Issue 33

M.Kurek et alii, Frattura ed Integrità Strutturale, 33 (2015) 302-308; DOI: 10.3221/IGF-ESIS.33.34 308 R EFERENCES [1] ASTM E 739–91, Standard practice for statistical analysis of linearized stress–life (S–N) and strain life fatigue data, in: Annual Book of ASTM Standards, Vol. 03.01, Philadelphia (1999) 614–628. [2] Carpinteri, A., Spagnoli, A., Vantadori, S., Multiaxial fatigue assessment using a simplified critical plane-based criterion, International Journal of Fatigue, 33(8) (2011) 969-976. doi: 10.1016/j.ijfatigue.2011.01.004. [3] Kardas D., Kluger, K., Łagoda, T., Ogonowski, P., Fatigue life under proportional constant amplitude bending with torsion in energy approach basic on aluminium alloy 2017(a), Physicochemical Mechanics of Materials, 4(2008) 68-74, Materials Science, 541-549 [4] Karolczuk, A., Macha, E., A review of critical plane orientations in multiaxial fatigue failure criteria of metallic materials, International Journal Fracture, 134 (2005) 267-304. [5] Kurek, M., Łagoda, T., Comparison of fatigue characteristics for some selected structural materials under bending and torsion, Materials Science, 47(3) (2011) 334-344. [6] Kurek M., Łagoda T., , Estimation of fatigue life of materials with out-of-parallel fatigue characteristics under block loading, Materials Science Forum Trans Tech Publications, Switzerland, 726 (2012) 181-188. [7] Łagoda, T., Ogonowski, P., Criteria of multiaxial random fatigue based on stress, strain and energy parameters of damage in the critical plane, Mat.-wiss. u. Werkstofftech, 36(9) (2005) 429-437. [8] Macha, E., Generalization of fatigue fracture criteria for multiaxial sinusoidal loadings in the range of random loadings, in: Biaxial and Multiaxial Fatigue, EGF 3 (Edited by M.W. Brown and K.J. Miller), Mechanical Engineering Publications, London, (1989) 425–436 [9] Muller, A., Zum Festigkeitsverhalten von mehrachsig stochastisch beanspruchten Gußeisen mit Kugelgraphit und Tempergu, Fraunhofer – Institut fur Betriebsfestigkeit, Darmstadt, (1994). [10] Niesłony, A., Łagoda, T., Walat, K., Kurek, M., Multiaxial fatigue behaviour of AA6068 and AA2017A aluminium alloys under in-phase bending with torsion loading condition, Mat.-wiss. U. Werkstofftech., 45 (2014) 947-952. [11] Pawliczek, R., Badanie wpływu parametrów obciążenia i geometrii karbu na trwałość przy zmiennym zginaniu i skręcaniu, Rozprawa doktorska, Politechnika Opolska, Opole (in Polish) (2001). [12] Walat, K., Łagoda, T., Lifetime of semi ductile materials through the critical plane approach, International Journal of Fatigue, 67 (2014) 73-77. [13] Kluger, K., Łagoda, T., Fatigue life of metallic material estimated according to selected models and load conditions, Journal of Theoretical and Applied Mechanics, 51(3) (2013) 581-592. [14] Sanetra, C., Untersuchungen zum Fetigkeitsvwrhalten bei mehrachsiger Randombeanspruchung unter Biegung und Torsion, Dissertation, Technische Universitat Clausthal, (1991). [15] Walat, K., Kurek, M., Ogonowski, P., Łagoda, T., The multiaxial random fatigue criteria based on strain and energy damage parameters on the critical plane for low-cycle range, Int. J. Fatigue , 37 (2012) 100-111. [16] Kurek, M., Łagoda, T., Fatigue life estimation under cyclic loading including out-of-parallelism of the characteristics, Applied Mechanics and Materials, 104 (2012) 125-132.