01152233

Component

https://doi.org/10.3141/2170-05

http://scholar.google.com...pata&publication_year=2010

The present study deals with the revision of the current model in the "Mechanistic–Empirical Pavement Design Guide" (MEPDG) used to predict the environmental factor for unfrozen unbound materials (F sub U), which is used to adjust the resilient response of soils resulting from seasonal changes. A large database with data from the existing literature and studies at Arizona State University was developed to evaluate the model. The results suggest that the environmental factor is underestimated for fine-grained materials with high plasticity under dry (arid) conditions. However, insufficient data were available to enhance the F sub U models for wetter conditions. Three fundamental factors that may have impacts on the F sub U values were evaluated in this study: stress state, compaction energy (soil density), and soil type. The stress state was found to have little to no impact on the predictions of F sub U. But density changes and soil type were found to be important. The potential for soil index properties to be predictive variables was assessed. Models dependent on enhanced moisture content accounting for the effect of soil type are proposed for nonplastic and plastic materials. The range of predicted F sub U values is in close agreement with the actual measured F sub U values found from laboratory studies. It is recommended that the new models be adopted in the revision of the MEPDG model for the drier conditions described in this report and that research be conducted to enhance the F sub U approach in the current MEPDG for wetter conditions brought on for a variety of reasons (e.g., groundwater table change, increased rainfall, and frost effects).

01320946

10-2438

English

pp 36-44

2010

Transportation Research Record: Journal of the Transportation Research Board

9780309160391

Print

Figures (7) ; References (22) ; Tables (1)

Arid land; Environmental impacts; Fine grained soils; Mathematical models; Modulus of resilience; Pavement design; Plasticity; Soil types

Mechanistic-Empirical Pavement Design Guide

Seasonal variations; Soil density; Soil properties

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

TRIS, TRB, ATRI

Jan 25 2010 11:09AM

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