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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Use of Vertical Electrical Impedance for Nondestructive Evaluation of Concrete Bridge Decks

Boekweg, Enoch Thomas 27 July 2021 (has links)
Nondestructive evaluation of civil infrastructure is increasingly important in the modern world to assess structures, predict longevity, and prescribe rehabilitation or replacement. For concrete bridge decks, one emerging diagnostic technique is vertical electrical impedance (VEI) testing, which is a nondestructive evaluation technology that quantitatively assesses the cover protection offered to steel reinforcement. Because VEI testing is still a relatively new approach to bridge deck inspection, additional studies are needed to increase the interpretability of VEI data. This thesis increases VEI interpretability with two advances. The first advance, presented in Chapter 2, offers an analytical model for interpreting VEI measurements of cracked bridge decks. The analytical model allows crack depth to be predicted from VEI measurements. The second advance, presented in Chapter 3, offers an interpretation of VEI measurements within the context of other, more typical, nondestructive bridge deck measurements. Surface cracks cause a significant acceleration of chloride ingress towards the steel reinforcement because they provide a direct path for chlorides to penetrate the concrete cover and corrode the steel. Estimating the depth of these cracks enables better prediction of chloride loading and influences predictions of service life. An invertible analytical model for VEI measurements of cracks based on a cylindrical dipole approximation is presented. This model is validated with numerical simulations, laboratory experiments, and destructive field tests performed on concrete parking garage decks. Inversion of the model permits depth estimation of cracks and a quantitative interpretation of VEI measurements for this specific concrete defect. An additional study was performed on a newly constructed bridge deck in Midvale, Utah, that was subject to an unexpected rainstorm during construction. Several forms of nondestructive testing, including VEI testing, were performed on the deck. Statistical analysis of the tests permitted assessment of the bridge deck. Comparing VEI testing with these other NDT methods has not been done before, and the results of this work will assist those who are unfamiliar with VEI with interpretation of VEI data in the context of other, more typical NDT techniques.
2

Vertical Electrical Impedance Measurements on Concrete Bridge Decks Using a Large-Area Electrode

Barton, Jeffrey David 01 August 2018 (has links)
In regions where chloride-based deicing salts are applied to bridge decks, corrosion of the interior steel reinforcement is a major problem. Vertical electrical impedance (VEI) is an effective measurement technique to quantitatively assess the cover protection on bridges against aggressive chemical penetration of reinforced concrete. In its current form, traditional vertical electrical impedance is time-consuming and destructive because a direct connection to the reinforcing steel is required to provide a ground reference. A new method using a large-area electrode (LAE) permits VEI measurement without a direct electrical connection to the steel reinforcement. The LAE creates a nondestructive, semi-direct, low impedance connection between the measurement electronics and the reinforcing steel. In this work, numerical simulations are performed on common electrode arrangements to demonstrate the effectiveness of the LAE when significant variations in concrete conductivity exist. Physical experiments of a large-area electrode are carried out in the laboratory and field to validate the numerical simulations and to provide additional comparisons with the traditional tapped steel reinforcement method. The results of this study are a set of important design considerations for VEI utilizing a LAE to connect to the underlying rebar. Using these design considerations, the large-area electrode method was validated using both an analytical and a finite-element model, laboratory experiments, and field experiments on two bridges in Utah. The validation results indicate the LAE can replace the direct connection to the reinforcing steel. As a result of this work, a multichannel VEI scanner which uses the LAE method was built which can provide VEI information for bridge engineers and managers to better rehabilitate deteriorating reinforced concrete.

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