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Size and geometry effects on ductile rupture of notched bars in a C-Mn steel: experiments and modelling

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Abstract

The aim of this work was to investigate the effect of specimen size and geometry on ductile fracture of a C-Mn steel with high sulphur content. Uniaxial tensile tests were conducted at 300°C on axisymmetric notched specimens having different sizes and geometries. Geometry effects were studied using specimens with various notch radii, thus inducing different stress triaxiality levels. Size effects were evidenced using homothetic samples having the same geometry. Results show that ductility is reduced on specimens with sharp notches (which is a common observation). As specimen size increases, mean ductility as well as scatter are reduced (showing a clear size effect). In order to predict rupture, locally coupled (post-processing type) and fully coupled (continuum damage mechanics) Finite Element models were used. They are based on the plastic criteria introduced by Gurson and Rousselier. In order to model size effect (decrease of ductility and scatter), initial distribution of inclusion volume fractions, measured by quantitative metallography, was accounted for in the simulations. Comparison of experiments with simulations showed that both model types could predict mean values of ductility and scatter.

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References

  1. J.F. Knott, Fundamentals of Fracture Mechanics, London Butterworths (1973): 176–203.

  2. F.A. McClintock, Plasticity aspects of fracture, in Fracture, H. Liebowitz (ed.) Academic Press, Vol. III, (1971) 47–218.

  3. J.R. Griffiths and D.R.J. Owen, ‘An elastic-plastic analysis for a notched bar in plane strain bending’, Journal of Mechanics and Physics of Solids, 19 (1971) 419–431.

    Article  Google Scholar 

  4. F.M. Beremin, A local criterion for cleavage fracture of a nuclear pressure vessel steel, Metallurgica Transaction 14A, 1983, 2277–2287.

    Google Scholar 

  5. A.S. Argon, J. Im and R. Safoglu, ‘Cavity formation in inclusions in ductile fracture’, Metallurgica Transaction A, 6A, (1975) 825–837.

    Google Scholar 

  6. F.M. Beremin, ‘Cavity formation from inclusion in ductile fracture of A508 steel’, Metallurgica Transaction A, 12A, (1981) 723–731.

    Google Scholar 

  7. L. Devillers Guerville, J. Besson and A. Pineau, Notched fracture toughness of a cast duplex stainless steel: Modelling of experimental scatter and size effect, Nuclear Engineering and Design, 168 (1997) 211–225.

    Article  Google Scholar 

  8. A. Pineau and P. Joly, Local versus global approaches to elastic-plastic fracture mechanics. Application to ferritic steels and a cast duplex stainless steel. Defect Assessment in Components — Fundamentals and Applications, ESIS/EGF9 J.G. Blauel and K.-H. Schwalbe (eds) (1991) Mechanical Engineering Publications, London, 381–414.

  9. C. Betégon and J.W. Hancock, ‘Two parameter characterization of elastic-plastic crack-tip fields’, Journal of Applied Mechanics, 58 (1991) 104–110.

    Google Scholar 

  10. N.P. O'Dowd and C.F. Shih, ‘Two parameter fracture mechanics: theory and applications,’ In: Fracture Mechanics: Twenty-Fourth Volume’, ASTM-STP 1207 J.D. Landes et al. (ed.), American Society for Testing and Materials, (1992) 21–47.

  11. J.D. Landes and D.H. Shaffer, ‘Statistical characterisation of fracture in the transition region’, ASTM-STP 700, (1980) 368–382.

    Google Scholar 

  12. A. Carpinteri, B. Chiaia and G. Ferro, Multifractal scaling law: an extensive application to nominal strength size effect of concrete structures, Politecnico di Torino, dipartimento di ingegneria strutturale, (1995) 1–21.

  13. B. Marini, Effet de taille des éprouvettes sur la résistance à la déchirure ductile, CEA CEREM, Service de Recherches Métallurgiques Appliquées, Internal report, 1992, NT SRMA 92-1997, F.A.5131.

  14. S. Carassou and B. Marini, Effet d'échelle sur la rupture ductile d'un acier type A48, SF2M — Journées d'Automne 1994, Revue de Métallurgie, 9 (1994) 1259.

    Google Scholar 

  15. F. Mudry, Etude de la rupture ductile et de la rupture par clivage d'aciers faiblement alliés, Thesis, Université de Technologie de Compiègne, 1982.

  16. A.L. Gurson, Continuum theory of ductile rupture by void nucleation and growth: Part I — Yield criteria and flow rules for porous ductile media, Journal of Engineering Materials and Technology, 99 (1977) 2–15.

    Google Scholar 

  17. V. Tvergaard, Advance in applied Mechanics, Material failure by void growth to coalescence, Department of Solid Mechanics, The Technical University of Denmark, (1990) 83–147.

  18. G. Rousselier, Ductile fracture models and their potential in local approach of fracture, Nuclear Engineering and Design, 105 (1987) 97–111.

    Article  Google Scholar 

  19. L. Bauvineau, Application de l'approche locale pour la prévision des courbes de résistance à la rupture ductile des aciers, Thesis, Ecole des Mines de Paris, 1996.

  20. R.T. Dehoff, F.N. Rhines, Microscopie quantitative, Masson et Cie, 1972.

  21. A.G. Franklin, Comparison between a quantitative microscope and chemical methods for assessment of non-metallic inclusions, Journal of The Iron and Steel Institute, (1969) 181–186.

  22. GRECO, Physique et Mécanique de l'endommagement, ed. Montheillet, F. Moussy, les Editions de Physique, 1988.

  23. W. Roberts, B. Lehtinen and K.E. Easterling, An in situ SEM study of void development around inclusions in steel during plastic deformation, Acta Metallurgica, 24 (1976) 745–758.

    Article  Google Scholar 

  24. G. Bernard, T. Hersant and F. Molière, Phénoménologie et description quantitative de la rupture ductile en présence, de sulfures allongés, Mémoires Scientifiques, Revue de Métallurgie, 11 (1979) 667–687.

    Google Scholar 

  25. C.A. Berg, Plastic dilation and void interaction, Inelastic behavior of solids, McGraw Hill, (1970) 171–209.

  26. V. Tvergaard and A. Needleman, Analysis of a cup-cone fracture in round tensile bar, Acta Metallurgica, 32 (1984) 157–169.

    Article  Google Scholar 

  27. J. Besson and R. Foerch, Large scale object oriented finite element code design, Computer Methods in Applied Mechanics and Engineering, 142 (1997) 165–187.

    Article  MATH  Google Scholar 

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Authors and Affiliations

  1. Centre des Matériaux, 4MR CNRS 7633, Ecole des Mines de Paris, BP 87, Evry Cedex, 91003, France

    K. Decamp, L. Bauvineau, J. Besson & A. Pineau

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  1. K. Decamp
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  2. L. Bauvineau
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  3. J. Besson
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  4. A. Pineau
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Decamp, K., Bauvineau, L., Besson, J. et al. Size and geometry effects on ductile rupture of notched bars in a C-Mn steel: experiments and modelling. International Journal of Fracture 88, 1–18 (1997). https://doi.org/10.1023/A:1007369510442

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