Predicting Laboratory and Field Permeability of Hot-Mix Asphalt
• Transitioning from Texas Gyratory Compactor to Superpave Gyratory Compactor
• Uniaxial Penetration Testing for Shear Resistance of Hot-Mix Asphalt Mixtures