Circumferential Cracks in Pressure Vessels and Piping: Presented at the 4th National Congress on Pressure Vessel and Piping Technology, the American Society of Mechanical Engineers, Portland, Oregon, June 19-24, 1983, Volume 2G. M. Wilkowski ASME, 1984 - Pipelines |
Contents
Parametric Calculations of Fatigue Crack Growth in Piping | 1 |
Fatigue and Fracture of Circumferentially Cracked Pipes | 15 |
Improved Influence Functions for PartCircumferential Cracks in Pipes | 35 |
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304 stainless steel applied ASTM austenitic axial crack behavior bending loads bending moment calculated Circumferentially Cracked Pipe comparison compliance crack angle crack extension crack initiation crack instability crack propagation crack tip criterion CTOA CTOD cyclic stress defect deformation ductile ductile fracture effect elastic Elastic-Plastic energy release rate EPRI equation evaluated experimental data failure ferritic finite element finite element analysis flawed piping flow stress Fracture Mechanics fracture toughness geometry girth welds hoop stress in-lb/inĀ² inch influence functions initial crack J-integral Kanninen leak ligament maximum load net-section collapse obtained parameter pipe experiments pipe material pipe specimens pipe test pipe wall Pipeline piping systems plastic collapse predicted Pressure Vessel Reactor rupture Section XI shell shown in Figure stainless steel pipes strain stress intensity factors surface crack surface flaws tearing instability tearing modulus temperature tensile through-wall crack Type 304 stainless values wall thickness Wilkowski Zahoor