LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES
H., A., K, S., M., R. (2011). LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES. EKB Journal Management System, 11(ASAT Conference, 17-19 May 2005), 395-410. doi: 10.21608/asat.2011.27159
Abdellatif S. H.; Shoukry M. K; Rabeeh B. M.. "LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES". EKB Journal Management System, 11, ASAT Conference, 17-19 May 2005, 2011, 395-410. doi: 10.21608/asat.2011.27159
H., A., K, S., M., R. (2011). 'LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES', EKB Journal Management System, 11(ASAT Conference, 17-19 May 2005), pp. 395-410. doi: 10.21608/asat.2011.27159
H., A., K, S., M., R. LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES. EKB Journal Management System, 2011; 11(ASAT Conference, 17-19 May 2005): 395-410. doi: 10.21608/asat.2011.27159

LIFE PREDICTION MODELING UNDER FATIGUE LOADING FOR ALUMINUM METAL MATRIX COMPOSITES

International Conference on Aerospace Sciences and Aviation Technology
Article 22, Volume 11, ASAT Conference, 17-19 May 2005, May 2011, Page 395-410  XML PDF (2.28 MB)
Document Type: Original Article
DOI: 10.21608/asat.2011.27159
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Authors
Abdellatif S. H.1; Shoukry M. K2; Rabeeh B. M.3
1Assistant Lecturer, Dept. of Mech. Engineering, Chair of Mech. design and production MTC, Cairo.
2Associate Professor, Dept. of Mech. Engineering, Chair of Mech. Mech. design and production MTC, Cairo.
3Associate Professor, Dept. of Mech. Engineering, Chair of Auto. MTC, Cairo.
Abstract
Metal matrix composites are currently being considered for use in many applications for their high strength-to-weight and stiffness-to-weight ratios, high wear resistance, and high thermal resistance. The present work focuses on the study of crack propagation in Aluminum monolithic and aluminum metal matrix composites reinforced with continuous stainless steel fibers at 4%, 8%, and 13% volume fractions with five plies, and unidirectional structural configuration. Based on experimental evidence, a micromechanical modeling approach was developed for the prediction of fatigue life and the model was compared with actual fatigue lives for these materials.
Keywords
Fatigue; Crack growth; life prediction; Metal Matrix Composites
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