Investigation of weld defects in friction-stir welding and fusion welding of aluminium alloys
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Annette, O. B. (2007). Friction stir welding. In AWS welding handbook part 2 (pp. 211–261). Miami, Florida: American Welding Society (AWS).
Arbegast, J., 2003. Modeling friction stir joining as a metalworking process. In: Hot deformation of aluminum alloys III. s.l.:The Minerals, Metals, and Materials Society, 1, 311-324.
Bo, L., Yifu, S., & Weiye, H. (2011). The study on defects in aluminum 2219-T6 thick butt friction stir welds with the application of multiple non-destructive testing methods. Materials and Design, 32, 2073–2084.
Cao, X., Wallace, W., Immarigeon, J., & Poon, C. (2003). Research in laser welding of wrought aluminum alloys I. Laser welding processes. Materials and Manufacturing Process, 18(1), 1–22.
Chang, C., et al. (2010). Effect of laser welding on properties of dissimilar joint of Al-Mg-Si and Al-Mn aluminum alloys. Material Science Technology, 26(3), 276–282.
Chong, P., Liu, Z., Skeldon, P., & Thompson, G. (2003). Corrosion behaviour of laser surface melted aluminium alloy in the T6 and T451 tempers. The Journal of Corrosion Science and Engineering, 6, 12.
Cicala, E., et al. (2005). Hot cracking in Al–Mg–Si alloy laser welding—operating parameters and their effects. Materials Science and Engineering A, 395, 1–9.
Courbiere, M., 2008. Welding aluminum alloys. In: R. Blondeau, ed. Metallurgy and mechanics of welding. s.l.: John Wiley and Sons, p. 512.
Crawford, R., et al. (2006). Experimental defect analysis and force prediction simulation of high weld pitch friction stir welding. Science and Technology of Welding and Joining, 11(6), 657–665.
Cross, C. E., Olson, D. L., & Liu, S. (2003). Handbook of aluminium: aluminum welding. New York: Marcel Dekker.
Dausinger, F., Chen, X., Fujioka, T. & Matsunawa, A., 2000. Proceedings of the SPIE-high-power lasers in manufacturing. Osaka, Japan, s.n.
Di, S., Yang, X., Fang, X., & Luan, G. (2007). The influence of zigzag curve defect on the fatigue properties of friction stir welds in 7075-T6 al alloy. Materia Chemistry and Physics, 104, 244–248.
Dickerson, P. (1998). Weld discontinuities—causes and cures. The Welding Journal, 77(6), 37–42.
Duley, W. (1998). Laser welding. New York: Wiley-Interscience Publishing.
Dursun, T., & Soutis, C. (2013). Recent developments in advanced aircraft aluminium alloys. Materials and Design, 56, 862–871.
Grujicic, M., et al. (2010). Modeling of AA5083 material-microstructure evolution during butt friction stir welding. Journal of Materials Engineering and Performance, 19(5), 672–684.
Guo, H., Hub, J., & Tsai, H. (2009). Formation of weld crater in GMAW of aluminum alloys. International Journal of Heat and Mass Transfer, 52(23–24), 5533–5546.
Hu, B., & Richardson, IM. (2004). Hybrid laser/GMA welding aluminium alloy 7075. In IIW (Ed.), IIW Doc. IV-869-04, Proceedings 57th Annual Assembly of the International Institute of Welding (IIW), IIW Commission IV "Power Beam Processes" (pp. 1-11). Osaka, Japan: IIW
Katayama, S. (2005). New development in laser welding. In New developments in advanced welding. Cambridge England: Woodhead Publishing Limited.
Katayama, S., Nagayama, H., Mizutani, M., & Kawahito, Y. (2009). Fibre laser welding of aluminium alloy. Welding International, 23(10), 744–752.
Katayama, S., Kawahitoa, Y., & Mizutania, M. (2010). Elucidation of laser welding phenomena and factors affecting weld penetration and welding defects. Physics Procedia, 5(B), 9–17.
Kawahito, Y., Mizutani, M., & Katayama, S. (2007). Elucidation of high-power fiber laserwelding phenomena of stainless steel and effect of factors on weld geometry. Journal of Applied Physics, 40(19), 5854.
Keivani, R., et al. (2013). Effects of pin angle and preheating on temperature distribution during friction stir welding operation. Transactions of Non Ferous Metals Society of China, 23, 2708–2713.
Kerr, H., & Katoh, M. (1987). Investigation of heat-affected zone cracking of GMA welds of Al–Mg–Si alloys using the varestraint test. Welding Journal, 66, 251–259.
Kou, S. (2003). Welding metallurgy. New Jersey: John Wiley and Sons.
Krishnan, K. (2002). On the formation of onion rings in friction stir welds. Materials Science and Engineering A, 327(2), 246–251.
Kumar, K., & Satish Kailas, V. (2008). The role of friction stir welding tool on material flow and weld formation. Materials Science and Engineering A, 485(1–2), 367–374.
Kyselica, S. (1987). High–frequency reversing arc switch for plasma welding of aluminum. Welding Journal, 19, 31–35.
Lawrence, J., Pou, J., Low, D. K. Y., & Toyserkani, E. (2010). Advances in laser materials processing. Washington, DC: Woodhead Publishing Ltd.
Lu, Z., Evans, W., Praker, J., & Birley, S. (1996). Simulation of microstructure and liquation cracking in 7017 aluminum alloy. Material Science Engineering A, 220(1–2), 1–7.
Matsunawa, A., Kim, J., & Seto, N. (1998). Dynamics of keyhole and molten pool in laser welding. Journal of Laser Applications, 10, 247.
Matsunawa, A. et al., 2000. Dynamics of keyhole and molten pool in high-power CO2 laser welding. Osaka, Japan, s.n.
Menga, W., et al. (2014). Porosity formation mechanism and its prevention in laser lap welding for T-joints. Journal of Materials Processing Technology, 214(8), 1658–1664.
Mishra, R., & Ma, Z. (2005). Friction stir welding and processing. Materials Science and Engineering R, 50, 1–78.
Nandan, R., DebRoy, T., & Bhadeshia, H. (2008). Recent advances in friction-stir welding—process, weldment structure and properties. Progress in Material Science, 53(6), 980–1023.
Ogura, T., et al. (2012). Partitioning evaluation of mechanical properties and the interfacial microstructure in a friction stir welded aluminum alloy/stainless steel lap joint. Scripta Materialia, 66(8), 531–534.
Peel, M., Steuwer, A., Preuss, M., & Withers, P. (2003). Microstructure, mechanical properties and residual stresses as a function of welding speed in AA5083 friction stir welds. Acta Materialia, 51(16), 4791–4801.
Pereira, M., Taniguchi, C., Brandi, S., & Machida, S. (1994). Analysis of solidification cracks in welds of Al–Mg–Si A6351 type alloy welded by high frequency pulsed TIG process. Journal of the Japan Welding Society, 12(3), 342–350.
Quinn, T. (2002). Process sensitivity of GMAW: aluminum vs. steel. Welding Journal, 4, 554–60s.
Ramasamy, S., & Albright, C. (2000). CO2 and Nd:YAG laser beam welding of 6111-T4 aluminum alloy for automotive application. Journal of Laser Applications, 12, 101.
Regis, B. (2008). Metallurgy and mechanics of welding. France: John Wiley and Sons.
Runnerstam, O., & Persson, K. (1995). The importance of a good quality gas shield. Svetsaren, 50(3), 24–27.
Sakiyama, T., et al. (2013). Dissimilar metal joining technologies for steel sheet and aluminum alloy sheet in auto body. Futtsu, Chiba: Nippon Steel Technical Report.
H.L., Saunders. (1997). Welding Aluminum: Theory and Practice, 3rd ed., The Aluminum Association, pp. 1.2–9.5.
Schneider, J., Beshears, R., & Nunes, A. (2006). Interfacial sticking and slipping in the friction stir welding process. Material Science Engineering A, 435–436, 297–304.
Seto, N., Katayama, S., & Matsunawa, A. (2000). High-speed simultaneous observation of plasma and keyhole behavior during high power CO2 laser welding: effect of shielding gas on porosity formation. Journal of Laser Applications, 12, 245.
Thomas, W. et al., 1991. Friction stir welding. England, Patent No. PCT/GB92102203.
Tu, J., & Paleocrassas, A. (2011). Fatigue crack fusion in thin-sheet aluminum alloys AA7075-T6 using low-speed fiber laser welding. Journal of Materials Processing Technology, 211(1), 95–102.
Wanjara, P., Monsarrat, B., & Larose, S. (2013). Gap tolerance allowance and robotic operational window for friction stir butt welding of AA6061. Journal of Materials Processing Technology, 213, 631–640.
Whitaker, I., Mccartney, D., Calder, N., & Steen, W. (1993). Microstructural characterization of CO2 laser welds in the Al–Li based alloy 8090. Journal of Material and Science, 28, 5469–5478.
Xiaopeng, H., Yang, X., Cui, L., & Zhou, G. (2014). Influences of joint geometry on defects and mechanical properties of friction stir welded AA6061-T4 T-joints. Materials and Design, 53, 106–117.
Zhao, Y., Zhou, L., Wang, Q., Yan, K., & Zou, J. (2014). Defects and tensile properties of 6013 aluminum alloy T-joints by friction stir welding. Materials and Design, 57, 146–155.