PSI - Issue 25
Ch.F. Markides et al. / Procedia Structural Integrity 25 (2020) 214–225
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Ch. F. Markides et al., Structural Integrity Procedia 00 (2019) 000 – 000
3. Conclusions Two configurations for the determination of the tensile strength of brittle materials were discussed, aiming to relief limitations of existing configurations. Closed form solutions were obtained for both the critical stress corresponding to the tensile strength and, also, for the respective components of the displacement field. A series of advantages of the configurations introduced were enlightened, related to the very low level of the force required to fracture the specimens (eliminating the risk of parasitic fracture at the loaded areas of the specimens) and, also, to the fact that the stress field at the critical points consists of a single tensile stress component. Of equal importance is the fact that for the configur ations discussed the ratio of the maximum compressive stress versus the maximum tensile one is not a-priori defined but rather it is controllable by adjusting geometrical features of the specimens. This ratio is always smaller than three (the value for the standardized BD test) and, in some cases, it is smaller than one, rendering these configurations suitable even for brittle materials for which the tensile and compressive strength are relatively close to each other. Another crucial aspect is related to the role of the geometry and the specimen’s dimensions: Ignoring the size effect the tensile strength is a material property and its value is independent of the specimen’s dimensions. The criticism made (Hudson, 1969; Hudson et al., 1972) on Hobbs (1964; 1965) expression providing the tensile strength as a function of the CR dimensions (Eq.(2)) is somehow relieved here since Hobbs ’ correlation factor k , now becomes either k (CSRc) or k (CSRt) given apart from ρ , R 2 and c , also, as a function of the P f (CSRc,t) / P f (BD) ratio (Eqs.(22, 23) of the present analysis). It is thus concluded that, eventually, one does not obtain different values for the tensile strength, but rather different fracture loads P f , depending on the test adopted each time. In other words, the final choice is only related to the easier laboratory implementation and the easier preparation of the respective specimens. References Akazawa, S., 1943. Splitting tensile test of cylindrical specimens. J. Japanese Civil Engineering Institute 6(1), 12 – 19. Carneiro, F.L.L.B., 1943. A new method to determine the tensile strength of concrete. Proc. 5 th meeting of the Brazilian association for technical rules, 3d. section, 16 September 1943, 126 – 129 (in Portuguese). Fairhurst, C., 1964. On the validity of the ‘Bra zil ian’ test for brittle materials. Int Int J Rock Mech Min Sci. 1, 535 – 546. Golovin, Kh., 1882. A static problem of the elastic body. Minutes of the Technological Institute, St. Petersburg, 1880-1881, St. Petersburg. Hobbs, D.W., 1964. The tensile strength of rocks. Int J Rock Mech Min Sci. 1, 385 – 396. Hobbs, D.W., 1965. An assessment of a technique for determining the tensile strength of rock. Br J Appl Phys 16(2), 259 – 268. Hondros G., 1959. The e valuation of Poisson’s ratio and the modulus of materials of a low tensile resistance by the Brazilian (Indirect tensile) test with particular reference to concrete. Australian J. of Applied Science 10, 243 – 268. Hooper, J. A. (1971). The failure of glass cylinders in diametral compression. J. Mech. Phys. Solids, 19, pp. 179 – 200. Hudson, J.A., 1969. Tensile strength and the ring test. Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts 6(1), 91 – 97. Hudson, J.A., Brown, E.T., Rummel, F., 1972. The controlled failure of rock discs and rings loaded in diametral compression. Int J Rock Mech Min Sci. 9(2), 241 – 248. Jaeger, J.C., Hoskins, E.R., 1966. Stresses and failure in rings of rock loaded in diametral tension or compression. Br J Appl Phys 17(5), 685 – 692. Kourkoulis S.K., Exadaktylos G.E., Vardoulakis I., 1999. U-notched Dionysos-Pentelicon marble in three point bending: The effect of non linearity, anisotropy and microstructure. Int. J. Fract. 98(3-4), 369 – 392 Kourkoulis, S.K., Markides, Ch.F., 2014. Stresses and displacements in a circular ring under parabolic diametral compression. Int J Rock Mech Min Sci. 71, 272 – 292. Kourkoulis, S.K., Pasiou, E.D., Markides, Ch.F., 2018. Analytical and numerical study of the stress field in a circular semi-ring under combined diametral compression and bending, Frattura ed Integrità Strutturale 13(47), 247 – 265 Kuruppu, M.D., Obara, Y., Ayatollahi, M.R., Chong, K.P., Funatsu. T., 2014. ISRM-suggested method for determining the mode I static fracture toughness using semi-circular bend specimen. Rock Mech. Rock Eng 47(1), 267. Love, A.E.H., 1927. A Treatise on the Mathematical Theory of Elasticity. Cambridge University Press. Markides, Ch.F., Kourkoulis, S.K., 2012. The stress field in a standardized Brazilian disc: the influence of the loading type acting on the actual contact length. Rock Mech. Rock Eng. 45(2), 145 – 158. Markides, Ch.F., Pasiou, E.D., Kourkoulis, S.K., 2018. A preliminary study on the potentialities of the Circular Semi-Ring test. Proc. Struct. Integrity 9, 108 – 115. Markides, Ch.F., Pazis, D.N., Kourkoulis, S.K., 2010. Closed full-field solutions for stresses and displacements in the Brazilian disk under dis tributed radial load. Int J Rock Mech Min Sci 47(2), 227 – 237. Mellor, M, Hawkes, I., 1971. Measurement of tensile strength by diametral compression of discs and annuli. Eng Geol 5(3), 173 – 225. Muskhelishvili, N. I., 1933 and 1963. Some Basic Problems of the Mathematical Theory of Elasticity, Noordhoff, Groningen, The Netherlands. Ripperger, E., Davis, N., 1947. Critical stresses in a circular ring. Trans Am Soc Civil Eng 112(1), 619 – 628 (Paper no 2308). Timoshenko, S.P., Goodier, J.N., 1951 (Timoshenko 1910). Theory of Elasticity, 2 nd edition. Eng. Societies Monographs. McGraw-Hill, New York. Timpe, A. 1905. Probleme der Spannungsverteilung in ebenen Systemen, einfach gelӧst mit Hilf der Airyschen Function. Z . Math. Phys. 52, 348 – 383. Volterra, V., 1907. Sur l' équilibre des corps élastiques multiplement connexes. Annales scientifiques de l' Éqole Normale S upérieure . 24, 401 – 517. Wang, Q.Z., Jia, X.M., Kou, S.Q. et al., 2004. The flattened Brazilian disc specimen used for testing elastic modulus, tensile strength and fracture toughness of brittle rocks: analytical and numerical results. Int J Rock Mech Min Sci. 41(2), 245 – 253.
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