Advertisement

Dynamic Fracture

Part of the Solid Mechanics and Its Applications book series (SMIA, volume 123)

Keywords

Stress Intensity Factor Dynamic Fracture Crack Velocity Strain Energy Release Rate Double Cantilever Beam 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

References

  1. 8.1.
    Mott, N.F. (1948) ‘Fracture of metals: Theoretical considerations’, Engineering 165, 16–18.Google Scholar
  2. 8.2.
    Roberts, D.K. and Wells, A.A. (1954) ‘The velocity of brittle fracture’, Engineering 178, 820–821.Google Scholar
  3. 8.3.
    Berry, J.P. (1960) ‘Some kinetic considerations of the Griffith criterion for fracture’, Journal of the Mechanics and Physics of Solids 8, 194–216.Google Scholar
  4. 8.4.
    Dulaney, E.N. and Brace, W.F. (1960) ‘Velocity behavior of a growing crack’, Journal of Applied Physics 31, 2233–2236.Google Scholar
  5. 8.5.
    Kanninen, M.F. (1968) ‘An estimate of the limiting speed of a propagating ductile crack’, Journalof the Mechanics and Physics of Solids 16, 215–228.Google Scholar
  6. 8.6.
    Duffy, A.R., McClure, G.M., Eiber, R.J., and Maxey, W.A. (1969) ‘Fracture design practices for pressure piping’, in Fracture — An Advanced Treatise, Vol. V (ed. H. Liebowitz), Academic Press, pp. 159–232.Google Scholar
  7. 8.7.
    Gdoutos, E.E. (1990) Fracture Mechanics Criteria and Applications, Kluwer Academic Publishers, pp. 234–237.Google Scholar
  8. 8.8.
    Broberg, K.B. (1960) ‘The propagation of a brittle crack’, Arkivfor Fysik 18, 159–192.Google Scholar
  9. 8.9.
    Baker, B.R. (1962) ‘Dynamic stresses created by a moving crack’, Journal of Applied Mechanics, Trans. ASME 29, 449–458.Google Scholar
  10. 8.10.
    Rose, L.R.F. (1976) ‘An approximate (Wiener-Hopf) kernel for dynamic crack problems in linear elasticity and viscoelasticity’, Proceedings of the Royal Society of London A349, 497–521.Google Scholar
  11. 8.11.
    Sih, G.C. (1970) ‘Dynamic aspects of crack propagation’, in Inelastic Behavior of Solids (eds. M.F. Kanninen, W.F. Adler, A.R. Rosenfield and R.I. Jaffee), McGraw-Hill, pp. 607–639.Google Scholar
  12. 8.12.
    Sih, G.C. (ed.) (1977) ‘Mechanics of Fracture, Vol. 4, Elastodynamic Crack Problems’, Noordhoff Int. Publ., The Netherlands, pp. XXXIX–XLIV.Google Scholar
  13. 8.13.
    Irwin, G.R., Dally, J.W., Kobayashi, T., Foumey, W.F.E, Etheridge, M.J., and Rossmanith, H.P. (1979) ‘On the determination of the \(\dot a\)K relationship for birefringent polymers’, Experimental Mechanics 19, 121–128.Google Scholar
  14. 8.14.
    Dally, J.W. (1979) ‘Dynamic photoelastic studies of fracture’, Experimental Mechanics 19, 349–361.Google Scholar
  15. 8.15.
    Rosakis, A.J. and Zehnder, A.T. (1985) ‘On the dynamic fracture of structural metals’, International Journal of Fracture 27, 169–186.Google Scholar
  16. 8.16.
    Bluhm, J.I. (1969) ‘Fracture arrest’, in Fracture — An Advanced Treatise (ed. H. Liebowitz), Academic Press, Vol. 5, pp. 1–63.Google Scholar
  17. 8.17.
    Wells, A. and Post, D. (1958) ‘The dynamic stress distribution surrounding a running crack — A photoelastic analysis’, Proceedings of the Society for Experimental Stress Analysis 16, 69–92.Google Scholar
  18. 8.18.
    Bradley, W.B. and Kobayashi, A.S. (1970) ‘An investigation of propagating cracks by dynamic photoelasticity’, Experimental Mechanics 10, 106–113.Google Scholar
  19. 8.19.
    Kobayashi, A.S. and Chan, C.E. (1976) ‘A dynamic photoelastic analysis of dynamic-tear-test specimen’, Experimental Mechanics 16, 176–181.Google Scholar
  20. 8.20.
    Kobayashi, A.S. and Mall, S. (1978) ‘Dynamic fracture toughness of Homalite 100’, Experimental Mechanics 18, 11–18.Google Scholar
  21. 8.21.
    Rossmanith, H.P. and Irwin, G.R. (1979) ‘Analysis of dynamic isochromatic crack-tip stress pattems’, University of Maryland Report.Google Scholar
  22. 8.22.
    Dally, J.W. and Kobayashi, T. (1979) ‘Crack arrest in duplex specimens’, International Journal of Solids and Structures 14, 121–129.Google Scholar
  23. 8.23.
    Katsamanis, F., Raftopoulos, D., and Theocaris, P.S. (1977) ‘Static and dynamic stress intensity factors by the method of transmitted caustics’, Journal of Engineering Materials and Technology 99, 105–109.Google Scholar
  24. 8.24.
    Theocaris, P.S. and Katsamanis, E (1978) ‘Response of cracks to impact by caustics’, Engineering Fracture Mechanics 10, 197–210.Google Scholar
  25. 8.25.
    Theocaris, P.S. and Papadopoulos, G. (1980) ‘Elastodynamic forms of caustics for running cracks under constant velocity’, Engineering Fracture Mechanics 13, 683–698.Google Scholar
  26. 8.26.
    Rosakis, A.J. (1982) ‘Experimental determination of the fracture initiation and dynamic crack propagation resistance of structural steels by the optical method of caustics’, Ph.D. Thesis, Brown University.Google Scholar
  27. 8.27.
    Rosakis, A.J. and Freund, L.B. (1981) ‘The effect of crack-tip plasticity on the determination of dynamic stress-intensity factors by the optical method of caustics’, Journal of Applied Mechanics, Trans. ASME 48, 302–308.Google Scholar
  28. 8.28.
    Beinert, J. and Kalthoff, J.F. (1981) ‘Experimental determination of dynamic stress intensity factors by shadow patterns’, in Mechanics of Fracture, Vol. 7 (ed. G.C. Sih), Martinus Nijhoff Publ., pp. 281–330.Google Scholar

Copyright information

© Springer 2005

Personalised recommendations