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Methodologies for Predicting the Thermomechanical Fatigue Life
Evolution of Bridging Fiber Stress in Titanium Metal Matrix Composites
Thermomechanical Fatigue of Polymer Matrix Compositeslarry h strait
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alloy American Society anticlastic ASTM STP axial baseline bending bridging fiber calculated components compressive computed constraining force correlation crack closure crack depth crack growth rate crack initiation crack length crack propagation crack tip curve deformation effects elastic elastomer Engineering estimated experimental FALSTAFF Fatigue Crack Growth fatigue damage fatigue lives fatigue tests fiber stress finite element fractographic Fracture Mechanics fully constrained hoop stress hysteresis Inconel IP TMF laminate strain level of minimum macroblock maximum mean stress Metal Matrix Composites method microcracks microstructural minimum stress notch plastic zone notch root number of cycles overconstrained plate ply stress ratio S-N curves short crack shown in Fig Society for Testing spectrum loading spot weld strain energy strain range stress intensity factor stress level stress range stress-strain structural stress superalloy surface temperature tensile tensile stress Testing and Materials thermal cycling Titanium tubing unconstrained versus West Conshohocken yield strength