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Development and Evaluation of Improved Model for Engineering Critical Assessment of Pipelines

Development and Evaluation of Improved Model for Engineering Critical Assessment of Pipelines <jats:p>In past work, the authors developed a very useful model for engineering critical assessment (ECA) of pipelines with stress corrosion cracking (SCC). That model uses the effective area method to characterize the crack-depth profile along with flow strength and fracture toughness failure criteria. In the current work, the model was improved in four areas. Tearing instability was added to the fracture toughness failure criteria, formulations for computing values of the J integral for surface cracks were improved, interaction criteria were developed for co-planar flaws, and relationships for estimating values of the strain-hardening exponent were developed. To help validate the improved model, J fracture toughness tests were conducted using compact-tension (CT) specimens, and burst tests were conducted on pipe samples with large flaw length-to-depth ratios.</jats:p> http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png 4th International Pipeline Conference, Parts A and B CrossRef

Development and Evaluation of Improved Model for Engineering Critical Assessment of Pipelines

4th International Pipeline Conference, Parts A and BJan 1, 2002

Development and Evaluation of Improved Model for Engineering Critical Assessment of Pipelines


Abstract

<jats:p>In past work, the authors developed a very useful model for engineering critical assessment (ECA) of pipelines with stress corrosion cracking (SCC). That model uses the effective area method to characterize the crack-depth profile along with flow strength and fracture toughness failure criteria. In the current work, the model was improved in four areas. Tearing instability was added to the fracture toughness failure criteria, formulations for computing values of the J integral for surface cracks were improved, interaction criteria were developed for co-planar flaws, and relationships for estimating values of the strain-hardening exponent were developed. To help validate the improved model, J fracture toughness tests were conducted using compact-tension (CT) specimens, and burst tests were conducted on pipe samples with large flaw length-to-depth ratios.</jats:p>

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Publisher
CrossRef
DOI
10.1115/ipc2002-27027
Publisher site
See Article on Publisher Site

Abstract

<jats:p>In past work, the authors developed a very useful model for engineering critical assessment (ECA) of pipelines with stress corrosion cracking (SCC). That model uses the effective area method to characterize the crack-depth profile along with flow strength and fracture toughness failure criteria. In the current work, the model was improved in four areas. Tearing instability was added to the fracture toughness failure criteria, formulations for computing values of the J integral for surface cracks were improved, interaction criteria were developed for co-planar flaws, and relationships for estimating values of the strain-hardening exponent were developed. To help validate the improved model, J fracture toughness tests were conducted using compact-tension (CT) specimens, and burst tests were conducted on pipe samples with large flaw length-to-depth ratios.</jats:p>

Journal

4th International Pipeline Conference, Parts A and BCrossRef

Published: Jan 1, 2002

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