00771106

Component

https://doi.org/10.3141/1668-02

http://scholar.google.com...kard&publication_year=1999

In the past, concrete pavement design procedures have been based on stresses computed with the assumption of either a frictionless or a fully bonded interface between pavement layers. It is recognized that neither of these assumptions is realistic for layers not intentionally bonded. Information on the degree of interaction between pavement layers is provided. Full-scale load-induced strain and falling weight deflectometer testing was conducted to measure the degree of bonding between portland cement concrete pavement and a lean concrete base (LCB) layer prepared using five commonly specified interface treatments. For each interface treatment, the effect of extending the LCB layer beyond the slab edge was also evaluated. Strain gauges installed at different pavement depths measured the load-induced edge and wheelpath stress profiles, which allowed the degree of layer interaction to be evaluated. By analysis of load-induced stress and deflection, it was verified that a double layer of polyethylene promotes an unbonded interface with very little frictional interaction. Other interface treatments create varying degrees of friction or partial bond between the layers, reducing the load-induced stress. Slab bottom tensile stress reductions were computed in comparison with measured slab top compressive stress, measured polyethylene interface tensile stress, and theoretically calculated unbonded stress. Overall, the most effective stress-reducing interface treatments were asphalt emulsion and plain (no treatment) conditions, where tensile stress reductions of more than 40% were measured.

This paper appears in Transportation Research Record No. 1668, Concrete in Pavements and Structures.

English

p. 9-17

1999

Transportation Research Record

0309070635

Figures (2) ; References (8) ; Tables (7)

Asphalt emulsions; Bonding; Concrete bases; Concrete pavements; Deflection; Falling weight deflectometers; Interfaces; Load tests; Pavement layers; Strain gages; Stresses

Layer interaction; Polyethylene; Tensile stress

Design; Highways; Pavements; I22: Design of Pavements, Railways and Guideways; I23: Properties of Road Surfaces

TRIS, TRB, ATRI

Oct 6 1999 12:00AM

• CONCRETE CAPILLARY POROSITY AS IT RELATES TO DURABILITY OF PAVEMENTS BUILT WITH ALKALI-SILICA-REACTIVE AGGREGATES
• CRACKING DAMAGE/DETERIORATION AND REHABILITATION CONSIDERATIONS OF SOME BIRMINGHAM, ALABAMA, INTERSTATE BRIDGE DECKS
• EFFECT OF MICROCRACKING ON DURABILITY OF HIGH-STRENGTH CONCRETE
• GEOCHEMICAL METHOD FOR IDENTIFYING ALKALI-SILICA-REACTION GEL
• IMPACT OF PROCESSED CELLULOSE FIBERS ON PORTLAND CEMENT CONCRETE PROPERTIES
• INFLUENCE OF ALKALINE EARTH SILICATE ADMIXTURE ON DURABILITY OF PENNSYLVANIA TURNPIKE BRIDGES
• INFLUENCE OF TOTAL AGGREGATE GRADATION ON FREEZE-THAW DURABILITY AND OTHER PERFORMANCE MEASURES OF PAVING CONCRETE
• INVESTIGATION OF DESIGN PARAMETERS AFFECTING TRANSVERSE CRACKING IN JOINTED CONCRETE PAVEMENTS
• MITIGATION OF ALKALI-SILICA REACTION IN PAVEMENT PATCH CONCRETE THAT INCORPORATES HIGHLY REACTIVE FINE AGGREGATE
• PROPOSED GUIDELINES FOR THE PREVENTION OF ALKALI-SILICA REACTION IN NEW CONCRETE STRUCTURES
• USE OF A LITHIUM-BEARING ADMIXTURE TO SUPPRESS EXPANSION IN CONCRETE DUE TO ALKALI-SILICA REACTION
• VERY-EARLY-STRENGTH LATEX-MODIFIED CONCRETE OVERLAY
• VIRGINIA'S APPROACH TO EVALUATION OF CONCRETE RESISTANT TO ALKALI-SILICA REACTIONS