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HomeKey Engineering MaterialsKey Engineering Materials Vols. 264-268Fictitious Crack Modeling of the Fracture of a...

Fictitious Crack Modeling of the Fracture of a Refractory Ceramic: Fitting through Experimental Measurements of the Displacement Field around the Fracture Process Zone

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Euro Ceramics VIII

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Periodical:

Key Engineering Materials (Volumes 264-268)

Pages:

1759-1762

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.264-268.1759

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Online since:

May 2004

Authors:

Emilio Jiménez-Piqué, A. Dortmans, G. de With

Keywords:

Fictitious Crack Model, Fracture Process Zone FPZ, Model Materials, Refractory Ceramics

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© 2004 Trans Tech Publications Ltd. All Rights Reserved

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[1] Hillerborg, A.: Int. J. Fract. Vol 51 (1991) p.95.

[2] Duan,K. Mai, Y. -W. and Cotterell, B.: J. Eur. Ceram. Soc. Vol 15 (1995), p.1061.

[3] Hillerborg, A, Modéer, M and Petersson, P-E.: Cem. & Conc. Res. Vol 6 (1976) p.773.

[4] Chu, T.C., Ranson, W.F., Sutton, M.A. and Peters, W.H.: Exp. Mech. Vol 25 (1985) p.232.

[5] Bruck, H.A., McNeil, Sutton, M.A. and Peters, W.H.: Exp. Mech. Vol 29(3) (1989) p.261.

[6] E. Jimenez-Pique, A. Dortmans and G. de With. submitted to Acta Mater.

[7] Sphinx Technical Ceramics. Brochure (1997).

[8] Vogel, D.: Materials Mechanics, Fracture Mechanics, Micro Mechanics. (Winkler, T., Schubert, A. (eds. ) Berlin, Germany, 1999, p.161).

[9] Carpinteri, A., Colombo, G., Ferrara, G. and Giuseppeti, G.: SEM/RILEM. International Conference on fracture on concrete and rock., Houston, USA (1987) SEM/RILEM, p.131.

[10] van Gils, M.: Quasi-brittle fracture of ceramics. Ph.D. thesis. Eindhoven University of Technology, Eindhoven, The Netherlands (1997).

[11] van Gils, M. A. J, Dortmans, L.J.M. G, de With, G., Brekelmans and W.A.M., de Vree, J.H.P.: Int. J. Fract. Vol 75 (1996).