All Study Guides Bridge Engineering Unit 13
🌉 Bridge Engineering Unit 13 – Seismic Design & Performance of BridgesSeismic design of bridges focuses on ensuring structural integrity during earthquakes. It considers factors like seismic hazard, site conditions, and bridge configuration. The approach emphasizes performance-based design, ductility, and energy dissipation to prevent collapse and allow controlled damage.
Key components in seismic bridge design include foundations, piers, abutments, bearings, and superstructure elements. Each plays a crucial role in resisting seismic forces and maintaining stability. Analysis methods range from simplified static approaches to complex nonlinear dynamic simulations, guiding the design process and performance evaluation.
Key Concepts in Seismic Design
Seismic design aims to ensure bridges can withstand earthquake loads and maintain structural integrity
Considers factors such as seismic hazard, site conditions, bridge configuration, and materials
Utilizes performance-based design approach focuses on achieving specific performance objectives under different seismic hazard levels
Incorporates ductility and energy dissipation mechanisms to prevent sudden collapse and allow for controlled damage
Emphasizes the importance of redundancy and continuity in the load path to redistribute forces during seismic events
Accounts for soil-structure interaction effects can significantly influence the seismic response of bridges
Includes kinematic interaction modifies the ground motion input to the bridge
Also includes inertial interaction alters the dynamic properties and response of the bridge
Recognizes the need for regular maintenance and retrofit of existing bridges to enhance their seismic performance
Seismic Hazard Analysis
Seismic hazard analysis assesses the probability and intensity of earthquake ground motions at a bridge site
Involves identification and characterization of seismic sources such as faults and seismogenic zones
Considers historical seismicity and geological evidence to estimate the likelihood and magnitude of future earthquakes
Utilizes probabilistic seismic hazard analysis (PSHA) to quantify the uncertainty in ground motion predictions
PSHA combines the contributions from all potential seismic sources and ground motion models
Produces hazard curves and uniform hazard spectra for various return periods (e.g., 475 years, 2475 years)
Deterministic seismic hazard analysis (DSHA) is also used to estimate the worst-case scenario ground motions from specific seismic sources
Site-specific ground motion studies may be required for critical bridges or sites with complex geology
Seismic hazard maps and design codes provide regional hazard information for preliminary design and assessment
Bridge Components and Their Seismic Behavior
Bridge components include foundations, piers, abutments, bearings, and superstructure elements (girders, deck)
Foundations transfer loads from the bridge to the ground and provide stability during earthquakes
Pile foundations are commonly used in seismic regions to resist lateral loads and prevent soil liquefaction
Spread footings may be used for bridges on competent soils with low seismic hazard
Piers and columns are critical elements that support the superstructure and resist seismic forces
Ductile detailing and confinement reinforcement improve the deformation capacity and prevent brittle failure
Plastic hinges are designed to form at the base of piers to dissipate energy and limit damage to the superstructure
Abutments provide vertical and lateral support to the superstructure and retain the approach embankment
Seat-type abutments allow for relative movement and reduce seismic forces on the superstructure
Integral abutments provide a rigid connection and transfer seismic forces to the foundation
Bearings accommodate thermal movements and transmit vertical loads between the superstructure and substructure
Elastomeric bearings allow for limited horizontal movement and provide some energy dissipation
Seismic isolation bearings (lead-rubber, friction pendulum) decouple the superstructure from the substructure and reduce seismic forces
Superstructure elements (girders, deck) distribute loads and provide a continuous load path
Continuous superstructures enhance redundancy and allow for redistribution of forces during seismic events
Expansion joints and hinges are vulnerable components that require special detailing to prevent unseating and collapse
Seismic design philosophies have evolved from elastic design to ductile design and performance-based design
Elastic design aims to keep the structure in the elastic range under seismic loads, but can result in uneconomical designs
Ductile design allows for controlled inelastic behavior and energy dissipation, reducing seismic forces but accepting some damage
Performance-based design sets specific performance objectives for different seismic hazard levels
Performance objectives are defined in terms of structural damage, functionality, and repair time
Common performance levels include fully operational, operational, life safety, and near collapse
Design codes and standards (AASHTO, Caltrans) provide guidance on seismic design criteria and performance objectives
Importance factor is used to adjust seismic design forces based on the bridge's importance and consequence of failure
Seismic design category (SDC) is assigned based on the seismic hazard and site conditions, influencing the level of analysis and detailing required
Service level and ultimate level earthquakes are considered to ensure serviceability and prevent collapse, respectively
Seismic Analysis Methods
Seismic analysis methods predict the response of bridges under earthquake loads and guide the design process
Equivalent static analysis (ESA) is a simplified method that represents seismic forces as static lateral loads
Suitable for regular bridges with short periods and low seismic hazard
Seismic forces are distributed along the bridge based on mass and stiffness
Response spectrum analysis (RSA) is a linear dynamic analysis method that uses the structure's modal properties
Combines the peak responses of each mode using methods like SRSS (square root of sum of squares) or CQC (complete quadratic combination)
Accounts for higher mode effects and provides more accurate force and displacement estimates than ESA
Time history analysis (THA) is the most sophisticated and computationally intensive method
Requires input of ground motion time histories compatible with the site's seismic hazard
Captures the nonlinear behavior of bridge components and soil-structure interaction effects
Used for critical bridges, irregular configurations, or when significant nonlinear response is expected
Pushover analysis is a nonlinear static analysis method that assesses the bridge's capacity and identifies potential failure mechanisms
Applies incrementally increasing lateral loads to the bridge until a target displacement or collapse is reached
Provides insight into the bridge's ductility, strength hierarchy, and potential plastic hinge locations
Seismic isolation and energy dissipation devices may require specialized analysis techniques to capture their behavior
Analysis results are used to verify performance objectives, design components, and detail connections
Seismic Design Strategies and Techniques
Seismic design strategies aim to control damage, prevent collapse, and ensure post-earthquake functionality
Capacity design principle ensures a desirable hierarchy of strength and ductility in bridge components
Ductile components (plastic hinges in piers) are designed to yield and dissipate energy
Brittle components (foundations, superstructure) are designed to remain elastic and resist the maximum forces from ductile components
Ductile detailing improves the deformation capacity and energy dissipation of bridge components
Closely spaced transverse reinforcement (hoops, spirals) provides confinement and prevents buckling of longitudinal reinforcement
Plastic hinge regions require enhanced detailing to accommodate large inelastic rotations without significant strength degradation
Seismic isolation decouples the superstructure from the substructure and reduces seismic forces transmitted to the substructure
Lead-rubber bearings (LRBs) combine the flexibility of rubber layers with the energy dissipation of a lead core
Friction pendulum bearings (FPBs) use curved sliding surfaces to provide isolation and restore the superstructure to its original position
Supplemental energy dissipation devices (dampers) can be installed to absorb seismic energy and reduce structural response
Viscous dampers utilize the resistance of fluid flow to dissipate energy
Hysteretic dampers (buckling-restrained braces, yielding metal dampers) dissipate energy through inelastic deformation of metals
Restrainer cables and shear keys prevent unseating and provide transverse stability at expansion joints and hinges
Seismic retrofit techniques are used to improve the performance of existing bridges
Jacketing of columns with steel or fiber-reinforced polymer (FRP) increases confinement and ductility
Adding isolation bearings or dampers reduces seismic forces and improves the response
Strengthening foundations and increasing seat widths enhance stability and prevent unseating
Performance evaluation assesses the seismic behavior and vulnerability of existing bridges
Visual inspection and condition assessment identify structural deficiencies, damage, and deterioration
Material testing (concrete cores, reinforcement samples) provides information on the strength and quality of bridge components
Nondestructive testing techniques (ultrasonic, ground-penetrating radar) help evaluate the condition without causing damage
Structural analysis using as-built plans and current seismic codes determines the bridge's capacity and identifies potential weaknesses
Fragility analysis quantifies the probability of exceeding specific damage states under various seismic hazard levels
Fragility curves relate the ground motion intensity to the probability of damage
Used to prioritize bridges for retrofit and estimate post-earthquake functionality
Experimental testing validates analytical models and provides insights into the seismic behavior of bridge components
Quasi-static cyclic testing applies reversing lateral loads to assess the hysteretic behavior and ductility of components
Shake table testing subjects scaled bridge models to simulated earthquake ground motions
Hybrid simulation combines physical testing of critical components with numerical modeling of the remaining structure
Instrumentation and monitoring of bridges during earthquakes provide valuable data for model calibration and performance evaluation
Post-earthquake reconnaissance and damage assessment inform future design practices and retrofit strategies
Case Studies and Lessons Learned
Case studies of bridges that have experienced significant earthquakes offer valuable lessons for seismic design and performance
San Francisco-Oakland Bay Bridge (Loma Prieta earthquake, 1989)
Failure of bolted connections and unseating of spans highlighted the need for improved detailing and restraint systems
Retrofit measures included strengthening connections, adding restrainer cables, and replacing vulnerable spans
Hanshin Expressway (Kobe earthquake, 1995)
Collapse of steel box girder spans due to insufficient lateral restraint and poor weld quality
Emphasized the importance of ductile detailing, quality control, and consideration of soil-structure interaction
Bolu Viaduct (Duzce earthquake, 1999)
Failure of tall, slender piers due to inadequate confinement and shear reinforcement
Highlighted the need for ductile detailing and capacity design principles in seismic regions
Chile's highway bridges (Maule earthquake, 2010)
Good performance attributed to the use of seismic isolation, ductile detailing, and conservative design codes
Demonstrated the effectiveness of modern seismic design practices in reducing damage and maintaining functionality
Lessons learned from case studies have influenced the evolution of seismic design codes and practices
Improved detailing requirements for ductility and confinement
Increased focus on preventing unseating and enhancing system redundancy
Adoption of performance-based design and consideration of multiple performance objectives
Recognition of the importance of regular maintenance and timely retrofit of existing bridges
Sharing knowledge and experiences from past earthquakes promotes the continuous improvement of seismic design and resilience of bridges.