Issue 42

D. Rozumek et alii, Frattura ed Integrità Strutturale, 42 (2017) 23-29; DOI: 10.3221/IGF-ESIS.42.03 29 [6] Rozumek, D., Bański, R., Crack growth rate under cyclic bending in the explosively welded steel/titanium bimetals, Materials & Design, 38 (2012) 139-146. [7] Gladskyi, M., Fatemi, A., Notched fatigue behavior including load sequence effects under axial and torsional loadings, International Journal Fracture, 55 (2013) 43-53. [8] Gasiak, G., Robak, G., Simulation of fatigue life of constructional steels within the mixed modes I and III loading, Fatigue & Fracture of Engineering Materials & Structures, 34 (2011) 389-402. [9] Carpinteri, A., Brighenti, R., Part-through cracks in round bars under cyclic combined axial and bending loading, International Journal of Fatigue 18, (1996) 33-39. [10] Spagnoli, A., Carpinteri, A., Ferretti, D., Vantadori, S., An experimental investigation on the quasi-brittle fracture of marble rocks, Fatigue & Fracture of Eng. Mat. & Structures, 39 (2011) 389-402. [11] Rozumek, D., Macha, E., J-integral in the description of fatigue crack growth rate induced by different ratios of torsion to bending loading in AlCu4Mg1, Materialwissenschaft und Werkstofftechnik, 40(10) (2009) 743-749. [12] Yates, J. R., Miller, K. J., Mixed mode (I+III) fatigue thresholds in a forging steel, Fatigue & Fracture of Eng. Mat. & Structures, 12 (1989) 259-270. [13] Pook, L.P., The fatigue crack direction and threshold behaviour of mild steel under mixed mode I and III loading, Int. J. Fatigue, 7 (1985) 21-30. [14] Thum, A., Petersen, C., Swenson, O., Verformung, Spannung und Kerbwirkung. VDI, Düesseldorf, (1960). [15] Rozumek, D., Marciniak, Z., Fatigue crack growth in AlCu4Mg1 under nonproportional bending with torsion loading, Materials Science, 46 ( 2011) 685-694. [16] Lewandowski, J., Rozumek, D., Cracks growth in S355 steel under cyclic bending with fillet welded joint, Theoretical and Applied Fracture Mechanics, 86 (2016) 342-350. [17] Rozumek, D., Marciniak, Z., Control system of the fatigue stand for material tests under combined bending with torsion loading and experimental results, Mechanical Systems and Signal Processing, 22(6) (2008) 1289-1296. [18] Paris, P. C., Erdogan, F., A critical analysis of crack propagations laws, Journal of Basic Engineering, Trans, American Society of Mechanical Engineers, 85 (1963) 528-534. [19] Picard, A. C., The application of 3-dimensional finite element methods to fracture mechanics and fatigue life prediction, Chameleon Press LTD, London, (1986). [20] Chell, G.G., Girvan, E., An Experimental Technique for Fast Fracture Testing in Mixed Mode, Int. J. Fracture, 14 (1978) 81-84. N OMENCLATURE a 0 notch length a active crack length a* passive crack length c crack depth da/dN fatigue crack growth rate along the length dc/dN fatigue crack growth rate along the depth E Young’s modulus K t theoretical stress concentration factor M a amplitude of moments N number of cycles crack growth R load ratio t time  means arctan (M T /M B ) of the ratio of the torsional moment to the bending moment  Poisson’s ratio  u ultimate tensile stress  y yield stress  K eq equivalent stress intensity factor range