论文信息 - Corrosion of silicon nitride materials in gas turbine environment

Corrosion of silicon nitride materials in gas turbine environment

Abstract In the present study the corrosion behavior of various silicon nitride materials will be presented. Hot gas tests were conducted in an atmosphere similar to that in a gas turbine (high temperature, pressure and flow rate and the water vapor pressure as the corrosive component). While some materials displayed a high degree of microstructural stability, all materials suffered surface degradation during the rig test. The oxidation surface layer of mainly SiO 2 , which is essential for the oxidation protection of nonoxide materials because it induces a passive, diffusion-controlled oxidation mechanism, was found to be degraded by evaporation processes involving volatile silicon hydroxides. As the mechanism of these processes a combination of linear oxidation and corrosion was proposed. The stabilization of the protective oxidation layer of silica should be considered as the main factor in stabilizing these materials in hot gas environments. This can be achieved by environmental barrier coatings (EBC), however their long-term stability was found to be still insufficient.

H. Klemm | Hagen Klemm

[1] H. Klemm,et al. Silicon nitride/molybdenum disilicide composite with superior long-term oxidation resistance at 1500°C , 2004 .

[2] É. Marmer,et al. High-temperature materials , 1971 .

[3] C. Gasdaska. Tensile creep in an in situ reinforced silicon nitride , 1994 .

[4] Tohru Yamamoto,et al. Degradation of Silicon Carbide in Combustion Gas Flow at High-Temperature and Speed , 2000 .

[5] Christian Schubert,et al. High Temperature Oxidation and Corrosion of Silicon-Based Non-Oxide Ceramics , 1998 .

[6] K. More,et al. Oxidation Behavior of Prospective Silicon Nitride Materials for Advanced Microturbine Applications , 2001 .

[7] J. Keiser,et al. Observations of Accelerated Silicon Carbide Recession by Oxidation at High Water-Vapor Pressures , 2000 .

[8] R. E. Hann,et al. Paralinear Oxidation of CVD SiC in Water Vapor , 1997 .

[9] S. Wittig,et al. Model Combustor to Assess the Oxidation Behavior of Ceramic Materials Under Real Engine Conditions , 1999 .

[10] James L. Smialek,et al. SiC Recession Caused by SiO2 Scale Volatility under Combustion Conditions: I, Experimental Results and Empirical Model , 1999 .

[11] Karren L. More,et al. Creep and Stress Rupture Behavior of an Advanced Silicon Nitride: Part I, Experimental Observations , 1994 .