High Pressure Technology, Fracture Mechanics, and Service Experience in Operating Power Plants: Presented at the 1990 Pressure Vessels and Piping Conference, Nashville, Tennessee, June 17-21, 1990S. Y. Zamrik, E. H. Perez |
Contents
TOUGHNESS REQUIREMENTS AND EFFECTS OF PRESTRESS ON HIGH PRESSURE VESSELS | 1 |
FRACTURE FATIGUE AND MATERIALS FOR HIGH PRESSURE APPLICATIONS | 23 |
A High Pressure Threaded Closure Subjected to Temperature Transients | 29 |
Copyright | |
4 other sections not shown
Common terms and phrases
ASME ASSIGN GTC5428 assumed autofrettage axial stress boundary conditions calculated Charpy crack depth crack extension crack growth rate creep creep deformation cylinder determined deterministic fracture analysis effect elastic Equation evaluation failing strand fatigue damage finite element flaw depth fraction fracture mechanics fracture toughness ft-lb function geometry high pressure vessel hoop stress inches input file instability J-R curve layer leakage material maximum method monitoring normalised operating parameters PERL pipe plane strain plant plot power law pressure tube pressure vessel prestressed PROFILE radial radius ratio ramp rate Reactor reference stress residual stresses rotor RSM program rupture safe end SAFER shown in Figure shrinkage sidehole simulation SLAR stationary strain range stress concentration factor stress intensity factor stress solution temperature distribution temperature transients tensile stress threaded toughness requirements uncracked ligament Upper Shelf Energy valve von Mises Stress wall thickness wire yield strength