화학공학소재연구정보센터
Journal of Materials Science, Vol.38, No.15, 3223-3231, 2003
Short-term flexural creep deformation in synroc-C
The flexural creep behaviour of synroc-C in an inert atmosphere was studied at temperatures of 860degreesC, 900degreesC and 940degreesC under constant-load conditions in four-point bending. Applied stresses ranged from 100 to 160 MPa. Individual creep curves show primary and secondary creep but little or no tertiary creep stage. The log of the creep rate was found to increase linearly with log of the applied stress at each temperature over the entire stress range. Analysis of the creep data using the Norton power-law function revealed that the stress exponent decreased from 3.3+/-0.6 for the 860degreesC and 900degreesC data to 2.0+/-0.2 for the 940degreesC data, and an activation energy of 440+/-40 kJ/mol was obtained over the entire temperature and stress range. Comparative analysis with the theta-projection equation was found to adequately represent the data yielding an activation energy of 464 kJ/mol while also showing a trend for the stress exponent to decrease with increasing temperature. Microstructural examination revealed extensive cavitation on the tensile surface of the creep specimens subjected to higher stresses at 900degreesC and 940degreesC. Dynamic high temperature X-ray diffraction analysis indicated little change in the phase assemblage apart from a slight reduction in the amount of the hollandite phase at higher temperatures which was attributed to a minor amount of oxidation. The possible creep damage mechanism was explored with reference to creep test results and microstructural modifications and the implications of the observations are discussed. (C) 2003 Kluwer Academic Publishers.