Crack Pattern Analysis of Plain Concrete Pavement due to Swelling Pressure on Expansive Soil

A jointed plain concrete pavement represents a reliable, historically proven technical solution for highly loaded roads, highways, airports and other industrial surfaces. Excellent resistance to permanent deformations (rutting) and also durability and maintenance costs play key roles in assessing the economic benefits, rehabilitation plans, traffic closures, consumption and recycling of materials. In the history of concrete pavement construction, slow-to-normal hardening Portland cement was used in Czechoslovakia during the 1970s-1980s. The pavements are being replaced after 40-50 years of service, mostly due to vertical slab displacements due to missing dowel bars. However, pavements built after 1996 used rapid hardening cements, resulting in long-term surface cracking and decreased durability. In order to build durable concrete pavements, slower hardening slag-blended binders were designed and tested in the restrained ring shrinkage test and in isothermal calorimetry. Corresponding concretes were tested mainly for the compressive/tensile strength evolution and deicing salt-frost scaling to meet current specifications. The pilot project was executed on a 14 km highway, where a unique temperature-strain monitoring system was installed to provide long-term data from the concrete pavement. A thermo-mechanical coupled model served for data validation, showing a beneficial role of slower hydration kinetics. Continuous monitoring interim results at 24 months have revealed small curling induced by drying and the overall small differential shrinkage of the slab.

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Analysis of Concrete Pavement Responses to Temperature and Wheel Loads Measured from Intrumented Slabs

Transportation Research Record Journal of the Transportation Research Board ◽

10.3141/1639-10 ◽

1998 ◽

Vol 1639 (1) ◽

pp. 94-101 ◽

Cited By ~ 37

Author(s):

H. Thomas Yu ◽

Lev Khazanovich ◽

Michael I. Darter ◽

Ahmad Ardani

Keyword(s):

Structural Response ◽

Plain Concrete ◽

Negative Temperature ◽

Concrete Pavement ◽

Temperature Gradients ◽

Critical Conditions ◽

Test Analysis ◽

Longitudinal Edge ◽

Critical Edge ◽

Using Data

The structural response of jointed plain concrete pavement slabs was evaluated using data obtained from instrumented slabs. The instrumented slabs were a part of newly constructed jointed plain concrete overlay that was constructed on existing asphalt concrete pavement on I–70 in Colorado, near the Kansas–Colorado border. The instrumentation consisted of dial gauges for measuring curling deflections at the slab corner and longitudinal edge and surface-mounted strain gauges for measuring load strains at the longitudinal edge at midslab. The through-thickness temperature profiles in the pavement slabs were also measured at 30-min intervals during the field test. Analysis of the field data showed that the instrumented slabs had a considerable amount of built-in upward curling and that concrete slabs on a stiff base can act completely independent of the base or monolithically with the base, depending on the loading condition. The built-in upward curling of the slabs has the same effect as negative temperature gradients. These findings suggest that the effects of temperature gradients on the critical edge stresses may not be as great as previously thought and that the corner loading, in some cases, may produce more critical conditions for slab cracking. Another important finding of this study is that a physical bond between pavement layers is not required to obtain a bonded response from concrete pavements.

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Experimental Study on Doweled Expansion Joints on Behavior for Plain Concrete Pavement System

Al-Khwarizmi Engineering Journal ◽

10.22153/kej.2018.03.001 ◽

2018 ◽

Vol 14 (3) ◽

pp. 68-80

Author(s):

Zainab Ahmed Al-kaissi ◽

Mohammed Hashim Mohammed ◽

Nabaa Sattar Kareem

Keyword(s):

Failure Load ◽

Concrete Slab ◽

Concrete Strength ◽

Plain Concrete ◽

Concrete Pavement ◽

Type I ◽

Expansion Joints ◽

Subgrade Soil ◽

Dowel Bar ◽

Bar Diameter

This paper deals with load-deflection behavior the jointed plain concrete pavement system using steel dowel bars as a mechanism to transmit load across the expansion joints. Experimentally, four models of the jointed plain concrete pavement system were made, each model consists of two slabs of plain concrete that connected together across expansion by two dowel bars and the concrete slab were supported by the subgrade soil. Two variables were dealt with, the first is diameter of dowel bar (12, 16 and 20 mm) and the second is type of the subgrade soil, two types of soil were used which classified according to the (AASHTO): Type I (A-6) and type II (A-7-6). Experimental results showed that increasing dowel bar diameter from 12 mm to 20 mm has a little effect on load-deflection behavior of the tested specimens with only 5% increase in failure load. This may be attributed to that the failure (caused by flexural crack) depends mainly on concrete strength. Results also showed that decreasing CBR value of subgrade soil from 7% to 5% decreases failure load by about 33%.

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