Project Abstract:
The problem we are trying to solve is the condition assessment of corroded prestressed concrete (PC) bridge girders in New England. The problem is important because that PC bridge girders are a critical component of highway bridges. Concrete spalling and prestressing strand corrosion not only cause losses in prestress but also lead to premature failures of PC bridges. We propose to 1) conduct multiplysical field inspection (using 3D photogrammetry, radar, impact-echo, and ultrasound) and to 2) develop an integrated assessment framework for predicting the level of structural damage and prestress losses for PC bridge girders.
This project will enhance the transportation infrastructure durability as follows:
1) Efficient condition assessment algorithm – The chemical-mechanical model proposed by this research will provide a theoretical, but computationally efficient algorithm for assessing the remaining structural strength of PC bridge girders.
2) Data-driven decision-making – The vulnerability function for defining multiple damage states adopts the Bayesian framework, a data-driven method. The outcome can be customized improve the durability of PC bridges through effective structural repair.
Principal Investigator:
Dr. Tzuyang Yu (UML)
Institutions:
University of Massachusetts Lowell
Western New England University
Co-investigator:
Dr. Susan Faraji (UML)
Dr. Moochul Shin (WNEU)
Dr. ChangHoon Lee (WNEU)
Project Type:
Competitive-Funded Research
Start Date:
1/1/2019
Project Cost:
$174,403
Project Status:
In Progress
End Date:
9/30/2021
Agency ID:
69A3551847101
Sponsors:
University Transportation Centers Program, Department of Transportation
University of Massachusetts Lowell
Western New England University
Implementation of Research Outcomes:
We have developed a method to control the level of steel rebar corrosion inside reinforced concrete cylinder specimens in order to subject them to a pull-out test.
Impacts and Benefits of Implementation:
This project will enhance the transportation infrastructure durability as
follows:
• Efficient condition assessment algorithm – The chemical-mechanical model proposed by this research will provide a theoretical, but computationally efficient algorithm for assessing the remaining structural
strength of PC bridge girders.
• Data-driven decision-making – The vulnerability function for defining multiple damage states adopts the Bayesian framework, a data-driven method. The outcome can be customized improve the durability of PC
bridges through effective structural repair.
Related Links:
https://www.uml.edu/Research/tidc/projects/assessment-corroded-prestressed-bridge-girders.aspx
Downloadable Documents
September 2019 Semi-Annual Progress Report
December 2019 Quarterly Progress Report
March 2020 Quarterly Progress Report
June 2020 Quarterly Progress Report
September 2020 Quarterly Progress Report
December 2020 Quarterly Progress Report
March 2021 Quarterly Progress Report
June 2021 Quarterly Progress Report
September 2021 Quarterly Progress Report