PSI - Issue 16

Roman Chepil et al. / Procedia Structural Integrity 16 (2019) 211–217 Roman Chepil, Olena Stankevych, Orest Ostash1, Bohdan Klym / Structural Integrity Procedia 00 (2019) 000 – 000

217

7

Qylafku, G., Azari, Z., Gjonaj, M., Pluvinage, G., 1998. On the fatigue failure and life prediction of the notched specimens. Materials Science 34, 604  608. Qylafku, G., Azari, Z., Kadi, N., Gjonaj, N., Pluvinage, G., 1999. Application of a new model proposal for the fatigue life prediction on notches and key-seats. International Journal of Fatigue 21, 753  760. Schijve, J., 2009. Fatigue of Structure and Materials. Dordrecht: Springer Science+Business Media, B. V., Netherlands. Socie, D.F., Morrow, J., Chen, W-C., 1979. A procedure of estimating the total fatigue life of notched and cracked members. Engineering Fracture Mechanics 11, 851  859. Stankevych, O., Skalsky, V., 2016. Investigation and identification of fracture types of structural materials by means of acoustic emission analysis. Engineering Fracture Mechanics 164, 24 – 34. Susmel, L., 2008. The theory of critical distances: a review of its applications in fatigue. Engineering Fracture Mechanics 75, 1706  1724. Taylor, D., 1999. Geometrical effects in fatigue: a unifying theoretical model. International Journal of Fatigue 21, 413 – 420. Taylor, D., Bologna, P., Bel Knani, K., 2000. Prediction of fatigue failure location on a component using a critical distance method. International Journal of Fatigue 22, 735 – 742. Vazquez, J., Navarro, C., Dominguez, J., 2010. On the estimation on fatigue life in notches differentiating the phase of crack initiation and propagation. Fatigue & Fracture of Engineering Materials & Structures 33, 22  36. Yu, M.T., DuQuesnay, D.L., Topper T.H., 1991. Notched fatigue behavior of two cold rolled steels. Fatigue & Fracture of Engineering Materials & Structures 14, 89  101.