A photoelastic technique for characterizing fatigue crack closure and the effective stress intensity factor

• Autorzy: Pacey M. , Patterson E. , James M.
• Konferencja: Summer School Of Fracture Mechanics. Current Research On Fatigue And Fracture/sympozjum (VII ; 18-22.06.2001 ; Opole - Pokrzywna, Poland)
• Języki publikacji: EN

Słowa kluczowe

EN

photoelastic technique; fatigue crack closure; effective stress intensity factor

• Wydawca: Oficyna Wydawnicza Politechniki Opolskiej
• Czasopismo: Zeszyty Naukowe. Mechanika / Politechnika Opolska
• Rocznik: 2001
• Tom: z. 67
• Strony: 239--260
• Opis fizyczny: Bibliogr. 23 poz., il., schem., tab.

Twórcy

autor

Pacey M.

autor

Patterson E.

autor

James M.

• Department of Mechanical and Marine Engineering, University of Plymouth, Drake Circus, Plymouth, PL4 8AA, UK Department of Mechanical Engineering, University of Sheffield, Mappin Street, Sheffield, S1 3 JD, UK

Bibliografia

• [1] Budiansky, B. and Hutchinson. J. W., 1978, Analysis of Closure in Fatigue Crack Growth, Journal of Applied Mechanics, 45, 267-276
• [2] Donald, J.K., 1999 Introducing the Compliance Ratio Concept for Determining Effective Stress Intensity. International Journal of Fatigue 19 (SI), S191-S195
• [3] Elber, W.. 1970, Fatigue Crack Closure Under Cyclic Tension. Engineering Fracture Mechanics. 2 37-45
• [4] Goldberg, D.E., 1989. Genetic Algorithms in Search Optimization and Machine Learning, Addison-Wesley
• [5] Gungor, S. and Patterson, E.A., 1997, A Photoelastic Determination of Stress Intensity Factors for Corner Cracks in a Bolted Joint, Journal of Offshore Mechanics and Arctic Engineering-Transactions of the AS ME, 119. 276-280
• [6] Irwin, G.R., 1958, Discussion of The Dynamic Stress Distribution Surrounding a Running Crack - A Photoelastic Analysis, Proceedings of the Society for Experimental Mechanics. 16. 93-96
• [7] James, M.N. and Knott, J.P., 1985, An Assessment of Crack Closure and the Extent of the Short Crack Regime in Q1N (HY SO) Steel. Fatigue and Fracture of Engineering Materials A Structures, 8 No. 2. 177-191
• [8] James, M.N., 1997, Some Unresolved Issues with Fatigue Crack Closure - Measurement. Mechanism, and Interpretation Problems. Advances in fracture research Karihaloo BL. et al. editors. Proceedings of the Ninth International Conference on Fracture, Sydney, Australia. 5 Amsterdam: Pergamon Press, 2403-14.35
• [9] Moscato, P.. 1989, On Evolution, Search , Optimization, Genetic Algorithms and Martial Arts: Towards Memetic Algorithms, Caltech Concurrent Computation Program, C3P Report 826
• [10] Muskhelishvili, N.I., 1953, Some Basic Problems of the Mathematical Theory of Elasticity, P. Noordhoff Ltd., Groningen, Holland
• [11] Nelder. J.A. and Mead, R., 1965, A Simplex Method for Function Minimization, Computer Journal. 7, 308-313
• [12] Newman, J.C, Jr., 1981, A Crack-closure Model for Predicting Fatigue Crack Growth under Aircraft Spectral Loading, in Methods and Models for Predicting Fatigue Crack Growth under Random Loading, ASTM STP 748, eds. Chang, J.B. and Hudson. C.M., American Society for Testing and Materials, 53-84
• [13] Nurse, A.D. and Patterson, E.A., 1990, A Photoelastic Technique to Predict the Direction of Edge Crack Extension using Blunt Cracks, International Journal of Mechanical Science, 32, 253-264
• [14] Nurse, A.D. and Patterson, E.A., 1993, Determination of Predominantly Mode II Stress Intensity Factors from Isochromatic Data, Fatigue and Fracture of Engineering Materials and Structures, 16, 1339-1354
• [15] Pacey, M.N., James, M.N. and Patterson, E.A., 1999. A Photoelastic Study of Plasticity Induced Crack Wake Contact Stresses in Polycarbonate Specimens, Proceedings of the Seventh International Fatigue Congress, Beijing, China, 4, 2819-2824
• [16] Pacey, M.N., James, M.N. and Patterson, E.A., 2000, On the Use of Photoelas ticity to Study Crack Growth Mechanisms, Proceedings of the IX SEM Interna, tional Congress on Experimental Mechanics, Orlando, USA, 375-378
• [17] Parker, A.P. 1981, The Mechanics of Fracture and Fatigue, E. & F. N. Spon, London Picon, R., Paris, P., Canas, J. and Marin, J., 1996, A Complete Field Method for Photoelastic Determination of K1 and Kll in General Mixed Mode Fracture Engineering Fracture Mechanics, 51, 506-516
• [18] Sanford. R.J. and Dally, J.W., 1979. A General Method for Determining Mixed Mode Stress Intensity Factors from Isochromatic Fringe Patterns, Engineering Fracture Mechanics, 11, 621-683
• [19] Schroedl, M.A., McGowan, J. J. and Smith, C. W., 1972, An Assessment of Factors Influencing Data obtained by the Photoelastic Stress Freezing Technique for Stress Fields near Crack Tips, Engineering Fracture Mechanics, 4, 801-809
• [20] Srawley, J.E., 1976, Wide Range Stress Intensity Factor Expressions for ASTM E399 Standard Fracture Toughness Specimens, International Journal of Fracture, 12, 475-476
• [21] Suresh, S., 1998, Fatigue of Materials, 2 nd edition, Cambridge University Press, Cambridge
• [22] Vasudevan, A.K., Sadananda, K. and Louat, N., 1992, Reconsideration of fatigue crack closure, Scripta Metallurgica et Materialia, 27, 1673-1678
• [23] Wei, L.-W. and James, M.N., 2000, A Study of Fatigue Crack Closure in Polycarbonate CT Specimens, Engineering Fracture Mechanics, 66, 223