Improvement of Resistance Spot Welding by Surfaces Treatment of AA1050 Sheets

Main Article Content

Qasim Mohammed Doos Al Attaby
Moneer Hammed Al Saadi
Ihsan Kadhom Abbas Al Naim

Abstract

Resistance spot welding (RSW) aluminum alloys has a major problem of inconsistent quality from weld to weld, because of the problems of the non-uniform oxide layer. The high resistivity of the oxide causes strong heat released which influence significantly on the electrode lifetime and the weld quality. Much effort has been devoted experimentally to the study of the sheet surface characteristics for as-received sheet and surface pretreatment sheet by pickling in NaOH and glassblasted with three thicknesses (0.6, 1.0, and 1.5 mm) of AA1050. Three different welding process parameters energy setup as a low, medium, and high were carried. Tensile-shear strength tests were performed to indicate the weld quality. Moreover, microhardness tests, macro/micrographs, and
SEM/EDS examinations were carried out to analyze, compare, and evaluate the effect of surface conditions on the weldability. The as received sheet showed a higher electrical contact resistance because of its thicker and non-uniform oxide layer. In contrast, the glass-blasted sheet showed lower value, since it has a roughest surface, which leads to easy breakdown the oxide layer. The highest average values and least scattering of the maximum load fracture are with treated sheet by
pickling in NaOH, these values are 760, 1193, and 2283 N for 0.6, 1.0, and 1.5 mm sheet thickness respectively for medium input energy. In contrast, the minimum values with glass-blasted sheet are 616, 1008, and 2020 N for 0.6, 1.0, and 1.5 mm sheet. The microhardness profiles of the fusion zone and HAZ is the lower than the base metal for all cases. Numerical simulation with SORPAS® was used to simulate and optimize the process parameters, and it has given good results in prediction when they compared with experiments.

Article Details

How to Cite
“Improvement of Resistance Spot Welding by Surfaces Treatment of AA1050 Sheets” (2013) Journal of Engineering, 19(02), pp. 217–234. doi:10.31026/j.eng.2013.02.05.
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Articles

How to Cite

“Improvement of Resistance Spot Welding by Surfaces Treatment of AA1050 Sheets” (2013) Journal of Engineering, 19(02), pp. 217–234. doi:10.31026/j.eng.2013.02.05.

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References

Brown, D. J., Newton, C. J., and Boomer, D. Optimization and Validation of a Model to Predict the Spot Weldability Parameter lobes for Aluminum Automotive Body Sheet. Advanced Technologies & Processes, IBEC, pp. 100-106, 1995.

Browne, D. J., Chandler, H. W., Evans, J. T., and Wen, J. Computer Simulation of Resistance Spot Welding in aluminum, part one, Welding Journal 74(10), pp. 339-344, 1995.

Browne, D. J., Chandler, H. W., Evans, J. T., James, P. S., Wen, J., and Newton, C. J. Computer Simulation of Resistance Spot Welding in aluminum, part two, Welding Journal 74(12), pp. 417-422, 1995.

Chao, Y. J. Ultimate Strength and Failure Mechanism of RSW Subjected to Tensile, Shear, and combined tensile/Shear Loads. ASME journal of Engineering Materials and Technology, Vol. 125, 125-13, 2003.

Cho, W., Li, and Hu, Design of Experiment Analysis and Weld Lobe Estimation for Aluminum Resistance Spot Welding. Supplement to the Welding Journal, sponsored by the American Welding Society and the Welding Research Council, 2006.

Crinon, E., Evans, J. T., The Effect of Surface Roughness, Oxide Film Thickness and Interfacial Sliding on the Electrical Contact Resistance of Aluminum. Material Science and Engineering Journal, A242, pp. 121-128, 1998.

Dzekster, N. N., and Ismailov, V. V. Some methods for Improving Aluminum Contacts. Proceeding of 36th Annual Holm conference on Electrical Contacts, Illinois Institute of Technology, Chicago III. pp. 518-520, 1990.

Hayat, F. 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, 2011.

Kim, D. C., Park, H. J., Hwang, I. S., Kang, M. J., RSW of Aluminum alloy sheet 5J32 Using SCR type and Inverter Type Power Supplies. International Scientific Journal, Vol. 38, Issue 1, Pages 55-60, 2009.

Ma, C., Chen, D. L., Bhole, S. D., Boudreau, G., Lee, A., Biro, E. Microstructure and Fracture Characteristics of Spot-Welded DP600 Steel. Materials Science and Engineering, 485, 334-346,2008.

Mathers, G. The Welding of Aluminum and its alloys. Book published by Woodhead Publishing Limited, Cambridge CB1 6AH, England, 2002.

Newton, C. J., Browne, D. J., Thornton, M. C., Boober, D. R., and Keay, B. F. The Fundamental of Resistance Spot Welding Aluminum. Sheet Metal Conference VI, Paper E2, 1994.

Patrick, E. P., Auhl, J. R., and Sun, T. S. Understanding the Process Mechanism is Key to

Reliable Resistance Spot Welding Aluminum Auto Body Components. SAE Technical Paper 840291, 1984.

Pederson, K. R. Resistance Welding of Aluminum Alloys. MSc. thesis, DTU, Department of Mechanical Engineering, Denmark, 2010.

Pouranvari, M. Prediction of Failure Mode in AISI 304 Resistance Spot Welds. Association of Metallurgical Engineers of Serbia, AMES, UDC: 621.791.763, PP. 23-29, 2010.

Rashid, M. Some Tribological Influences on the Electrode-Worksheet Interface during Resistance Spot Welding of Aluminum Alloys. Journal of Materials Engineering and Performance, Vol. 20(3), pp. 456-462, 2011.

RWMA, Resistance Welding Process. Resistance Welding Manuals, printed by George H. Buchman,Bridgeport, Nj USA, 2003.

Rnhult, T., Rilby, U., and Olefjord, I. The Surface State and Weldability of Aluminum Alloys. Material Science and Engineering, 42, pp. 329-336, 1980.

Senkara, J., Zhang, H., and Hu, S. J., Expulsion Prediction in Resistance Spot Welding. Welding Research, Welding Journal, pp. 123-132, 2004.

Song, Q., Zhang, W., and Bay, N. An Experimental Study Determines the Electrical Contact Resistance in Resistance Welding. Sponsored by AWS and WRC, Welding Journal, pp. 73-76, 2005.

Studer, F. J. Contact Resistance in Spot Welding. Welding Journal, Vol.18, Iss. 10, pp. 374-380, 1939.

Sun, T. S. Electrode Deterioration Mechanisms in Resistance Spot Welding of Aluminum. Aloa Internal Report No. 53-82-3, 1982.

SWANTEC Software and Engineering ApS. SORPAS®, Version 10.6, www.swantec.com.

Wheeler, M. J., Sheasby, P. G., and Kewley, D. Aluminum Structured Vehicle Technology. A comprehensive approach to vehicle design and manufacturing aluminum, SAE, Technical Paper 870146, 1987.

Williams, N. T. Suggested topics for Future Research in Resistance Welding. Welding in the World 22 (1/2), pp. 28-34, 1984.

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