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Shear behavior of prestressed concrete U-beamsMoore, Andrew Michael, 1984- 14 February 2011 (has links)
An experimental study was conducted at the Ferguson Structural Engineering Laboratory in order to investigate the shear behavior of 54-inch deep prestressed concrete U-beams. The primary goal of this research was to improve the design and detailing of the skewed end-blocks commonly used in these beams. As U-beams had been in service for several decades without incident, it was anticipated that there would be little need for change in the design, and the findings of the research would involve a slight tweaking to improve the overall performance.
Unfortunately, during the first phase of shear testing (testing of the current design standard) it was found that the U-beam was not reaching the code calculated shear capacity. During this phase of testing the premature failure mechanism was isolated as the breakdown of the web-to-flange interface in the end region of the girder.
Therefore, the second phase of testing sought to prevent the breakdown of this boundary by three options: (1) increasing the web width while maintaining current levels of mild reinforcement, (2) increasing the web width while also increasing the amount of reinforcement crossing the web-to-flange boundary, or (3) by increasing the amount of reinforcement at the boundary while maintaining the current web width.
Two acceptable solutions to the premature failure method were developed and tested during this phase both of which included an increase in the amount of mild reinforcement crossing the web-to-flange interface (with and without an increase in web width). The research into refining of these new details is ongoing as part of the Texas Department of Transportation’s Research Project number 0-5831. / text
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Structural performance of Texas U-beams at prestress transfer and under shear-critical loadsHovell, Catherine Grace, 1983- 13 October 2011 (has links)
The Texas U-Beam standard designs were released in the 1990’s and have been used increasingly in bridges across the state since. While prototypes of the 54-in. deep prestressed concrete beam were built during the design phase, no full-scale load tests were performed.
This study of the U-Beam had five goals: (i) determine the magnitude and location of stresses induced in reinforcing bars in the end region of the beam at prestress transfer, (ii) measure concrete curing temperatures in square and skewed end blocks, (iii) establish the vertical shear capacity of the standard section, (iv) evaluate interaction between behavior at prestress transfer and performance under shear-critical loads, and (v) identify design and detailing improvements and make recommendations. Eight full-scale Texas U54 prestressed concrete beams were fabricated to achieve these goals.
Load testing of the first four of these beams revealed a critical weakness along the bottom flange-to-web interface of the beam. The weakness caused failures that occurred at loads well below the calculated shear capacity. Given the horizontal sliding observed, the failure mode was called horizontal shear. The next two beams were fabricated to test three modifications to the end-region design, two of which were deemed successful. The final two beam sections tested contained the recommended new standard reinforcement and concrete geometry.
A method to evaluate the horizontal shear demand on and capacity of the bottom flange-to-web interface of prestressed concrete beams was developed. The calculations were formulated using the theories of beam bending and shear friction. This method was calibrated and verified using the U-Beam test data, a series of small-scale specimens, and results of shear tests in the literature.
Stresses induced in reinforcing bars at prestress transfer met expectations set by existing codified equations. No modifications to the current U-Beam standard design are needed to manage these stresses. The induced stresses did not influence vertical shear behavior, and no interaction between the two is believed to exist for U-Beams.
This dissertation contains the specifics of the beams tested and the data collected, and provides the details of recommended changes to the Texas U-Beam standard drawings. / text
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Impact of AASHTO LRFD specifications on the design of precast, pretensioned u-beam bridgesAdnan, Mohsin 12 April 2006 (has links)
Texas Department of Transportation (TxDOT) is currently designing its highway
bridge structures using the AASHTO Standard Specifications for Highway Bridges, and
it is expected that TxDOT will make transition to the use of the AASHTO LRFD Bridge
Design Specifications before 2007. The objectives of this portion of the study are to
evaluate the current LRFD Specifications to assess the calibration of the code with
respect to typical Texas U54 bridge girders, to perform a critical review of the major
changes when transitioning to LRFD design, and to recommend guidelines to assist
TxDOT in implementing the LRFD Specifications. This study focused only on the
service and ultimate limit states and additional limit states were not evaluated.
The available literature was reviewed to document the background research
relevant to the development of the LRFD Specifications, such that it can aid in meeting
the research objectives. Two detailed design examples, for Texas U54 beams using the
LRFD and Standard Specifications, were developed as a reference for TxDOT bridge
design engineers. A parametric study was conducted for Texas U54 beams to perform an
in-depth analysis of the differences between designs using both specifications. Major
parameters considered in the parametric study included span length, girder spacing,
strand diameter and skew angle. Based on the parametric study supplemented by the
literature review, several conclusions were drawn and recommendations were made. The
most crucial design issues were significantly restrictive debonding percentages and the
limitations of approximate method of load distribution.The current LRFD provisions of debonding percentage of 25 percent per section
and 40 percent per row will pose serious restrictions on the design of Texas U54 bridges.
This will limit the span capability for the designs incorporating normal strength
concretes. Based on previous research and successful past practice by TxDOT, it was
recommended that up to 75% of the strands may be debonded, if certain conditions are
met.
The provisions given in the LRFD Specifications for the approximate load
distribution are subject to certain limitations of span length, edge distance parameter (de)
and number of beams. If these limitations are violated, the actual load distribution should
be determined by refined analysis methods. During the parametric study, several of these
limitations were found to be restrictive for typical Texas U54 beam bridges. Two cases
with span lengths of 140 ft. and 150 ft., and a 60 degree skew were investigated by
grillage analysis method.
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Bursting and spalling in pretensioned U-beamsDunkman, David Andrew 31 August 2010 (has links)
An experimental program was conducted at the Ferguson Structural Engineering Laboratory of The University of Texas at Austin, under the auspices of Texas Department of Transportation (TxDOT) Research Project 5831, to investigate the tensile stresses that develop in the end regions of pretensioned concrete U-beams at transfer of prestress. Understanding the effect of these “bursting” and “spalling” stresses is essential in order to design standard details that might lead to reliably-serviceable end regions.
Two full-scale beam specimens, designed to be worst-case scenarios for bursting and spalling, were fabricated. Each beam had one square and one highly skewed end. Extensive instrumentation, including strain gages on transverse and lateral reinforcing bars, was employed in the end regions of these U-beams. Experimentally determined bursting and spalling stresses in these bars were compared to results of past projects (from the literature) investigating I-beams and inverted T-beams.
Preliminary recommendations are made for changes in the standard reinforcing details for U-beam end regions. Such recommended details will be tested in the upcoming phase of Research Project 5831. / text
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