Abstract
Long-span prestressed concrete (PSC) bridges often suffer excessive deflection during their service lives. The nonuniform shrinkage strains of concrete caused by uneven moisture distributions can induce significant additional deflections, when combined with the creep and cracking of the concrete. Current design practices usually overlook these factors, and the few proposed approaches to consider them are complex and computationally expensive. This study proposes a simplified approach for considering the effect of nonuniform shrinkage by using the equivalent load concept in combination with a nonlinear analysis of the creep and cracking using three-dimensional finite element models. The long-term deflections of short-, medium-, and long-span PSC bridges are calculated under the combined effects of creep, shrinkage, and cracking. The results show that the nonuniform shrinkage effect is significant in medium- to long-span bridges, and that the cracking of the concrete reduces the stiffness, thereby increasing the long-term deflection of the bridges (more severely so in combination with creep and shrinkage). The predicted long-term deflections reasonably agree with the measured data. Thus, the equivalent load approach is effective for calculating long-term deflections considering nonuniform shrinkage strains, without the complicated and expensive coupling of moisture transport and structural analyses.
Highlights
Modern transportation systems, such as high-speed train systems, demand for long-span bridges are increasing
Long-span prestressed concrete (PSC) bridges often suffer excessive deflections during their service lives. This excessive deflection is mainly owing to the creep and shrinkage of the concrete
This study proposes a simplified approach for capturing the additional effects of nonuniform shrinkage in a 3D structural analysis simultaneously with those concrete creep, uniform shrinkage, and cracking models, based on commercial software
Summary
Modern transportation systems, such as high-speed train systems, demand for long-span bridges are increasing. The longer span length and faster operating speed make the system very sensitive to deflections of super and sub-structures [1]. Accurate prediction of the time-dependent deflections of these structures (especially slender bridges) has become imperative. Long-span prestressed concrete (PSC) bridges often suffer excessive deflections during their service lives. This excessive deflection is mainly owing to the creep and shrinkage of the concrete. Current design codes provide practical methods for predicting the long-term deflections of concrete bridges, but they often underestimate the results [2,3,4,5]
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