01044209

Component

https://doi.org/10.3141/1998-02

http://scholar.google.com...ahia&publication_year=2007

Most tests used to evaluate moisture damage require compacted asphalt mixtures. The tests generally simulate field material and conditions and provide a performance-related parameter of moisture effects. In mixtures, however, variable asphalt–aggregate–air void structure contributes to the difficulty of isolating the fundamental rheological properties of an asphalt–aggregate bond. To avoid the complications and obtain the properties of the asphalt–aggregate interface, a new experimental design was developed in this study. This test features a dynamic shear rheometer (DSR) as an improved tool for evaluating interface properties. One key feature of the experimental design is the use of rock disks to simulate an asphalt–aggregate interface. The simulated interface is easily wet-conditioned in a water cup installed on the DSR. From various testing protocols, a stress sweep test that defines a linear viscoelastic (LVE) region is adopted to evaluate the interaction and moisture effects of selected specimens. A viscoelastic characteristic produced from stress sweep tests is recommended as the fundamental property of the interaction and can be used to evaluate moisture effects onto the rheological behavior. One of the critical findings is that the LVE complex modulus, G*, measured at relatively small strains or stresses cannot evaluate the moisture effects on the bond of the asphalt–aggregate interface. The LVE G* measured at high shear stresses are instead much more effective at evaluating such moisture effects. Therefore, the results indicate that the role of moisture damage in pavement problems such as rutting or fatigue needs to be evaluated at design stresses covering a nonlinear viscoelastic range. This study focuses on understanding more the basic characteristics of asphalt–aggregate interface than the bulk properties of mixtures.

01082316

English

pp 10-17

2007

Transportation Research Record: Journal of the Transportation Research Board

9780309104241

Print

Figures; Photos; References (16) ; Tables (1)

Aggregates; Asphalt mixtures; Moisture damage; Rheological properties; Rheology; Rheometers; Rutting; Shear modulus; Stresses; Viscoelasticity

Asphalt-aggregate interface; Complex modulus

Geotechnology; Highways; Materials; I31: Bituminous Binders and Materials

TRIS, TRB, ATRI

Feb 8 2007 6:24PM

• Comparative Laboratory Study of Sasobit and Aspha-Min Additives in Warm-Mix Asphalt
• Comparison of Polyphosphoric Acid–Modified Asphalt Binders with Straight and Polymer-Modified Materials
• Comparison of Simple Performance Test |E*| of Accelerated Loading Facility Mixtures and Prediction |E*|: Use of NCHRP 1-37A and Witczak’s New Equations
• Effect of Aggregate Degradation on Volumetric Properties of Georgia’s Hot-Mix Asphalt
• Effect of Calcareous Fillers on Bituminous Mix Aging
• Effect of Modification Processes on Bond Energy of Asphalt Binders
• Evaluation of Heated Reclaimed Asphalt Pavement Material and Wax-Modified Asphalt for Use in Recycled Hot-Mix Asphalt
• Field Performance of Warm-Mix Asphalt at National Center for Asphalt Technology Test Track
• Impact of Lime and Liquid Antistrip Agents on Properties of Idaho Hot-Mix Asphalt Mixture
• Investigation of Properties of Plant-Produced Reclaimed Asphalt Pavement Mixtures
• Investigation of Superpave Fine Aggregate Angularity Criterion for Asphalt Concrete
• Laboratory Investigations of Mechanical Performance of Foamed Bitumen Mixes That Use Half-Warm Aggregates
• Loss of Polymer-Modified Binder Durability with Oxidative Aging: Base Binder Stiffening Versus Polymer Degradation
• Moisture Sensitivity of Modified Asphalt Binders: Factors Influencing Bond Strength
• Role of Viscosity in Dynamic Creep Tests in Conventional, Oxidized, and Polymer-Modified Asphalts
• Thermal Sensitivity and Fatigue Life of Gap-Graded Asphalt Mixes Incorporating Crumb Rubber from Tire Waste