Experimental tests of a seismic retrofit components on a full-scale model of a typical steel bridge in Mid-America

Pfeifer, Thomas A.

12 1900

No description available.

Bridges Remodeling

Earthquake resistant design

Bridges Testing

Seismic analysis and retrofit of mid-America bridges

Choi, Eunsoo

05 1900

No description available.

Bridges Remodeling

Earthquake resistant design

Bridges Testing

Seismic retrofit of bridges using shape memory alloys

Delemont, Michael A.

12 1900

No description available.

Bridges Remodeling

Earthquake resistant design

Shape memory alloys

Seismic Vulnerability Assessment of Retrofitted Bridges Using Probabilistic Methods

Padgett, Jamie Ellen

09 April 2007

The central focus of this dissertation is a seismic vulnerability assessment of retrofitted bridges. The objective of this work is to establish a methodology for the development of system level fragility curves for typical classes of retrofitted bridges using a probabilistic framework. These tools could provide valuable support for risk mitigation efforts in the region by quantifying the impact of retrofit on potential levels of damage over a range of earthquake intensities. The performance evaluation includes the development of high-fidelity three-dimensional nonlinear analytical models of bridges retrofit with a range of retrofit measures, and characterization of the response under seismic loading. Sensitivity analyses were performed to establish an understanding of the appropriate level of uncertainty treatment to model, assess, and propagate sources of uncertainty inherent to a seismic performance evaluation for portfolios of structures. Seismic fragility curves are developed to depict the impact of various retrofit devices on the seismic vulnerability of bridge systems. This work provides the first set of fragility curves for a range of bridge types and retrofit measures. Framework for their use in decision making for identification of viable retrofit measures, performance-based retrofit of bridges, and cost-benefit analyses are illustrated. The fragility curves developed as a part of this research will fill a major gap in existing seismic risk assessment software, and enable decision makers to quantify the benefits of various retrofits.

Retrofit

Seismic risk

Reliability

Bridges

Fragility

Earthquakes

Bridges Remodeling

Response surfaces (Statistics)

Earthquake resistant design

Bridges Earthquake effects

Seismic Response and Analysis of Multiple Frame Bridges Using Superelastic Shape Memory Alloys

Andrawes, Bassem Onsi

14 April 2005

The feasibility of using superelastic shape memory alloys in the retrofit of multiple frame bridges is investigated. First, three shape memory alloy constitutive models with various levels of complexity are compared in order to determine the significance of including subloops and cyclic loading effects on the structural response. The results show that the structural response is more sensitive to the shape memory alloys strength degradation and residual deformation than the sublooping behavior. Next, two parametric studies are conducted to explore the sensitivity of hinge opening to the mechanical behavior of the superelastic shape memory alloys. The first study is focused on the hysteretic properties of the alloy that could vary depending on the chemical composition or the manufacturing process of the alloy, while the second study targets the changes in the mechanical behavior of shape memory alloys resulting from the variability in the ambient temperature. The results show that the hysteretic behavior of shape memory alloys has only a slight effect on the bridge hinge opening as long as the recentering property is maintained. A detailed study on the effect of temperature shows that a reduction in the ambient temperature tends to negatively affect the hinge opening while an increase in temperature results in a slight improvement. Next, a parametric study is conducted to examine the effectiveness of shape memory alloy retrofit devices in limiting hinge openings in bridges with various properties. In addition, a comparison is made with other devices such as conventional steel restrainers, metallic dampers, and viscoelastic solid dampers. The results illustrate that superelastic shape memory alloys are superior in their effectiveness compared to other devices in the case of bridges with moderate period ratios and high level of ductility, especially when subjected to strong earthquakes.

Unseating

Shape memory alloys

Bridges

Seismic

Restrainers

Multiple frame bridges

Superelastic

Earthquakes

Bridges Remodeling

Deformations (Mechanics)

Earthquake resistant design

Elasticity