Classification of failure modes of pipelines containing longitudinal surface cracks using mechanics-based and machine learning models

This paper applies the mechanics-based approach and five machine learning algorithms to classify the failure mode (leak or rupture) of steel oil and gas pipelines containing longitudinally oriented surface cracks. The mechanics-based approach compares the nominal hoop stress remote from the surface...

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Bibliographic Details
Published in:Journal of infrastructure preservation and resilience 2023-12, Vol.4 (1), p.5-25, Article 5
Main Authors: Sun, Haotian, Zhou, Wenxing
Format: Article
Language:English
Subjects:
Algorithms
Bayesian analysis
Burst tests
Civil Engineering
Classification
Corrosion
Crack
Crack propagation
Cracks
Decision trees
Engineering
Failure mode
Failure modes
Full-scale test
Gas pipelines
Hoop stress
Hoops
Leaks
Learning algorithms
Machine learning
Machine learning models
Mechanics
Mechanics (physics)
Mechanics-based models
Natural gas
Neural networks
Petroleum pipelines
Pipeline
Pipelines
Pipes
Stress propagation
Support vector machines
Surface cracks
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Summary:This paper applies the mechanics-based approach and five machine learning algorithms to classify the failure mode (leak or rupture) of steel oil and gas pipelines containing longitudinally oriented surface cracks. The mechanics-based approach compares the nominal hoop stress remote from the surface crack at failure and the remote nominal hoop stress to cause unstable longitudinal propagation of the through-wall crack to predict the failure mode. The employed machine learning algorithms consist of three single learning algorithms, namely naïve Bayes, support vector machine and decision tree; and two ensemble learning algorithms, namely random forest and gradient boosting. The classification accuracy of the mechanics-based approach and machine learning algorithms is evaluated based on 250 full-scale burst tests of pipe specimens collected from the open literature. The analysis results reveal that the mechanics-based approach leads to highly biased classifications: many leaks erroneously classified as ruptures. The machine learning algorithms lead to markedly improved accuracy. The random forest and gradient boosting models result in the classification accuracy of over 95% for ruptures and leaks, with the accuracy of the decision tree and support vector machine models somewhat lower. This study demonstrates the value of employing machine learning models to improve the integrity management practice of oil and gas pipelines.
ISSN:2662-2521
2662-2521
DOI:10.1186/s43065-022-00062-5