Publication Detail

Warm-Mix Asphalt Study: Summary Report on Rubberized Warm-Mix Asphalt Research

UCD-ITS-RR-13-34

Research Report

UC Pavement Research Center

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Suggested Citation:
Jones, David, Frank Farshidi, John T. Harvey (2013) Warm-Mix Asphalt Study: Summary Report on Rubberized Warm-Mix Asphalt Research. Institute of Transportation Studies, University of California, Davis, Research Report UCD-ITS-RR-13-34

Warm-mix asphalt (WMA) is a relatively new technology. It was developed in response to needs for reduced energy consumption and stack emissions during the production of asphalt concrete, long hauls, lower placement temperatures, improved workability, and better working conditions for plant and paving crews. Studies in the United States and Europe indicate that significant reductions in production and placement temperatures, and, potentially, in related emissions are possible. However, concerns exist about how these lower production and placement temperatures could influence asphalt binder aging and, consequently, short- and long-term performance, specifically rutting. The overall objective of the warm-mix asphalt study was to determine whether the use of technologies that reduce the production and construction temperatures of asphalt concrete mixes influences performance of the mix. The objective of this part of the study was to identify limitations and benefits of using warm-mix asphalt technologies in rubberized asphalt mixes.
The testing completed in this phase of the warm-mix asphalt study provided no results to suggest that warm-mix technologies should not be used in rubberized mixes in California, provided that standard specified mix design, construction, and performance limits for hot-mix asphalt are met. The use of warm-mix asphalt technologies in rubberized asphalt mixes has clear benefits when compared to hot mixes. These include significant reductions in, or even elimination of, smoke and odors, lower emissions, improved workability, better working conditions, and better performance on projects with long hauls or where mixes are placed under cool conditions. The slightly higher costs of using warm-mix technologies are outweighed by these benefits.
Based on the findings of this study, the use of warm-mix asphalt technologies in rubberized asphalt mixes is encouraged, especially on projects in urban areas and on those with long hauls and/or where mixes are placed under cool conditions. Given that warm-mix asphalt may be produced at significantly lower temperatures than hot-mix asphalt (with associated lower aggregate heating temperatures), moisture sensitivity, especially on water-based warm-mix asphalt technologies, should be closely monitored in mix-design and quality control/quality assurance testing.
Keywords: Warm-mix asphalt; rubberized hot-mix asphalt; rubberized warm-mix asphalt; asphalt emissions
UC Pavement Research Center document number UCPRC-SR-2013-03