Behavior of instrumented prestressed high performance concrete bridge girders

Many bridge owners have developed new precast, prestressed concrete bridge girder sections that are optimized for high-performance concrete and pretensioning strands with diameters greater than 0.5 in. (12.7 mm). Girder sections have been developed for increased span capacities, while others fill a need in shorter span ranges. Accurate geometric properties are essential for design. Common properties, including cross-sectional area, location of centroid, and major axis moment of inertia, are generally easy to compute and are readily available in standard design references. Computation of the torsion constant is a different matter. This paper presents the methods and results of a study to determine the torsion constant for many of the modern precast, prestressed concrete bridge girders used in the United States and compares the results with values from the approximate methods of the AASHTO LRFD specifications.

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Shrinkage in Ultra-High Performance Concrete Overlays on Concrete Bridge Decks

MATEC Web of Conferences ◽

10.1051/matecconf/201927107008 ◽

2019 ◽

Vol 271 ◽

pp. 07008

Author(s):

William Toledo ◽

Leticia Davila ◽

Ahmed Al-Basha ◽

Craig Newtson ◽

Brad Weldon

Keyword(s):

High Performance ◽

High Performance Concrete ◽

Bridge Decks ◽

Plastic State ◽

Early Age ◽

Concrete Bridge ◽

Ultra High Performance Concrete ◽

Concrete Overlays ◽

Concrete Bridge Decks ◽

Normal Strength

This paper investigates the shrinkage and thermal effects of an ultra-high performance concrete (UHPC) mixture proposed for use as an overlay material for concrete bridge decks. In this study, early-age and longer-term shrinkage tests were performed on the locally produced UHPC. Thermal and shrinkage effects in normal strength concrete slabs overlaid with UHPC were also observed. Early-age shrinkage testing showed that approximately 55% of the strain occurred in the plastic state and may not contribute to bond stresses since the elastic modulus of the UHPC should be small at such early ages. Thickness of the substrate and amount of reinforcing steel were important factors for shrinkage in the slabs. The thickest slab experienced greater shrinkage than thinner slabs. Comparing this slab to a thinner slab with the same reinforcement indicated that reinforcement ratio is more important than the area of steel.

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Prestress Loss Measurements in Missouri's First Fully Instrumented High-Performance Concrete Bridge

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198105192800113 ◽

2005 ◽

Vol 1928 (1) ◽

pp. 118-125 ◽

Cited By ~ 1

Author(s):

Yumin Yang ◽

John J. Myers

Keyword(s):

Prestressed Concrete ◽

High Performance ◽

High Performance Concrete ◽

High Strength ◽

Concrete Bridge ◽

Prestress Loss ◽

Prestress Losses ◽

Concrete Girders ◽

Allowable Stresses ◽

Loss Estimate

Prestress losses have a direct impact on concrete stress development and deflection behavior of highway bridge members. A poor estimate of prestress losses can result in a structure in which allowable stresses are exceeded or camber and deflection behavior is poorly predicted, such that the serviceability of a structure may be adversely affected. This paper reports the prestress losses observed throughout fabrication, shipment, erection, and the first 2 years of service for the first high-performance superstructure concrete bridge in Missouri. The prestress losses investigated included prerelease losses, elastic shortening losses, relaxation losses, creep losses, and shrinkage losses. Results from the study were compared with eight commonly used loss estimate models for total prestress losses, including AASHTO and Prestressed Concrete Institute methods. Recommendations were proposed by the authors for the most appropriate methodology to use to predict prestress losses in high-strength concrete girders accurately.

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