NTL Record

Title A Predictive Approach for Long-Term Performance of Recycled Materials Using Accelerated Aging - Volume 2: Appendices
Record ID 74998
Personal Name
Creator
Eighmy, T. T.; Cook, R.; Coviello, A.; Spear, J. C. M.; Hover, K. C.
Personal Name
Contributor
Simon, Marcia
Corporate Creator United States. Department of Transportation. Federal Highway Administration. Office of Infrastructure Research and Development
Corporate
Contributor
Recycled Materials Resource Center
Publisher United States. Department of Transportation. Federal Highway Administration. Office of Infrastructure Research and Development
Publication Date 20010601
Language English
Abstract Use of recycled materials in a proposed highway application frequently requires the assessment of physical and environmental performance. Future behavior is often difficult to predict. As an alternative to field demonstrations, there is a need to develop strategies to predict long-term physical and environmental performance. Accelerated aging is one means of exploring the long-term physical and environmental performance of recycled materials in a highway. Coal fly ash (CFA) use in portland cement concrete (PCC) was selected as a model system to develop an accelerated aging approach. Three types of accelerated aging were chosen for this project: Arrhenius aging (AA), cyclic loading (Cl), and freeze-thaw exposure (FT). This approach, incorporated in an experimental design, allowed a systematic. exploration of the separate effects and combined interactions of both developmental and degradative accelerated aging variables. A slab from U.S. Route 20 in northwest Iowa was used as a both the basis for the concrete mixes and as a field verification site. The aging protocol impacted both physical and chemical properties of the prism monoliths. Generally speaking, the main effects were more important than the interactive effects, which was unexpected. It took about 9 months of elapsed time to age specimens to an equivalent age of up to 4 years. The equivalent ages matched well with the time frame seen in the field in Iowa for the onset of early distress and also matched well the chronological age of the field pavement. AA significantly reduced the compressive strength of the concrete, possibly indicating the onset of a deleterious reaction in the mix. Cl affected the microcracking in the concrete. All aging variables affected the fine pore structure of the concrete. Cl affected the Ca diffusional leaching from the monoliths. logically, there appears to be a linkage between strength loss, microcracking, and leaching behavior of a major matrix constituent in the concrete (notably Cal. Most response variables from the aged laboratory prisms and the field samples were similar, suggesting that the method did a reasonable job of producing a laboratory pavement of similar age and distress to the field pavement. Certain field aging phenomena (microcracking from unknown sources, road salting, and carbonation) could not be recreated in the laboratory specimens.
Public Note Agreement Officer's Technical Representative (AOTR): Marcia Simon (HRDI-12)
Rosap ID dot:50238
Rosap URL https://rosap.ntl.bts.gov/view/dot/50238
TRT Terms Recycled materials; Material aging; Calculation; Life cycle analysis; Cyclic strength; Cyclic tests; Freeze thaw tests; Fly ash; Portland cement concrete; Physical properties; Geochemistry; Microcracking; Leaching
General Subjects recycled materials; accelerated aging; Arrhenius aging; cyclical loading; freeze-thaw distress; coal fly ash; portland cement concrete; physical properties; leaching; geochemical modeling
Geographical
Coverage
United States
TRIS Online
Accession No
815739
Contract Number DTFH61-97-X-00021
Report Number FHWA-RD-01-023
Resource type Tech Report
URL https://ntlrepository.blob.core.windows.net/lib/74000/74900/74998/FHWA-RD-01-023.pdf
Format PDF
Database NTL Digital Repository