Method and system to detect stress corrosion cracking in pipeline systems
First Claim
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1. A method of determining crack locations associated with a tubular member, the method comprising:
- locating a set of stress corrosion cracking indicators associated with a tubular member;
locating a set of low-level corrosion indicators associated with a tubular member;
comparing locations of the set of stress corrosion cracking indicators with locations of the set of low-level corrosion indicators;
establishing a subset of stress corrosion cracking indicators and a subset of low-level corrosion indicators when the location of any of the set of stress corrosion cracking indicators is located within a first preselected distance from any of the set of low-level corrosion indicators;
locating a set of soil characterization indicators associated with the tubular member;
comparing locations of the set of soil characterization indicators with locations of the subset of stress corrosion cracking indicators and locations of the subset of low-level corrosion indicators;
establishing a plurality of predictor stress corrosion cracking indicators, a plurality of predictor low-level corrosion indicators, and a plurality of predictor soil characterization indicators when the location of any of the set of soil characterization indicators is located both within a second preselected distance from any of the subset of stress corrosion cracking indicators and within a third preselected distance from any of the subset of low-level corrosion indicators; and
predicting at least one of a plurality of locations associated with the tubular member susceptible to stress corrosion cracking responsive to at least two of the plurality of predictor indicators.
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Abstract
A method for predicting the location of stress corrosion cracking in a steel gas pipeline in which in-line stress corrosion cracking smart tool data, external low level metal loss data and soil characterization data are compiled to predict the location of stress corrosion cracking in a steel gas pipeline segment.
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Citations
25 Claims
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1. A method of determining crack locations associated with a tubular member, the method comprising:
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locating a set of stress corrosion cracking indicators associated with a tubular member; locating a set of low-level corrosion indicators associated with a tubular member; comparing locations of the set of stress corrosion cracking indicators with locations of the set of low-level corrosion indicators; establishing a subset of stress corrosion cracking indicators and a subset of low-level corrosion indicators when the location of any of the set of stress corrosion cracking indicators is located within a first preselected distance from any of the set of low-level corrosion indicators; locating a set of soil characterization indicators associated with the tubular member; comparing locations of the set of soil characterization indicators with locations of the subset of stress corrosion cracking indicators and locations of the subset of low-level corrosion indicators; establishing a plurality of predictor stress corrosion cracking indicators, a plurality of predictor low-level corrosion indicators, and a plurality of predictor soil characterization indicators when the location of any of the set of soil characterization indicators is located both within a second preselected distance from any of the subset of stress corrosion cracking indicators and within a third preselected distance from any of the subset of low-level corrosion indicators; and predicting at least one of a plurality of locations associated with the tubular member susceptible to stress corrosion cracking responsive to at least two of the plurality of predictor indicators. - View Dependent Claims (2, 3)
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4. A method of determining crack locations associated with a tubular member, the method comprising:
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evaluating the tubular member to gather data relating associated with the tubular member; locating a plurality of stress corrosion cracking indicators associated with the tubular member; locating a plurality of low-level corrosion indicators associated with the tubular member; locating a plurality of soil characterization indicators associated with the tubular member; establishing a plurality of predictor stress corrosion cracking indicators, a plurality of predictor low-level corrosion indicators, and a plurality of predictor soil characterization indicators when any of the plurality of stress corrosion cracking indicators, any of the plurality of low-level corrosion indicators and any of the plurality of soil characterization indicators are located within a preselected distance from each other; and predicting a plurality of locations on the tubular member susceptible to stress corrosion cracking responsive to at least two of the plurality of predictor indicators. - View Dependent Claims (5, 6, 7, 8, 9, 10)
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11. A system to determine crack locations on a tubular member, the system comprising:
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a comparator to compare locations of a set of stress corrosion cracking indicators associated with a tubular member with locations of a set of low-level corrosion indicators associated with the tubular member to thereby establish a subset of stress corrosion cracking indicators and a subset of low-level corrosion indicators, responsive to comparing the sets of indicators, when the location of any of the set of stress corrosion cracking indicators is located within a first preselected distance from any of the set of low-level corrosion indicators, the comparator further comparing locations of a set of soil characterization indicators associated with the tubular member with locations of the subset of stress corrosion cracking indicators and locations of the subset of low-level corrosion indicators; and a predictor to predict that a segment of the tubular member is susceptible to stress corrosion cracking, responsive to comparing the set of soil characterization indicators with the subsets of indicators, when any of the set of soil characterization indicators is located both within a second preselected distance from any of the subset of stress corrosion cracking indicators and within a third preselected distance from any of the subset of low-level corrosion indicators. - View Dependent Claims (12, 13, 14, 15, 16, 17)
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18. A system to determine crack locations associated with a tubular member, the system comprising:
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a comparator to compare locations of a set of stress corrosion cracking indicators associated with the tubular member with locations of a set of low-level corrosion indicators associated with the tubular member to thereby establish a subset of stress corrosion cracking indicators and a subset of low-level corrosion indicators, responsive to comparing the sets of indicators, when the location of any of the set of stress corrosion cracking indicators is located within a first preselected distance from any of the set of low-level corrosion indicators, the comparator also being positioned to compare locations of a set of soil characterization indicators associated with the tubular member with locations of the subset of stress corrosion cracking indicators and locations of the subset of low-level corrosion indicators; and a confirmer to confirm a presence of stress corrosion cracking in a segment of the tubular member, responsive to comparing the set of soil characterization indicators with the subsets of indicators, when any of the set of soil characterization indicators is located both within a second preselected distance from any of the subset of stress corrosion cracking indicators and within a third preselected distance from any of the subset of low-level corrosion indicators. - View Dependent Claims (19, 20, 21, 22, 23)
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24. A method of determining crack locations associated with a pipeline body wall, the method comprising:
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detecting a set of crack-like features associated with the pipeline; detecting a set of low-level metal loss corrosions; comparing locations of the set of crack-like features with locations of the set of low-level metal loss corrosions; establishing a subset of crack-like features and a subset of low-level metal loss corrosions, responsive to comparing the set of crack-like features with the set of low-level metal loss corrosions, when the location of any of the set of crack-like features is located within a first preselected distance from any of the set of low-level metal loss corrosions; detecting a set of soil characterization models; comparing locations of the set of soil characterization models with locations of the subset of crack-like features and locations of the subset of low-level metal loss corrosions; and confirming with high probability the presence of stress corrosion cracks associated with the pipeline body wall when the location of any of the set of soil characterization models is located both within a second preselected distance from any of the subset of crack-like features and within a third preselected distance from any of the subset of low-level metal loss corrosions.
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25. A method of predicting a location of stress crack corrosion in a gas pipeline, the method comprising:
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integrating in-line pipeline wall inspection results, in-line low level external metal loss, external corrosion analysis results, and soil characterization model results; and comparatively evaluating the in-line pipeline wall inspection results, the in-line low level external metal loss, the external corrosion analysis results, and the soil characterization model results to determine with a high confidence level whether actual stress corrosion cracking exists at a physical gas pipeline segment location responsive to the integrating.
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Specification