Abstract
The solidification cracking susceptibility of the 7000 series Al-Zn-Mg high strength aluminum alloy has been studied. The cracking behaviour of the specimens were evaluated by a Tig-a-Ma-Jig Varestraint test process under various augmented strain conditions. It has been experimentally observed that the addition of copper decreased the solidification cracking resistivity of the high strength aluminum alloy weld metal by increasing the total crack length (TCL). The effect of the addition of manganese on the solidification cracking behaviour is found to be beneficial by markedly decreasing the solidification cracking susceptibility as the manganese content increases from 0.3 to 0.7%. This enhancement by manganese is understood to be attributed to the reduction of the mushy zone size during the solidification process. The effects of chromium and zirconium additions are also investigated. The weld metal containing zirconium is less sensitive to the solidification cracking than the weld metal containing chromium. In addition, the solidification behaviours of the tested alloys are also investigated and it is found that as the solidification temperature range (ΔT) becomes narrow, the solidified structure becomes more dendritic in its features which is believed to create higher solidification cracking resistance.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
H. Westengen, L. Auran and O. Reiso, Aluminum 57 (1981) 797.
R.E. Sanders, Jr. and E. A. Strake, Jr., Mater. Sci. Eng. 28 (1977) 53.
J. S. Santner, Metall. Trans. 9A (1978) 769.
D. S. Park and S. W. Nam, Metall. Trans. A (Comm.) 25 (1994) 1547.
S. W. Nam, Development of Weldable High Strength Aluminum Alloy(II), KAIST Report, August, 1994, p. 8.
R. Sandstrom, in Proceedings of the 5th International Conference on Aluminum Weldments, Aluminum-Verlag, Dusseldorf, Munich, April 1992, p. 531.
F. Matsuda, Trans. of Japan Welding Research Institute 14 (1985) 99.
K. Nakata, J. of the Japan Welding Society 4 (1986) 115.
M. J. Dvvornak and D. L. Olson, Welding Journal 70 (1993) 271S.
T. Fukui, J. of the JWS 35 (1966) 1122.
S. W. Nam and D. S. Park, High Strength Aluminum Alloy with Good Weldability, U. K. Patent No. GB2246578B, Mar. 1, 1995.
C. D. Lundin, in Proceedings of the 2nd International Conference on Recent Trend in Welding Science and Technology, ASM Tennessee, May 1989, p. 699.
F. Matsuda, Trans. of JWRI 14 2 (1985) 101.
Q. Z. Diao, Metall. Trans. 24A (1993) 963.
S. Kou, Welding Research Council Bulletin 320 (1986) 6.
J. C. Borland, Treatise on Material Science and Technology, Academic Press 1989, 555.
K. Nakata, in Proceedings of the 6th International Conference on Aluminum Weldments, Cleveland, April 1995, p. 387.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Kim, H.T., Nam, S.W. & Hwang, S.H. Study on the solidification cracking behaviour of high strength aluminum alloy welds: Effects of alloying elements and solidification behaviours. JOURNAL OF MATERIALS SCIENCE 31, 2859–2864 (1996). https://doi.org/10.1007/BF00355993
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/BF00355993