An Approach to Establishing Manufacturing Process and Vintage of Line Pipe Using In-Situ Nondestructive Examination and Historical Manufacturing Data

Switzner, Nathan; Veloo, Peter; Rosenfeld, Michael; Rovella, Troy; Gibbs, Jonathan

doi:10.1115/ipc2020-9589

Cited by 2 publications

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“…Equation (1) applies only for low-carbon ferrite-pearlite steels, and the reported accuracy of Equation (1) was ±31 MPa (4.5 ksi). Both manganese and carbon increase UTS, as observed by the following relationship developed by the same authors, because carbon makes up 0.77 wt.% of the microstructural constituent, pearlite, where pearlite represents the percent pearlite observed via metallographic evaluation [19]: UTS(MPa) = 294 + 28Mn + 83Si + 3.85(pearlite) + 7.7d − 1 2 (2) Recent findings [23] have shown that, over the past 100 years, manganese content and the content of microalloying elements such as vanadium, titanium, niobium, chromium, and molybdenum in line pipe steels has tended to increase, while carbon content has tended to decrease. Therefore, these long-accepted empirical relationships in Equations ( 1) and (2) may not hold for some contemporary line pipe steels.…”

Section: Introductionmentioning

confidence: 87%

Accurate Estimation of Yield Strength and Ultimate Tensile Strength through Instrumented Indentation Testing and Chemical Composition Testing

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Anderson²,

Kornuta

et al. 2022

Materials

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Federal rule changes governing natural gas pipelines have made non-destructive techniques, such as instrumented indentation testing (IIT), an attractive alternative to destructive tests for verifying properties of steel pipeline segments that lack traceable records. Ongoing work from Pacific Gas and Electric Company’s (PG&E) materials verification program indicates that IIT measurements may be enhanced by incorporating chemical composition data. This paper presents data from PG&E’s large-scale IIT program that demonstrates the predictive capabilities of IIT and chemical composition data, with particular emphasis given to differences between ultimate tensile strength (UTS) and yield strength (YS). For this study, over 80 segments of line pipe were evaluated through tensile testing, IIT, and compositional testing by optical emission spectroscopy (OES) and laboratory combustion. IIT measurements of UTS were, generally, in better agreement with destructive tensile data than YS and exhibited about half as much variability as YS measurements on the same sample. The root-mean squared error for IIT measurements of UTS and YS, respectively, were 27 MPa (3.9 ksi) and 43 MPa (6.2 ksi). Next, a machine learning model was trained to estimate YS and UTS by combining IIT with chemical composition data. The agreement between the model’s estimated UTS and tensile UTS values was only slightly better than the IIT-only measurements, with an RMSE of 21 MPa (3.1 ksi). However, the YS estimates showed much greater improvement with an improved RMSE of 27 MPa (3.9 ksi). The experimental, mechanical, and metallurgical factors that contributed to IIT’s ability to consistently determine destructive UTS, and the differences in its interaction with composition as compared to YS, are discussed herein.

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Section: Introductionmentioning

confidence: 87%

Accurate Estimation of Yield Strength and Ultimate Tensile Strength through Instrumented Indentation Testing and Chemical Composition Testing

Scales

Anderson²,

Kornuta

et al. 2022

Materials

Self Cite

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In Situ Metallography Applications in the Pipeline Industry

Amend¹,

Gould²,

Veloo³

et al. 2021

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The Merriam-Webster Dictionary defines metallography as “a study of the structure of metals, especially with the microscope.” The structure of a steel visible at high magnification can reveal information about how the steel was formed or heat-treated, the general “quality” of the steel, whether any observed discontinuities originated during manufacturing or while the component was in service, and the extent to which properties may be consistent across the wall thickness. Microstructural features such as grain size, the amount and distribution of inclusions, and the types and amounts of different microstructural phases are known to influence a material’s properties. In some cases, the observed attributes are qualitatively characterized. In other cases, manual or digital image analysis facilitates quantitative descriptions of attributes such as grain size, the percent of a selected phase, or inclusions that are present. Typically, small sections are cut from the pipe or other component and metallographic sample preparation and examination are performed in a laboratory. When destructive sampling is impractical, the specimen preparation, visual examination, and related photo documentation can be performed nondestructively in the field. That process is known as “in situ metallography” and is the subject of this paper.

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An Approach to Establishing Manufacturing Process and Vintage of Line Pipe Using In-Situ Nondestructive Examination and Historical Manufacturing Data

Cited by 2 publications

References 0 publications

Accurate Estimation of Yield Strength and Ultimate Tensile Strength through Instrumented Indentation Testing and Chemical Composition Testing

Accurate Estimation of Yield Strength and Ultimate Tensile Strength through Instrumented Indentation Testing and Chemical Composition Testing

In Situ Metallography Applications in the Pipeline Industry

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