The Federal Highway Administration (FHWA) conducted full-scale accelerated pavement testing to evaluate the performance of unmodified and polymer modified asphalt binders and to recommend improved specification tests over existing SUperiorPERforming Asphalt PAVEment (SuperpaveĀ®) binder performance grading methodologies.
Candidate replacement tests were evaluated via their ability to discern fatigue cracking resistance and rutting. Two fatigue cracking specification tests were identified as more capable in capturing performance than others: binder yield energy and critical tip opening displacement. Two rutting specification tests that quantify irrecoverable deformations exhibited the best strength to capture rutting: multiple stress creep and recovery and oscillatory-based nonrecoverable stiffness.
Based on the full-scale performance and laboratory tests, crumb rubber modified asphalt (Arizona wet process) was shown to significantly slow or stop the growth of fatigue cracks in a composite asphalt pavement structure. A hybrid technique to modify asphalt with a combination of crumb rubber and conventional polymers (terminally blended) exhibited good fatigue cracking resistance relative to the control binder. Also, a simple addition of polyester fibers to asphalt mix was shown to have high resistance to fatigue cracking without the use of polymer modification.
The research study also quantified the capabilities of the National Cooperative Highway Research Programās mechanistic-empirical pavement design and analysis methodologies to predict rutting and fatigue cracking of modified asphalts that were not captured in the calibration data from the Long-Term Pavement Performance program. Falling weight deflectometer, multidepth deflectometer, and strain gauge instrumentation were used to measure pavement response.
The results illustrated that the nationally calibrated mechanistic-empirical performance models could differentiate between structural asphalt thickness but had difficulty differentiating modified from unmodified asphalt binder performance. Nonetheless, the mechanistic-empirical performance ranking and predictions were enhanced and improved using mixture-specific performance tests currently being implemented using the asphalt mixture performance tester.
Authors: Nelson Gibson, Xicheng Qi, Aroon Shenoy, Ghazi Al-Khateeb, M. Emin Kutay, Adrian Andriescu, Kevin Stuart, Jack Youtcheff, and Thomas Harman
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