George C. White Phone: (206) 685-7198 Email: gcw@u.washington.edu Joe P. Mahoney

This paper is used to demonstrate that it is feasible, realistic, and practical to develop and deploy, on a local or national scale, an online database to monitor hot mix asphalt (HMA) projects throughout their life cycle. Such a tool allows for the real-time acquisition and monitoring of mix design, field construction, and performance data, as well as archival of such data. Monitoring includes browsing, searching and analyzing data ranging from mix design and quality assurance/quality control (QA/QC) field data to performance measures such as roughness, cracking, and rutting. In particular, this paper demonstrates early implementation via Washington State’s Superpave project data. The database includes quantitative design and construction data, field instrument readings, infrared and video images, and performance information. Analysis and search capabilities are provided, including a map-based front-end to support spatial searches

and location-based data entry. It is currently available online at http://hotmix.ce.washington.edu/.

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Blue Earth County CSAH 20 – An Engineered Cold In-Place Recycling Project

Cold In-place Recycling (CIR) has been effective at rehabilitating aged pavements, but has lacked well-defined engineering parameters, and success has been inconsistent. To rehabilitate a County State Aid Highway in Blue Earth County, Minnesota, both conventional CIR and a new engineered process were used. The new process includes selection guidelines, a sampling protocol, a new mix design protocol including performance testing of laboratory prepared samples, quality control and quality assurance plan, and a new chemistry asphalt emulsion designed for quicker early strength, higher residual binder content and longer durability. The performance testing includes a new raveling test, thermal cracking testing, strength tests, and moisture susceptibility testing. The design included laboratory crushing the reclaimed asphalt concrete into three gradations. Mix designs were done on each of the gradations, so that when the actual gradation was determined in the field, the correct job mix formula could be selected. The new process CIR samples exhibited superior performance on raveling, thermal cracking and moisture susceptibility testing. Field stiffness testing showed quicker early strength, enabling quicker traffic return. Falling weight deflectometer testing showed higher moduli for the new CIR. While initial costs are about 10 percent higher, the higher binder content and reliability of the engineered process are expected to give lower overall life cycle costs. The costs were significantly lower than new Superpave mix. The project also evaluates several surface treatments. The project will continue to be monitored with time to determine the long-term performance and relative cost benefits.

It has been found that coarse-graded hot-mix asphalt mixtures designed under Superpave mixture design criteria may be permeable, and under certain conditions at or near full saturation. A study of a typical coarse-graded Superpave pavement subject to moving loads and saturated conditions was undertaken. Using a coupled finite element analysis based on the theory of mixtures, the influence of permeability, and rate of loading on a saturated flexible pavements subject to dynamic loads was performed. The theory of mixtures provides a link between the void structure (microstructure) of materials and a continuum description that is suitable for finite element formulations. The hot-mix asphalt is treated as a two-phase material, consisting of a solid skeleton and voids, which can be either dry or liquid filled. The results from this study show that significant pore pressures can occur in coarse-graded Superpave mixtures. In addition, the magnitude and distribution of pore pressures were a function of permeability and rate of loading. It is proposed that further study of asphalt skeleton stresses, stripping and layer de-bonding be undertaken.