Assessing Cracking and Seam Weld Anomalies in Pipelines
Led by Sergio Limón
November 9-10, 2022 | PRCI’s Technology Development Center | Houston

Featuring hands-on technology demonstrations

Register before October 26, 2022 and save $200!

COURSE SCHEDULE
Day 1:	9am-5pm CDT
Day 2:	9am-5pm CDT

Course Syllabus

Day 1

1. Characteristics and Behavior of Cracks and Long Seam Weld Anomalies in Pipelines
• A review of line pipe making, with emphasis on vintage ERW, Flash and Direct Current Welded pipelines
• The formation and growth of
• Environmentally Assisted Cracking: SCC axial & circumferential, hydrogen induced cracking, corrosion fatigue cracking, sulfide stress cracking, and selective seam corrosion
• Manufacturing Related Imperfections: lack of fusion, cold welds, stitching, and hook crack-like features
• Operationally Driven Cracking: fatigue cracks
• Difference between cracks and long seam weld anomalies
• PHMSA requirements for evaluating pipelines with cracks and seam weld defects
• Old and new regulations in Parts 192 and 195
• Review of current industry standards and recommended practices related to addressing cracking and seam weld integrity
• ASME B31.8S and API 1176 and 1160
• Hands-on demonstration of pipeline samples with cracks and seam weld defects

2. Foundations of Engineering Fracture Mechanics 
• The fracture process of pipelines with cracks or seam weld anomalies
• Fracture initiation, stable propagation, and fracture arrest or final fracture
• Fracture behavior: brittle, ductile and mix-mode
• Basic principles underlining Liner Elastic and Elastic-Plastic Fracture Mechanics and their applications to pipelines
• The concept of Stress Intensity Factor describing the relationship of failure stress as a function of crack size and material properties
• Fracture toughness testing
• Impact Charpy V-Notch and its relation to Ductile-to-Brittle transition curve
• Fracture mechanics-based toughness testing: Kc, Jc, CTOD and J-R crack growth resistance curve
• Correlation of CVN to K, J and CTOD

3. Performing Failure Pressure Calculations
• What to look for in any engineering method for determining the failure pressure of pipelines in the presence of cracks or seam weld anomalies
• Review of the following engineering methods: NG-18 Equation, Newman-Raju Equation, CorLAS, API 579-1/ASME FFS-1, and PRCI MAT-8
• Review of published studies comparing the accuracy of these methods
• Which one is more accurate or conservative?
• Effects of fracture toughness on failure pressure predictions
• In class demonstration of an Excel failure stress analysis calculator
• A review of crack prioritization and severity rankings by ASME and CEPA
• Crack length interlinking conditions of neighboring crack features by CEPA and API 579
• SCC growth estimation and industry reported growth rates

Day 2

4. Performing Fatigue Crack Growth Analysis
• Common concepts in fatigue analysis and stages of fatigue and fatigue life
• Steps for performing a fatigue crack growth analysis and remaining life calculation
• Setting initial cracks sizes, evaluating cyclic pressure data, choosing material properties, selecting a fatigue crack growth model and deciding on one the termination point of the fatigue analysis (failure condition)
• Review of fatigue crack growth models: Paris-Erdogan, Walker, Forman, NASGRO and choosing an appropriate set of C & m fatigue parameters
• Simplifying variable amplitude cyclic pressure data by means of the rainflow counting methods (ASTM E1049) and assessing the severity of cyclic pressures
• Performing sensitivity analysis of the final calculated fatigue life
• The use of safety factor on the predicted final fatigue life
• In class demonstration of case studies and the analysis of cyclic pressures

5. Integrity Assessments for Addressing Cracks and Long Seam Weld Anomalies
• Factors to consider when evaluating and deciding on assessment methods
• Hydrostatic Testing: setting up appropriate pressure test targets, hold times, the role of spike testing and determination of appropriate re-test intervals
• In-line Inspection: description of the UT, EMAT and C-MFL technologies, their performance, industry experience, and development of response criteria
• Direct Assessment methods: review and applicability of NACE SP0204 for SCCDA and CSA Z662 & CEPA Condition Monitoring for SCC

6. In-Ditch Non-Destructive Evaluation (NDE)
• Pipeline coating removal and surface preparation techniques
• Review of most widely used NDE methods and technologies
• Magnetic particle inspection
• Conventional UT shearwave
• Phased array UT (PAUT)
• Total Focusing Method (TFM)
• Inverse Wave Field Extrapolation (IWEX)
• Eddy Current-based
• Including emerging technologies
• NDE personnel qualifications, what should they be for pipeline applications?
• Present an NDE protocol framework for field evaluations and characterization of cracks and long seam weld anomalies
• Hands-on demonstration of various NDE methods and technologies commonly used for crack and seam weld detection and sizing
• Review of repairs options in the industry: ASME B31.8 & B31.4 and PRCI Repair Manual