Issue 37

M. Kurek et alii, Frattura ed Integrità Strutturale, 37 (2016) 221-227; DOI: 10.3221/IGF-ESIS.37.29 227 [2] Macha, E., Generalization of fatigue fracture criteria for multiaxial sinusoidal loadings in the range of random loading, in: M. Brown, K.J. Miller (Eds.), Biaxial and Multiaxial Fatigue, Mechanical Engineering Publications, London, (1989) 425–436. [3] Carpinteri, A., Spagnoli, A., Vantadori, S. , Multiaxial Assessment Using a Simplified Critical Plane-Based Criterion, Int. J. Fatigue, 33 (2011) 969-976. DOI:10.1016/j.ijfatigue.2011.01.004 [4] 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 (2005) 429-437. DOI: 10.1002/mawe.200500898 [5] Kluger, K., Łagoda, T., Fatigue life of metallic material estimated according to selected models and load conditions, J. Theoret. Appl. Mech., 51 (2013) 581-592. [6] 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. DOI: 10.1016/j.ijfatigue.2011.09.013 [7] 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. [8] Nishihara, T., Kawamoto, M., The Strength of Metals under Combined Alternating Bending and Twisting, Memoirs of the College of Engineering, Kyoto Imperial University, Japan, (1941). [9] Muller, A., Zum Festigkeitsverhalten von mehrachsig stochastisch beanspruchten Gußeisen mit Kugelgraphit und Tempergu, Fraunhofer – Institut fur Betriebsfestigkeit, Darmstadt, (1994). [10] Pawliczek, R., Badanie wpływu parametrów obciążenia i geometrii karbu na trwałość przy zmiennym zginaniu i skręcaniu, Rozprawa doktorska, Politechnika Opolska, Opole (in Polish) (2001). [11] 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. [12] Sanetra, C., Untersuchungen zum Fetigkeitsvwrhalten bei mehrachsiger Randombeanspruchung unter Biegung und Torsion, Dissertation, Technische Universitat Clausthal, (1991). [13] Kohut, M., Łagoda, T., Badania zmęczeniowe mosiądzu MO58 w warunkach proporcjonalnego cyklicznego zginania ze skręcaniem, in: Seweryn, A. (Ed.), III Sympozjum Mechaniki Zniszczenia Materiałów i Konstrukcji, Dział Wydawnictw i Poligrafii Politechniki Białostockiej, Poland (2004). [14] Lee, S.B., A Criterion for Fully Reversed Out of Phase Torsion and Bending, in: Miller, K.J, Brown, M.W. (Eds), Multiaxial fatigue, ASTM STP 853, Philadelphia, USA, (1985) 553-568. [15] Sakane, M., Ohnami, M., Sawada, M., Fracture Modes and Low Cycle Biaxial Fatigue Life at Elevated Temperature, J. of Engineering and Technology 109 (1987) 236-243. DOI:10.1115/1.3225970 [16] Walat, K., Łagoda, T., Lifetime of semi ductile materials through the critical plane approach, Int. J. Fatigue, 67 (2014) 73-77.