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8 - Elastic Plastic Fracture Mechanics

Published online by Cambridge University Press:  05 February 2016

Surjya Kumar Maiti
Affiliation:
Indian Institute of Technology, Bombay
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Chapter
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Fracture Mechanics
Fundamentals and Applications
, pp. 202 - 256
Publisher: Cambridge University Press
Print publication year: 2015

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References

8.1 Anand, L. and D.M., Parks. 2004. Mechanics and Materials II, Supplementary notes, Department of Mechanical Engineering, MIT Cambridge, Massachusetts 02139.
8.2 Anderson, T.L. and R.H., Dodds Jr. 1991. ‘Specimen Size Requirements for Fracture Toughness Testing in Ductile-Brittle Transition Region.’ Journal of Testing and Evaluation 19: 123–34.Google Scholar
8.3 Barenblatt, G.I. 1962. ‘The Mathematical Theory of Equilibrium Cracks in Brittle Fracture.’ Advances in Applied Mechanics VII: 55–129.Google Scholar
8.4 Begley, J.A. and J.D., Landes. 1972. ‘The J-integral as a Fracture Criterion’. In Fracture Toughness, Part II, 1–23. Philadelphia: American Society for Testing and Materials [ASTM STP 514].Google Scholar
8.5 Chakrabarty, J. 1987. Theory of Plasticity. New York: McGraw-Hill Book Company.Google Scholar
8.6 Dugdale, D.S. 1960. ‘Yielding of Steel Sheets Containing Slits.’ Journal of Mechanics and Physics of Solids 8: 100–08.CrossRefGoogle Scholar
8.7 Harrison, R.P., K., Loosemoore and I., Milne. 1976. Assessment of Integrity of Structures Containing Crack. Central Electricity Generating Board Report No. R/H/R6, UK.
8.8 Hult, J.A.H. and F. A., McClintock. 1957. ‘Elastic Plastic Stress and Strain Distributions Around Sharp Notches under Repeated Shear’, Vol. 8, 51–58. Proceedings of the 9th International Congress of Applied Mechanics, University of Brussels.
8.9 Hutchinson, J.W. 1968a. ‘Singular Behavior at the End of a Tensile Crack in a Hardening Material.’ Journal of Mechanics and Physics of Solids 16: 13–31.CrossRefGoogle Scholar
8.10 Hutchinson, J.W. 1968b. ‘Plastic Stress and Strain Fields at a Crack Tip.’ Journal of Mechanics and Physics of Solids 16: 337–47.CrossRefGoogle Scholar
8.11 Hutchinson, J.W. 1983. ‘Fundamentals of the Phenomenological Theory of Nonlinear Fracture Mechanics.’ Journal of Applied Mechanics, Transactions of ASME 50: 1042–51.Google Scholar
8.12 Hutchinson, J.W. and P. C., Paris. 1979. ‘Stability Analysis of J-controlled Crack Growth’. In Elastic - Plastic Fracture, 37–64. Philadelphia: American Society for Testing and Materials [ASTM STP 668].Google Scholar
8.13 Kanninen, M.F. and C.H., Popelar. 1985. Advanced Fracture Mechanics. New York: Oxford University Press.Google Scholar
8.14 Kumar, V., M.D., German and C. F., Shih. 1981. An Engineering Approach for Engineering Elastic Plastic Fracture Analysis. Electric Power Research Institute (EPRI) NP-1931, Project 1287-1, Topical Report.
8.15 Landes, J.D. and J. A., Begley. 1972. ‘The Effect of Specimen Geometry on JIC,’ 24–29. Philadelphia: American Society for Testing and Materials [ASTM STP 514].
8.16 Landes, J.D., H., Walker and G. A., Clarke. 1979. ‘Evaluation of Estimation Procedure Used in J-integral Testing’. In Elastic - Plastic Fracture, 266–87. Philadelphia: American Society for Testing and Materials [ASTM STP 668].CrossRefGoogle Scholar
8.17 McClintock, F.A. 1971. ‘Plasticity Aspects of Fracture.’ In Fracture: An Advanced Treatise, Vol. 3, 47–225. New York: Academic Press.Google Scholar
8.18 Mendelson, A. 1968. Plasticity: Theory and Applications. New York: The Macmillan Company.Google Scholar
8.19 Merkle, J.G. and H. T., Corten. 1974. ‘A J-integral Analysis for the Compact Specimen, Considering Axial Force as well as Bending Effects.’ Journal of Pressure Vessel and Technology, Transactions of ASME 96: 286–92.CrossRefGoogle Scholar
8.20 O'Dowd, N.P. and C. F., Shih. 1991. ‘Family of Crack-tip Fields Characterized by a Triaxiality Parameter – I. Structure of Fields.’ Journal of Mechanics and Physics of Solids 39: 898–1015.CrossRefGoogle Scholar
8.21 O'Dowd, N.P. and C. F., Shih. 1992. ‘Family of Crcak-tip Fields Characterized by a Triaxiality Parameter – II. Fracture Applications.’ Journal of Mechanics and Physics of Solids 40: 939–63.CrossRefGoogle Scholar
8.22 Paris, P.C., H., Tada, Z., Zahoor and H., Ernst. 1979. ‘Instability of the Tearing Mode of Elastic Plastic Crack Growth’. In Elastic - Plastic Fracture, 5–36. Philadelphia: American Society for Testing and Materials [ASTM STP 668].Google Scholar
8.23 Rice, J.R. 1975. ‘Elastic Plastic Model for Stable Crack Growth.’ In Proceedings of Cambridge Conference, England, 1973, ed. May, M.J., 14–39. British Steel Corporation Physical Metallurgy Centre Publication.Google Scholar
8.24 Rice, J.R. and G. F., Rosengren. 1968. ‘Plane Strain Deformation Near a Crack Tip in a Power-Law Hardening Material.’ Journal of Mechanics and Physics of Solids 16: 1–12.CrossRefGoogle Scholar
8.25 Rice, J.R., P. C., Paris and J. G., Merkle. 1973. ‘Some Further Results on J-integral Analysis and Estimates’. In Progress in Flaw Growth and Fracture Toughness Testing, 231–245. Philadelphia: American Society for Testing and Materials [ASTM STP 536].Google Scholar
8.26 Ritchie, R.O., J. F., Knott and J. R., Rice. 1973. ‘On the Relationship Between Critical Tensile Stress andFracture Toughness in Mild Steel.’ Journal of Mechanics and Physics of Solids 21: 395–410.CrossRefGoogle Scholar
8.27 Shih, C.F. 1981. ‘Relationship Between the J-integral and the Crack Opening Displacement for Stationary and Extending Crack.’ Journal of Mechanics and Physics of Solids 29: 305–26.CrossRefGoogle Scholar
8.28 Tracy, D.M. 1976. ‘Finite Element Solutions for Crack-tip Behavior in Smallscale Yielding.’ Journal of Engineering Materials and Technology, Transactions of ASME 98: 146–51.Google Scholar
8.29 Wells, A.A. 1961. ‘Unstable Crack Propagation in Metals: Cleavage and Fast Fracture’, 210–30. Proceedings of the Crack Propagation Symposium, College of Aeronautics, Cranfield.Google Scholar
8.30 Williams, M.L. 1957. ‘On Stress Distributions at the Base of a Stationary Crack.’ Journal of Applied Mechanics, Transactions of ASME 24: 109–14.Google Scholar

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