Abstract
Early-age cracking can adversely affect strength, serviceability, and durability of concrete bridge decks. Early age is defined as the period after final setting, during which concrete properties change rapidly. Many factors can cause early-age bridge deck cracking including temperature change, hydration, plastic shrinkage, autogenous shrinkage, and drying shrinkage. The cracking may also increase the effect of freeze and thaw cycles and may lead to corrosion of reinforcement. This research paper presents an analysis of causes and factors affecting early-age cracking. It also provides a tool developed to predict the likelihood and initiation of early-age cracking of concrete bridge decks. Understanding the concrete properties is essential so that the developed tool can accurately model the mechanisms contributing to the cracking of concrete bridge decks. The user interface of the implemented computer Excel program enables the user to input the properties of the concrete being monitored. The research study and the developed spreadsheet were used to comprehensively investigate the issue of concrete deck cracking. The spreadsheet is designed to be a user-friendly calculation tool for concrete mixture proportioning, temperature prediction, thermal analysis, and tensile cracking prediction. The study also provides review and makes recommendations on the deck cracking based mainly on the Florida Department of Transportation specifications and Structures Design Guidelines, and Bridge Design Manuals of other states. The results were also compared with that of other commercially available software programs that predict early-age cracking in concrete slabs, concrete pavement, and reinforced concrete bridge decks. The outcome of this study can identify a set of recommendations to limit the deck cracking problem and maintain a longer service life of bridges.
Highlights
Transverse cracking has been observed in many bridge decks in Florida and other states (e.g., Wan et al 2010)
This volume change can lead to early-age cracking due to restraint of volume changes associated with thermal deformation, shrinkage due to hydration reactions, and shrinkage due to drying
There are several conclusions drawn from this study including implementing a number of practical methods for evaluating and reducing the risk of early-age cracking such as reducing the placement temperature of the concrete, selecting an aggregate with a low coefficient of thermal expansion, using a favorable grading, using a large maximum size aggregate, using a relatively coarsely ground cement with a low alkali content, and a high sulfate content relative to its C3A content, substituting some of the cement with fly ash, using entrained air, and using SRAs
Summary
Transverse cracking has been observed in many bridge decks in Florida and other states (e.g., Wan et al 2010). The Ohio DOT (ODOT) Bridge Design Manual (BDM) requires calculating a minimum reinforced concrete deck thickness using the following equation (BDM 302.2.1): TminðinchesÞ 1⁄4 ðS þ 17Þð12Þ=36 ! The Pennsylvania DOT (PennDOT) Design Manual Part 4 Structures (DM-4) recommends a minimum reinforced concrete deck thickness of 8.0 inches (Part B, 9.7.1.1) which includes a 0.5 inch wearing surface. This is true for both reinforced and prestressed precast concrete deck panels (Part B, 9.7.5.1). The AASHTO LRFD Bridge Design Specifications (LRFD) requires that the minimum thickness of a reinforced concrete deck should not be less than 7.0 inches (LRFD 9.7.1.1), if approved by the owner. Based on the information mentioned above, this research considered a range of 3000–5500 psi
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