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Fracture behavior of advanced ceramic hot gas filters: Final report
Author(s) -
Jitendra Singh,
S. Majumdar,
M. Sutaria,
W. Bielke
Publication year - 1997
Language(s) - English
Resource type - Reports
DOI - 10.2172/491572
Subject(s) - thermal shock , materials science , composite material , ceramic , composite number , temperature cycling , filter (signal processing) , shock (circulatory) , thermal , natural rubber , compression (physics) , fracture (geology) , epoxy , medicine , physics , meteorology , computer science , computer vision
This report presents the results of mechanical/microstructural evaluation, thermal shock/fatigue testing, and stress analyses of advanced hot-gas filters obtained from different manufacturers. These filters were fabricated from both monolithic ceramics and composites. The composite filters, made of both oxide and nonoxide materials, were in both as-fabricated and exposed conditions, whereas the monolithic filters were made only of nonoxide materials. Mechanical property measurement of composite filters included diametral compression testing with O-ring specimens and burst-testing of short filter segments with rubber plugs. In-situ strength of fibers in the composite filters was evaluated by microscopic technique. Thermal shock/fatigue resistance was estimated by measuring the strengths of filter specimens before and after thermal cycling from an air environment at elevated temperatures to a room temperature oil bath. Filter performance during mechanical and thermal shock/fatigue loadings was correlated with microstructural observations. Micromechanical models were developed to derive properties of composite filter constituents on the basis of measured mechanical properties of the filters. Subsequently, these properties were used to analytically predict the performance of composite filters during thermal shock loading

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