Statistical Size Effect in Quasi‐Brittle Structures: I. Is Weibull Theory Applicable?
Publication: Journal of Engineering Mechanics
Volume 117, Issue 11
Abstract
The classical applications of Weibull statistical theory of size effect in quasi‐brittle structures such as reinforced concrete structures, rock masses, ice plates, or tough ceramic parts are being reexamined in light of recent results. After a brief review of the statistical weakest‐link model, distinctions between structures that fail by initiation of macroscopic crack growth (metal structures) and structures that exhibit large macroscopic crack growth prior to failure (quasi‐brittle structures) are pointed out. It is shown that the classical Weibull‐type approach ignores the stress redistributions and energy release due to stable large fracture growth prior to failure, which causes a strong deterministic size effect. Further, it is shown that, according to this classical theory, every structure is equivalent to a uniaxially loaded bar of variable cross section, which means that the mechanics of the failure process is ignored. Discrepancies with certain recent test data on the size effect are also pointed out. Modification of the Weibull approach that can eliminate these shortcomings is left for a subsequent paper.
Get full access to this article
View all available purchase options and get full access to this article.
References
1.
Bažant, Z. P. (1984). “Size effect in blunt fracture: Concrete, rock, metal.” J. Engrg. Mech., ASCE, 110(4), 518–535.
2.
Bažant, Z. P. (1987). “Fracture Energy of Heterogeneous Materials and Similitude,” Preprints, SEM‐RILEM, Conference on Fracture of Concrete and Rock, Houston, TX, S. P. Shah and S. E. Swartz, eds., Soc. for Exper. Mech., 390–402.
3.
Bažant, Z. P. (1988). “Fracture of concrete.” Lecture Notes for Course 720‐D95, Northwestern Univ., Evanston, 111.
4.
Bažant, Z. P., and Sener, S. (1988). “Size effect in pullout tests.” ACI Materials J., 85(5), 347–351.
5.
Bažant, Z. P., and Kazemi, M. T. (1989). “Size effect on diagonal shear failure of beams without stirrups.” Report No. 89‐8/498s, S and T Ctr. on Advanced Cement‐Based Materials, Northwestern Univ., Evanston, 111.
6.
Bažant, Z. P., and Kazemi, M. T. (1990). “Size effect in fracture of ceramics and its use to determine fracture energy and effective process zone length.” J. Am. Ceram. Soc, 73(7), 1841–1853.
7.
Bažant, Z. P., Prat, P. C., and Tabbara, M. T. (1990). “Antiplane Shear Fracture Texts (Mode III.” ACI Materials J., 87(1), 12–19.
8.
Carpinteri, A. (1989). “Decrease of apparent tensile and bending strength with specimen size: Two different explanations based on fracture mechanics.” Int. J. Solids Struct., 25(4), 407–429.
9.
FrÉchet, M. (1927). Ann. Soc. Polon. Mat., (Cracow) 6, 93.
10.
Freudenthal, A. M. (1968). “Statistical approach to brittle fracture.” Fracture—An advanced treatise, H. Liebowitz, ed., Vol. 2, Academic Press, 591–619.
11.
Kani, G. N. J. (1967). “How safe are our large reinforced concrete beams?.” ACI J., March, 64, 128–141.
12.
Kittl, P., and Díaz, G. (1988). “Weibull's fracture statistics, or probabilistic strength of materials: state of the art.” Res. Mechanica, 24, 99–207.
13.
Kittl, P., and Díaz, G. (1989). “Some engineering applications of the probabilistic strength of materials.” Appl. Mech. Rev., 42(11), 108–112.
14.
Kittl, P., and Díaz, G. (1990). “Size effect on fracture strength in the probabilistic strength of materials.” Reliability Engrg. Syst. Saf., Vol. 28, 9–21.
15.
Mihashi, H., and Izumi, M. (1977). “Stochastic theory for concrete fracture.” Cem. Concr. Res., 7, 411–422.
16.
Mihashi, H., and Zaitsev, J. W. (1981). “Statistical nature of crack propagation.” Report to RILEM TC 50‐FMC, 1–21.
17.
Mihashi, H. (1983). “A stochastic theory for fracture of concrete.” Fracture mechanics of concrete, F. H. Wittmann, ed., Elsevier Science Publishers, B. V., Amsterdam, the Netherlands, 301–339.
18.
Petrovic, J. J. (1987). “Weibull statistical fracture theory for the fracture of ceramics.” Metall. Trans. A, 18a, Nov., 1829–1834.
19.
Peirce, F. T. (1926). J. Textile Inst., 17, 355.
20.
Tippett, L. H. C. (1925). Biometrika, 17, 364.
21.
Weibull, W. (1939). “A statistical theory of the strength of materials.” Royal Swedish Academy of Engrg. Sci. Proc, 151, 1–45.
22.
Weibull, W. (1951). “A statistical distribution function of wide applicability.” J. Appl. Mech., 18, 293–297.
23.
Zech, B., and Wittmann, F. H. (1977). “A complex study on the reliability assessment of the containment of a PWR, Part II. Probabilistic approach to describe the behavior of materials.” Trans. 4th Int. Conf. on Structural Mechanics in Reactor Technology, T. A. Jaeger and B. A. Boley, eds., European Communities, Brussels, Belgium, Vol. H, Jl/11, 1–14.
Information & Authors
Information
Published In
Journal of Engineering Mechanics
Volume 117 • Issue 11 • November 1991
Pages: 2609 - 2622
Copyright
Copyright © 1991 ASCE.
History
Published online: Nov 1, 1991
Published in print: Nov 1991
Authors
Metrics & Citations
Metrics
Citations
Download citation
If you have the appropriate software installed, you can download article citation data to the citation manager of your choice. Simply select your manager software from the list below and click Download.