01025684

Component

https://doi.org/10.3141/1952-13

http://scholar.google.com...Gisi&publication_year=2006

The Midwest States Accelerated Pavement Testing Pooled Fund Program, financed by the highway departments of Missouri, Iowa, Kansas, and Nebraska, has supported an accelerated pavement testing project to compare the performance of stabilized clayey embankment soil when portland cement, fly ash, lime, and a commercial product were used as stabilizing agents. The project aimed to determine if lime stabilization, the most common method used in Kansas for the chemical stabilization of embankment soils, is the optimum method. The experiments were conducted at the Civil Infrastructure Systems Laboratory of Kansas State University. The test program consisted of constructing four pavement structures and subjecting them to full-scale accelerated loading. The study indicated that cement and lime are the most effective stabilizers. These stabilizers resulted in lower vertical compressive stresses at the top of the subgrade and lower rut depth at the pavement surface than the stresses and depth resulting from fly ash–treated soil. After more than 2 million axle load repetitions, the pavement with cement-stabilized embankment soil exhibited much less surface cracking than did the pavement with fly ash–stabilized embankment soil. The commercial product proved ineffective in stabilizing the nonsulfate clayey soil used in this experiment, when the embankment was constructed at the same moisture content and compaction level as for the other three chemicals. The unconfined compressive strength measured on laboratory-prepared samples of soil stabilized with the commercial chemical compound was very similar to that of the untreated soil.

01032925

English

pp 118-124

2006

Transportation Research Record: Journal of the Transportation Research Board

0309099617

Print

Figures (6) ; References (4) ; Tables (2)

Accelerated tests; Calcium oxide; Cement; Clay soils; Compressive strength; Embankment foundations; Fly ash; Load tests; Pavement performance; Rutting; Soil stabilization; Stresses; Subgrade (Pavements)

Soil stabilizers

Geotechnology; Highways; I42: Soil Mechanics

TRIS, TRB, ATRI

Mar 3 2006 10:33AM

• Aggregate Morphology Affecting Resilient Behavior of Unbound Granular Materials
• Assessing the Quality of Soils Modified with Lime Kiln Dust: Measuring Electrical Conductivity with Time Domain Reflectometry
• Development of Cement-Treated Base Material for Reducing Shrinkage Cracks
• Effect of Aggregate Gradation, Mineral Fillers, Bitumen Grade, and Source on Mechanical Properties of Foamed Bitumen-Stabilized Mixes
• Evaluation of Test Equipment for Determination of Fine Aggregate Specific Gravity and Absorption
• Field Validation of Airport Pavement Granular Layer Rutting Predictions
• Full-Scale Accelerated Testing of Flexible Pavements Made of Coal Combustion Products
• Georgia’s Use of Cement-Stabilized Reclaimed Base in Full-Depth Reclamation
• Laboratory Assessment of Coarse Granular Road Foundation Materials
• Laboratory Characterization of Recycled Concrete for Use as Pavement Base Material
• Performance Evaluation and Numerical Modeling of Embankment over Soft Clayey Soil Improved with Chemico-Pile
• Permanent Deformation in Flexible Pavements with Unbound Base Courses
• Recommendations for Stabilization of High-Sulfate Soils in Texas
• Selection of Optimum Gravel Aggregate Size to Resist Permanent Deformation in Hot-Mix Asphalt