THERMOMECHANICAL FATIGUE BEHAVIOR OF A SILICON-CARBIDE FIBER-REINFORCED CALCIUM ALUMINOSILICATE COMPOSITE

Isothermal fatigue and in-phase thermomechanical fatigue (TMF) tests were performed on a unidirectional, continuous-fiber, Nicalon(R)-reinforced calcium aluminosilicate glass-ceramic composite ([0]16, SiC/CAS-II). Monotonic tensile tests were performed at 1100-degrees-C (2012-degrees-F) and 100 MPa/s (14.5 ksi/s) to determine the material's ultimate strength (sigma(ult)) and proportional limit (sigma(pl)). Isothermal fatigue tests at 1100-degrees-C employed two loading profiles, a triangular waveform with ramp times of 60 s and a similar profile with a superimposed 60-s hold time at sigma(max). All fatigue tests used a sigma(max) of 100 MPa (40% of sigma(pl)), R = 0.1. TMF loading profiles were identical to the isothermal loading profiles, but the temperature was cycled between 500-degrees and 1100-degrees-C (932-degrees and 2012-degrees-F). All fatigued specimens reached run-out (1000 cycles) and were tested in tension at 1100-degrees-C immediately following the fatigue tests. Residual modulus, residual strength, cyclic stress-strain modulus, and strain accumulation were all examined as possible damage indicators. Strain accumulation allowed for the greatest distinction to be made among the types of tests performed. Fiber and matrix stress analyses and creep data for this material suggest that matrix creep is the primary source of damage for the fatigue loading histories investigated.