Calibration of AASHTO LRFD Concrete Bridge Design Specifications for Serviceability
Calibration of AASHTO LRFD Concrete Bridge Design Specifications for Serviceability

Author: Wagdy G. Wassef

Publisher:

Published: 2014

Total Pages:

ISBN-13:

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The notion of limit state is fundamental in the AASHTO LRFD Bridge Design Specifications (AASHTO LRFD). A limit state is defined as the boundary between acceptable and unacceptable performance of the structure or its component. The strength, or ultimate, limit states (ULS) of the AASHTO LRFD are calibrated through structural-reliability theory to achieve a certain level of safety. Exceeding the strength limit state results in a collapse or failure, an event that should not occur any time during the lifetime of the structure. Therefore, there is a need for an adequate safety margin expressed in the form of a target reliability index, BT. For bridge girders, the target reliability is taken as, BT = 3.5. The strength limit states do not consider the integration of the daily, seasonal, and long-term service stresses that directly affect long-term bridge performance and subsequent service life. The current service limit states (SLS) of the AASHTO LRFD are intended to ensure a serviceable bridge for the design life; assumed to be 75 years in AASHTO LRFD. When the SLS is exceeded, repair or replacement of components may be needed, repeatedly exceeding SLS can lead to deterioration and eventually collapse or failure (ULS). In general, SLS can be exceeded but the frequency and magnitude have to be within acceptable limits. The current service limit states are based upon the traditional serviceability provisions of the Standard Specifications for Highway Bridges. They are formulated to achieve component proportions similar to those of the Standard Specifications. However, these service limit states were not calibrated using reliability theory to truly achieve uniform probability of exceedence as the tools and data necessary to accomplish this calibration were not available to the code writers when AASHTO LRFD was developed. Currently, the development of calibrated service limit states remains a difficult task due to the lack of clear consequences of exceeding the SLS. This report presents the work performed on calibrating the service limit states related to concrete bridges in AASHTO LRFD.

Calibration of AASHTO LRFD Bridge Design Specifications
Calibration of AASHTO LRFD Bridge Design Specifications

Author: Benjamin Berwick

Publisher: LAP Lambert Academic Publishing

Published: 2013

Total Pages: 128

ISBN-13: 9783659494628

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It is important to develop and incorporate the knowledge needed to design, construct, and maintain bridges to have the longest service life as possible. Consequently, the fatigue effects on bridges need to be considered and more accurately reflected within the proper bridge design specifications. This thesis describes the calibration process used to select the load and resistance factors for the fatigue limit states of steel bridge members within the AASHTO LRFD Bridge Design Specifications. The process presented within this thesis builds upon work completed as part of the Strategic Highway Research Program No. 2 including the determination of the fatigue load model. The resistance model was developed using available fatigue test data and statistically analyzed using specially developed techniques. Load and resistance factors were finally chosen for both Fatigue I and Fatigue II service limit states. We expect the new load and resistance factors for the fatigue service limit states to more accurately capture the fatigue effects of steel bridges and thus increase their service life.

Calibration of the Live Load Factor in LRFD Design Guidelines
Calibration of the Live Load Factor in LRFD Design Guidelines

Author: Oh-Sung Kwon

Publisher:

Published: 2010

Total Pages: 104

ISBN-13:

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The Load and Resistant Factor Design (LRFD) approach is based on the concept of structural reliability. The approach is more rational than the former design approaches such as Load Factor Design or Allowable Stress Design. The LRFD Specification for Bridge Design has been developed through 1990s and 2000s. In the development process, many factors were carefully calibrated such that a structure designed with LRFD can achieve a reliability index of 3.5 for a single bridge girder (probability of failure of about 2 in 10,000). As the initial development of the factors in the LRFD Specification was intended to be applied to the entire nation, state-specific traffic conditions or bridge configuration were not considered in the development process. In addition, due to lack of reliable truck weigh data in the early 1990s in the U.S., the truck weights from Ontario, Canada measured in the 1970s were used for the calibration. Hence, the reliability of bridges designed with the current LRFD specification needs to be evaluated based on the Missouri-specific data and the load factor needs to be re-calibrated for optimal design of bridges. The objective of the study presented in this report is to calibrate the live load factor in the Strength I Limit State in the AASHTO LRFD Bridge Design Specification. The calibration is based on the Missouri-specific data such as typical bridge configurations, traffic volume, and truck weights. The typical bridge configurations and the average daily truck traffic of the bridges in Missouri are identified from statistical analyses of 2007 National Bridge Inventory. The Weigh-In-Motion (WIM) data from 24 WIM stations in Missouri are used to simulate realistic truck loads. Updated material and geometric parameters are also used to update the resistance distributions. From this study, it was found that most representative bridges in Missouri have reliability indices slightly lower than 3.5 mainly due to the adopted projection method to predict 75 year load. For many bridges in rural areas with Average Daily Truck Traffic (ADTT) of 1,000 or less, the average reliability indices are higher than the average reliability index of bridges with ADTT of 5,000. This study proposes a table of calibration factors which can be applied to the current live load factor of 1.75. The calibration factor is developed as a function of ADTT such that bridge design practitioners can select a calibration factor considering the expected ADTTs of a bridge throughout its life span. Impact of the calibration factor on the up-front bridge construction cost is also presented.

Numerical Modelling of Discrete Materials in Geotechnical Engineering, Civil Engineering and Earth Sciences
Numerical Modelling of Discrete Materials in Geotechnical Engineering, Civil Engineering and Earth Sciences

Author: Heinz Konietzky

Publisher: CRC Press

Published: 2004-10-15

Total Pages: 1022

ISBN-13: 9789058096807

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In this fully up-to-date volume, important new developments and applications of discrete element modelling are highlighted and brought together for presentation at the First International UDEC/3DEC Symposium. Papers covered the following key areas: * behaviour of masonry structures (walls, bridges, towers, columns) * stability and deformation of tunnels and caverns in fractured rock masses * geomechanical modelling for mining and waste repositories * rock reinforcement design (anchors, shotcrete, bolts) * mechanical and hydro-mechanical behaviour of dams and foundations * rock slope stability, deformation and failure mechanisms * modelling of fundamental rock mechanical problems * modelling of geological processes * constitutive laws for fractured rock masses and masonry structures * dynamic behaviour of discrete structures. Numerical Modelling of Discrete Materials in Geotechnical Engineering, Civil Engineering, and Earth Sciences provides an ultra-modern, in-depth analysis of discrete element modelling in a range of different fields, thus proving valuable reading for civil, mining, and geotechnical engineers, as well as other interested professionals.

Design of Highway Bridges
Design of Highway Bridges

Author: Richard M. Barker

Publisher: John Wiley & Sons

Published: 2021-03-23

Total Pages: 560

ISBN-13: 1119646332

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The latest in bridge design and analysis—revised to reflect the eighth edition of the AASHTO LRFD specifications Design of Highway Bridges: An LRFD Approach, 4th Edition, offers up-to-date coverage of engineering fundamentals for the design of short- and medium-span bridges. Fully updated to incorporate the 8th Edition of the AASHTO Load and Resistance Factor Design Specifications, this invaluable resource offers civil engineering students and practitioners a a comprehensive introduction to the latest construction methods and materials in bridge design, including Accelerated Bridge Construction (ABC), ultra high-performance concrete (UHPC), and Practical 3D Rigorous Analysis. This updated Fourth Edition offers: Dozens of end-of-chapter worked problems and design examples based on the latest AASHTO LRFD Specifications. Access to a Solutions Manual and multiple bridge plans including cast-in-place, precast concrete, and steel multi-span available on the Instructor’s companion website From gaining base knowledge of the AASHTO LRFD specifications to detailed guidance on highway bridge design, Design of Highway Bridges is the one-stop reference for civil engineering students and a key study resource for those seeking engineering licensure through the Principles and Practice of Engineering (PE) exam.

Bridge Engineering Handbook, Five Volume Set
Bridge Engineering Handbook, Five Volume Set

Author: Wai-Fah Chen

Publisher: CRC Press

Published: 2014-01-24

Total Pages: 3130

ISBN-13: 1482255030

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Over 140 experts, 14 countries, and 89 chapters are represented in the second edition of the Bridge Engineering Handbook. This extensive collection provides detailed information on bridge engineering, and thoroughly explains the concepts and practical applications surrounding the subject, and also highlights bridges from around the world.Published