01477036

Component

https://doi.org/10.3141/2335-10

http://scholar.google.com...rsen&publication_year=2013

Reclaimed asphalt pavement (RAP) is a byproduct of roadway resurfacing. A limited amount of RAP can be recycled into new hot-mix asphalt; the rest is stockpiled. Some states allow the use of RAP–aggregate blends as base course material. Because of RAP’s low strength and susceptibility to creep deformation, the Florida Department of Transportation (DOT) excludes RAP from being used as pavement base course for high-traffic areas. The research objective was to determine whether the strength characteristics of RAP could be improved through compaction and thereby make its base suitable in high-traffic areas. Modified Proctor, vibratory, and gyratory compaction data were compared. Four RAP sources were used. Specimens compacted by the three methods were tested with the limerock bearing ratio (LBR), unconfined compressive strength, and indirect split tensile strength. LBR is Florida’s variation of the California bearing ratio. Specimens were compacted to either a density or a compaction energy level. Vibratory compaction produced the lowest densities and strengths. Modified Proctor produced higher densities and strengths than vibratory, but the LBR strengths for all RAP types were consistently below Florida DOT standards. Gyratory compaction produced the highest densities and strengths. Gyratory RAP specimens were two to four times as strong as modified Proctor specimens at the same density. The compaction method did not have as significant an effect on creep, although gyratory-compacted samples produced less creep than modified Proctor–compacted samples.

01490600

13-1220

English

pp 89–98

2013

Transportation Research Record: Journal of the Transportation Research Board

9780309263320

Print

Figures (13) ; References (9)

Base course (Pavements); Compaction; Creep properties; Laboratory studies; Materials tests; Reclaimed asphalt pavements; Strength of materials

Florida Department of Transportation

Geotechnology; Highways; Materials; Pavements; I22: Design of Pavements, Railways and Guideways; I42: Soil Mechanics

PRP, TRIS, TRB, ATRI

Feb 5 2013 12:20PM

• Analytical and Laser Scanning Techniques to Determine Shape Properties of Aggregates
• Assessing Soil Stiffness of Stabilized Pavement Foundations
• Assessment of Scour on Bridge Foundations by Means of In Situ Erosion Evaluation Probe
• Blast Furnace Slag as Sustainable Material in Concrete Pavements
• Durability Assessment of Coarse Aggregates for Hot-Mix Asphalt in Maine
• Evaluation of Aggregate Imaging Techniques for Quantification of Morphological Characteristics
• Evaluation of Aggregate Size and Shape by Means of Segmentation Techniques and Aggregate Image Processing Algorithms
• Guidelines for Selection and Use of Coarse Recycled-Concrete Aggregates in Structural Concrete
• Improving Properties of Reclaimed Asphalt Pavement for Roadway Base Applications Through Blending and Chemical Stabilization
• Measuring Shear Wave Velocity in Laboratory to Link Small- and Large-Strain Behavior of Soils
• Microstructural Analysis for Mechanical Behavior of Granular Waste Materials
• Moisture-Sensitive and Stress-Dependent Behavior of Unbound Pavement Materials from In Situ Falling Weight Deflectometer Tests