Issue 46

T. Bounini et alii, Frattura ed Integrità Strutturale, 46 (2018) 1-13; DOI: 10.3221/IGF-ESIS.46.01 13 [8] Chen, C.M. and Kovacevic, R. (2003). Finite Element Modeling Of Friction Stir Welding—Thermal And Thermomechanical Analysis. Science Direct, International Journal Of Machine Tools & Manufacture 43, pp. 1319– 1326. [9] Mishra, R.S. and Ma, Z.Y. (2005). Friction stir welding and processing, Materials Science and Engineering R, 50(1-2), pp. 1-78. [10] Buffa, G., Fratini, L. and Pasta, S. (2009). Residual Stresses In Friction Stir Welding: Numerical Simulation And Experimental Verification, JCPDS-International Centre for Diffraction Data, pp. 444-453 [11] Kambouz, Y., Benguediab, M. and Bouchouicha, B. (2017). Numerical Study of the Mechanical Behavior and Fatigue in a Weld Bead by Friction Stir for a 6082–T6 Aluminum Alloy. Mechanics and Mechanical Engineering, 21(1), pp. 67- 83. [12] Elangovan, K. and Balasubramanian, V. (2007). Influences of pin profile and rotational speed of the tool on the formation of friction stir processing zone in AA2219 aluminium alloy, Material Science and Engineering: A, 459 (1-2), pp. 7-18. [13] Elangovan, K., Balasubramanian, V. and Valliapan, M. (2008). Effect of Tool Pin Profile and Tool Rotational Speed on Mechanical Properties of Friction Stir Welded AA6061 Aluminium Alloy Materials and Manufacturing Processes, 23(3), pp. 251-260. [14] Fernandez, G.J., and Murr, L.E. (2004). Characterization of tool wear and weld optimization in the friction-stir welding of cast aluminum 359+20% SiC metal-matrix composite. Materials Characteization 52(1), pp. 65-75. [15] Beer, F. P., Russell Johnston Jr., E., DeWolf, J. T. and Mazurek, D.F. (2009). Mechanics of materials (5th ed). Mc Graw Hill, p.49.