Issue 46

W. Song et alii, Frattura ed Integrità Strutturale, 46 (2018) 94-101; DOI: 10.3221/IGF-ESIS.46.10 101 [4] Atzori, B., Lazzarin, P. and Meneghetti, G. (2008). Fatigue strength assessment of welded joints: From the integration of Paris' law to a synthesis based on the notch stress intensity factors of the uncracked geometries, Eng. Fract. Mech., 75, pp. 364-378. [5] Lazzarin, P. and Tovo, R. (1998). A notch intensity factor approach to the stress analysis of welds, Fatigue Fract. Eng. Mater. Struct. 21, pp. 1089-1103. [6] Lazzarin, P., Berto, F., Gomez, F.J. and Zappalorto, M. (2008). Some advantages derived from the use of the strain energy density over a control volume in fatigue strength assessments of welded joints, Int. J. Fatigue 30, pp. 1345-1357. [7] Lazzarin, P., Berto, F. and Zappalorto, M. (2010). Rapid calculations of notch stress intensity factors based on averaged strain energy density from coarse meshes: Theoretical bases and applications, Int. J. Fatigue 32, pp. 1559-1567. [8] Lazzarin, P., Berto, F. and Atzori, B., (2013). A synthesis of data from steel spot welded joints of reduced thickness by means of local SED. Theor Appl Fract Mech., 63, pp. 32-39. [9] Razavi, S.M.J, Ferro, P., Berto, F. and Torgersen, J. (2017). Fatigue strength of blunt V-notched specimens produced by Selective Laser Melting of Ti-6Al-4V, Theoretical and Applied Fracture Mechanics 87. [10] Song, W. and Liu, X. (2018). Fatigue assessment of steel load-carrying cruciform welded joints by means of local approaches. Fatigue Fract. Eng. Mater. Struct, 41. [11] Meneghetti, G. (2008). The peak stress method applied to fatigue assessments of steel and aluminium fillet-welded joints subjected to mode I loading, Fatigue Fract. Eng. Mater. Struct. 31, pp. 346-369. [12] Meneghetti, G., Marchi, A. De and Campagnolo, A. (2016). Assessment of root failures in tube-to-flange steel welded joints under torsional loading according to the Peak Stress Method, Theor. Appl. Fract. Mech. 83, pp. 19-30. [13] Nykänen, T., Li, X., Björk, T. and Marquis, G., (2005). A parametric fracture mechanics study of welded joints with toe cracks and lack of penetration, Eng. Fract. Mech. 72, pp. 1580-1609. [14] Liu, G., Liu, Y. and Huang, Y. (2014). A novel structural stress approach for multiaxial fatigue strength assessment of welded joints, Int. J. Fatigue 63, pp. 171-182. [15] Zong, L., Shi, G., Wang, Y.-Q., Yan, J.-B. and Ding Y. (2017). Investigation on fatigue behaviour of load-carrying fillet welded joints based on mix-mode crack propagation analysis, Archives of Civil and Mechanical Engineering 17, pp. 677-686. [16] Singh, P. J., Achar, D. R. G., Guha, B. and Nordberg, H. (2003). Fatigue life prediction of gas tungsten arc welded AISI 304L cruciform joints with different LOP sizes, International Journal of Fatigue, 25, pp. 1-7. [17] Xing, S., Dong, P. and Threstha, A. (2016). Analysis of fatigue failure mode transition in load-carrying fillet-welded connections, Marine Structures, 46, pp. 102-126. [18] Lazzarin, P., Berto, F., Zappalorto, M. and Meneghetti, G. (2009). Practical application of the N-sif approach in fatigue strength assessment of welded joints, Welding in the World, 53. [19] Feng, L. and Qian X. (2017). A hot-spot energy indicator for welded plate connections under cyclic axial loading and bending, Eng. Struct. 147, pp. 598-612. [20] Saiprasertkit, K., Hanji, T. and Miki, C. (2012). Fatigue strength assessment of load-carrying cruciform joints with material mismatching in low- and high-cycle fatigue regions based on the effective notch concept, Int. J. Fatigue 40, pp. 120-128. [21] Gross, B. and Mendelson, A. (1972). Plane elastostatic analysis of V-notched plates, Int. J. Fract.Mech. 8, pp. 267-276. [22] Lazzarin, P. and Zambardi, R. (2001). A finite-volume-energy based approach to predict the static and fatigue behavior of components with sharp V-shaped notches, Int. J. Fract. 112, pp. 275-298. [23] Meneghetti, G., Marini, D. and Babini, V. (2016). Fatigue assessment of weld toe and weld root failures in steel welded joints according to the peak stress method, Welding in the World, 60, pp. 559-572. [24] Atzori, B., Lazzarin, P. and, Tovo R. (1999). Stress field parameters to predict the fatigue strength of notched components, J. Strain Anal. Eng. Des. 34, pp. 437-453. [25] Lazzarin P., Livieri P., Berto F. and Zappalorto, M. (2008). Local strain energy density and fatigue strength of welded joints under uniaxial and multiaxial loading, Eng. Fract. Mech. 75, pp. 1875-1889.