Determination of Barge Impact Probabilities for Bridge Design.

机译：桥梁设计中驳船撞击概率的确定。

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Waterway bridges in the United States are designed to resist vessel collision loads according to design provisions released by the American Association of State Highway and Transportation Officials (AASHTO). These provisions provide detailed procedures for calculating design vessel impact loads within the context of a comprehensive risk assessment. One of the primary sub-components of this process is the calculation of probabilities that estimate the likelihood that a barge-to-bridge impact event will occur. However, the expressions used to predict the frequency of barge-to-bridge collisions were developed from a limited number of data sets. Furthermore, the technology employed by the maritime industry at the time the original AASHTO provisions were developed—in the early 1990s—has been significantly improved in subsequent decades. As a consequence of these factors, current estimates of barge-to-bridge collision probabilities may differ from presently-employed AASHTO estimates. The focus of the research described in this report was the development of a revised barge impact probability expression particularly applicable for the design of bridge structures located on Florida waterways. Specifically, the existing AASHTO expression for the base aberrancy rate (BR)—used to estimate the likelihood that a barge flotilla will stray from the intended transit path—was recalibrated and updated. Barge flotilla traffic data and barge-to-bridge collision (casualty) data for Florida bridge locations were collected and used to compute historical barge-to-bridge collision probabilities. These probabilities were then utilized in conjunction with additional supplementary parameters specified in AASHTO—quantified using bridge site-specific information—to back-calculate BR values for each bridge location. A subset of BR estimates from several bridge sites were then utilized to produce a single design value of BR that may be used in risk assessments for new and existing bridge structures. Based on results from the recalibration process, the updated BR estimate was 55% smaller than the current value prescribed by AASHTO. To demonstrate the effect of the recalibrated BR parameter, annual frequency (AF) of collapse values from risk assessments of two previously-investigated bridge structures—the Bryant Grady Patton Bridge (Apalachicola Bay, FL) and the LA-1 Bridge (Leeville, LA)—were recomputed using the updated BR expression. Despite the reduction in BR, values of AF estimated using UF/FDOT methods and the updated BR expression remained high relative to AF estimates produced by existing AASHTO methods. It was noted in this study that bridge locations with low volumes of barge traffic corresponded to high estimates of BR. This finding was a consequence of utilizing less data in the statistical calibration process, which reduced the accuracy of the resulting predictions. Consequently, only Florida bridge locations with significant levels of barge flotilla traffic were utilized to produce the recommended design value of BR. However, additional out-of-state locations exist with more highly trafficked bridge locations, as well as a more comprehensive source of barge traffic data. Inclusion of such locations in a similar recalibration effort could result in a lower design value of BR.

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Consolazio, G. R.; Kantrales, G. C.;
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年度 2016
页码 1-119
总页数 119
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Waterway bridges; Impact probabilities; Bridge design specifications; Barge impact; Barge-to-bridge collision; Bridge structures; Statistical data Methodology; Development and evaluation; American Association of State Highway and Transportation Officials (AASHTO);

机译：水路桥梁;冲击概率;桥梁设计规范;驳船冲击;驳船与桥梁碰撞;桥梁结构;统计数据方法学;开发和评估;美国国家公路和运输官员协会（aasHTO）;

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2. Probability of Collapse Expression for Bridges Subject to Barge Collision [J] . Michael T. DavidsonA.M.ASCE, Gary R. ConsolazioM.ASCE, Daniel J. GetterS.M.ASCE, Journal of bridge engineering . 2013,第4期

机译：驳船碰撞的桥梁坍塌表达的概率
3. Numerical Simulation of Barge Impact on a Continuous Girder Bridge and Bridge Damage Detection [J] . Yanyan Sha, Hong Hao International Journal of Protective Structures . 2013,第1期

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4. Development of an Improved Probability of Collapse Expression for Bridge Piers Subject to Barge Impact [C] . By Michael T. Davidson, Gary R. Consolazio Structures congress 2010 . 2010

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5. Probability assessment of bridge collapse under barge collision loads. [D] . Davidson, Michael Thomas. 2010

机译：驳船碰撞荷载下桥梁倒塌的概率评估。
6. Effects of salt bridges on protein structure and design. [O] . C. V. Sindelar, Z. S. Hendsch, B. Tidor 1998

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7. Numerical Simulation of Barge Impact on a Continuous Girder Bridge and Bridge Damage Detection [O] . Yanyan Sha, Hong Hao 2012

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8. Determination of Barge Impact Probabilities for Bridge Design, Summary Report. [R] . Consolazio, G. R., Kantrales, G. C. 2016

机译：桥梁设计中驳船撞击概率的确定，总结报告。

Determination of Barge Impact Probabilities for Bridge Design.

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