01124933

Component

https://doi.org/10.3141/2101-06

http://scholar.google.com...bell&publication_year=2009

Over the past three decades, many areas in western Canada have experienced increasing volumes of heavy commercial vehicles, primarily related to resource-based economic development. Combinations of changing moisture conditions, marginal granular materials, and heavy loadings often lead to premature road structure distress, failure, or both. In particular, slow-moving and turning truck traffic can significantly increase the applied stress states and moisture-pumping effects within the road structure, both at the surface and deep within the road structure. Strengthening a road structure to sustain severe heavy truck loadings often requires installing substructure drainage systems before placing the structural strengthening system. However, explicitly measuring the initial design requirements and the life-cycle performance of substructure drainage systems, as well as the impact of drainage systems on structural integrity, is difficult with traditional empirical model–based road structural evaluation and design methods. The use of a mechanistic model–based structural asset management approach to evaluate the performance of existing substructure drainage systems and to engineer the requirements of new drainage systems across three case studies is summarized. The findings of these case studies indicate that falling weight deflectometer and ground-penetrating radar are effective mechanistic model–based methods of structural assessment. They accurately quantify the spatial limits, the end-product structural asset value, and the performance of in-service drainage systems.

01139462

09-1650

English

pp 44-52

2009

Transportation Research Record: Journal of the Transportation Research Board

9780309126175

Print

Figures (8) ; Photos (7) ; References (8)

Asset management; Case studies; Drainage structures; Falling weight deflectometers; Ground penetrating radar; Heavy vehicles; Performance measurement; Subsurface drainage

Canada

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

PRP, TRIS, TRB, ATRI

Jan 30 2009 5:54PM

• Development and Validation of a Method to Evaluate Unpaved Road Condition with Objective Distress Measures
• Effect of Exopolymers on the Liquid Limit of Clays and Its Engineering Implications
• Effect of Suction on Resilient Modulus of Compacted Fine-Grained Subgrade Soils
• Estimation of Subgrade Resilient Modulus for Virginia Soil
• Functional Characteristics of Double Draining Layer Flexible Pavements
• Influence of Soil Suction on Small-Strain Stiffness of Compacted Residual Subgrade Soil
• Inverse Analysis of Plate Load Tests to Assess Subgrade Resilient Modulus
• Matric Suction Prediction Model in New AASHTO Mechanistic–Empirical Pavement Design Guide
• Method for Assessing Heavy Traffic Impacts on Gravel Roads Serving Oil- and Gas-Drilling Operations
• Roughness of Unpaved Roads: Estimation and Use as an Intervention Threshold
• Three-Point Imaging Test for AASHTO Soil Classification
• Variations of Resilient Modulus of Subgrade Soils with Postcompaction Moisture Contents