13th International Conference on Fracture June 16–21, 2013, Beijing, China -10- [7] M. Yilmaz, Failures during the production and usage of steel wires. J Mater Process Technol, 171 (2006) 232–239. [8] G.J. Fowler, The influence of non-metallic inclusions on the threshold behavior in fatigue. Mater Sci Eng, 39 (1979) 121–126. [9] K. Lambrighs, I. Verpoest, B. Verlinden, M. Wevers, Influence of non-metallic inclusions on the fatigue properties of heavily cold drawn steel wires. Procedia Engineering, 2 (2010) 173–181. [10] B. González, Influencia del proceso de fabricación en el comportamiento plástico y en fractura de aceros de pretensado, PhD Thesis, University of Salamanca, Zamora, Spain, 2007. [11] J. Toribio, J.C. Matos, B. González, Micro- and macro-approach to the fatigue crack growth in progressively drawn pearlitic steels at different R-ratios. Int J Fatigue, 31 (2009) 2014–2021. [12] J. Toribio, E. Ovejero, Effect of cumulative cold drawing on the pearlite interlamellar spacing in eutectoid steel. Scripta Mater, 39 (1998) 323–328. [13] J. Toribio, E. Ovejero, Effect of cold drawing on microstructure and corrosion performance of high-strength steel. Mech Time-Depend Mater, 1 (1998) 307–319. [14] A.W. Thompson, J.C. Chesnutt, Identification of a fracture mode: the tearing topography surface. Metall Trans A, 10 (1979) 1193–1196. [15] J.E. Costa, A.W. Thompson, Hydrogen cracking in nominally pearlitic 1045 steel. Metall Trans A, 13 (1982) 1315–1318. [16] J. Toribio, A.M. Lancha, M. Elices, Characteristics of the new tearing topography surface. Scripta Metall Mater, 25 (1991) 2239–2244. [17] A. Sonsöz, A.E. Tekkaya, Service life estimation of extrusion dies by numerical simulation of fatigue-crack-growth. Int J Mech Sci, 38 (1996) 527–538. [18] D.O. Olowokere, D.I. Nwosu, Numerical studies on crack growth in a steel tubular T-joint. Int J Mech Sci, 39 (1997) 859–871. [19] P.C. Paris, F. Erdogan, A critical analysis of crack propagation laws. J Basic Eng, 85D (1963) 528–534. [20] C.S. Shin, C.Q. Cai, Fatigue crack propagation properties from small sized rod specimens. Nucl Eng Des, 236 (2006) 2574–2579. [21] M.A. Astiz, An incompatible singular elastic element for two- and three-dimensional crack problems. Int J Fract, 31 (1986) 105–124. [22] D.L. McDowell, An engineering model for propagation of small cracks in fatigue. Eng Fract Mech, 56 (1997) 357–377. [23] J. Toribio, A. Valiente, Failure analysis of cold drawn eutectoid steel wires for prestressed concrete. Eng Fail Anal, 13 (2006) 301–311.
RkJQdWJsaXNoZXIy MjM0NDE=