Effects of Electrode Deformation of Resistance Spot Welding on 304 Austenitic Stainless Steel Weld Geometry

Nachimani  Charde

doi:10.15282/jmes.3.2012.2.0024

Authors

Nachimani Charde Department of Mechanical, Material and Manufacturing Engineering, Faculty of Engineering, The University of Nottingham Malaysia Campus, Jalan Broga, 43500 Semenyih, Selangor Darul Ehsan, Malaysia

DOI:

https://doi.org/10.15282/jmes.3.2012.2.0024

Keywords:

Spot welding; electrode deformation; electrode mushrooming.

Abstract

The resistance spot welding process is accomplished by forcing huge amounts of current flow from the upper electrode tip through the base metals to the lower electrode tip, orvice versa or in both directions. A weld joint is established between the metal sheets through fusion, resulting in a strong bond between the sheets without occupying additional space. The growth of the weld nugget (bond between sheets) is therefore determined from the welding current density; sufficient time for current delivery; reasonable electrode pressing force; and the area provided for current delivery (electrode tip). The welding current and weld time control the root penetration, while the electrode pressing force and electrode tips successfully accomplish the connection during the welding process. Although the welding current and weld time cause the heat generation at the areas concerned (electrode tip area), the electrode tips’ diameter and electrode pressing forces also directly influence the welding process. In this research truncated-electrode deformation and mushrooming effects are observed, which result in the welded areas being inconsistent due to the expulsion. The copper to chromium ratio is varied from the tip to the end of the electrode whilst the welding process is repeated. The welding heat affects the electrode and the electrode itself influences the shape of the weld geometry.

References

Aravinthan, A., & Nachimani, C. (2011). Analysis of spot weld growth on mild and stainless steel. Welding Journal, 143-147.

Bower, R. J., Sorensen, C. D., & Eager, T. W. (1990). Electrode geometry in resistance spot welding. Welding Journal, 45-51.

Chang, B. H., & Zhou, Y. (2003). Numerical study on the effect of electrode force in small-scale resistance spot welding. Journal of Materials Processing Technology, 139, 635-641.

Chen, Z., Zhou, Y., & Scotchmer, N. (2005). Coatings on resistance welding electrodes to extend life. SAE International, 1-4.

Hayat, F. (2011). The effects of the welding current on heat input, nugget geometry, and the mechanical and fractural properties of resistance spot welding on Mg/Al dissimilar materials. Materials and Design, 32, 2476-2484.

Mehdi, M. M., & Abadi, M. P. (2010). Correlation between macro/micro structure and mechanical properties of dissimilar resistance spot welds of AISI 304 austenitic stainless steel and AISI 1008 low carbon steel. MJoM (Association of Metallurgical Engineers of Serbia), 16(2): 133-146.

Ozyurek, D. (2008). An effect of weld current and weld atmosphere on the resistance spot weld ability of 304L austenitic stainless steel. Materials and Design, 29(3), 597-603.

Rao, Z. H., Liao, S. M., Tsai, H. L., Wang, P. C., & Stevenson, R. (2009). Mathematical modeling of electrode cooling in resistance spot welding. Welding Journal, 111-119.

Shamsul, J. B., & Hisyam, M. M. (2007).Study of spot welding of austenitic stainless steel type 304. Journal of Applied Sciences Research, 3(11), 1494-1499.

Yeung, K. S., & Thornton, P. H. (1999). Transient thermal analysis of spot welding electrodes. Welding Journal, 1-6.