Issue 50

O. Plekhov et alii, Frattura ed Integrità Strutturale, 50 (2019) 1-8; DOI: 10.3221/IGF-ESIS.50.01 8 [12] Hammouda M.M.I., Fayed A.S., Sallam H.E.M. (2004). Stress intensity factors of a central slant crack with frictional surfaces in plates with biaxially loading, Int. J.Fract, 129, pp. 141-148. [13] Hammouda M.M.I., Fayed A.S., Sallam H.E.M. (2003). Simulation of mixed mode I/II cyclic deformation at the tip of a short kinked inclined crack with frictional surfaces. J. of Fatigue, 25(8), pp. 743-753. [14] Hammouda M.M.I., Fayed A.S., Sallam H.E.M. (2003). Stress intensity factors of a shortly kinked slant central crack with frictional surfaces in uniaxially loaded plates, J. of Fatigue, 25(4), pp. 283-298. [15] Hammouda M.M.I., Fayed A.S., Sallam H.E.M. (2002). Mode II stress intensity factors for central slant cracks with frictional surfaces in uniaxially compressed plates, J. of Fatigue, 24(12), pp. 1213-1222. [16] Bever M.B., Holt D.L., Titchener A.L. (1973). The stored energy of cold work, Progress in Materials Science, 17, pp. 5- 177. [17] Iziumova A., Vshivkov A., Plekhov O. (2016). The study of the effect of energy dissipation at fatigue crack tip on its propagation rate. 13th Quantitative Infrared Thermography Conference. Gdańsk, Pologne, paper 101.