How to cite this paper
Jain, S., Sharma, N & Gupta, R. (2018). Dissimilar alloys (AA6082/AA5083) joining by FSW and parametric optimization using Taguchi, grey relational and weight method.Engineering Solid Mechanics, 6(1), 51-66.
Refrences
Akbari, M., Aliha, M. R. M., Keshavarz, S. M. E., & Bonyadi, A. (2016). Effect of tool parameters on mechanical properties, temperature, and force generation during FSW. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 1464420716681591.
Aliha, M. R. M., Shahheidari, M., Bisadi, M., Akbari, M., & Hossain, S. (2016). Mechanical and metallurgical properties of dissimilar AA6061-T6 and AA7277-T6 joint made by FSW technique. The International Journal of Advanced Manufacturing Technology, 86(9-12), 2551-2565.
Antony, J. (2001). Simultaneous optimisation of multiple quality characteristics in manufacturing processes using Taguchi's quality loss function. The International Journal of Advanced Manufacturing Technology, 17(2), 134-138.
Bahemmat, P., Haghpanahi, M., Givi, M. K. B., & Seighalani, K. R. (2012). Study on dissimilar friction stir butt welding of AA7075-O and AA2024-T4 considering the manufacturing limitation. The International Journal of Advanced Manufacturing Technology, 59(9-12), 939-953.
Baratzadeh, F., Handyside, A. B., Boldsaikhan, E., Lankarani, H., Carlson, B., & Burford, D. (2011, February). Microstructural and mechanical properties of friction stir welding joints of 6082-T6 with 6063-T6. In Friction stir welding and processing VI. Held during the TMS 2011 Annual Meeting and Exhibition (pp. 229-236).
Baratzadeh, F., Widener, C. A., Lankarani, H. M., & Burford, D. A. (2012). Methods to increase the fatigue life of friction stir lap welds in no-load transfer coupons using a retractable pin tool. Journal of ASTM International, 9(5), 1-16.
Barker, T.B. (1990). Engineering quality by design. New York: Marcel Dekker Inc.
Behnagh, R. A., Besharati Givi, M. K., & Akbari, M. (2012). Mechanical properties, corrosion resistance, and microstructural changes during friction stir processing of 5083 aluminum rolled plates. Materials and Manufacturing Processes, 27(6), 636-640.
Byrne, D.M., & Taguchi, S. (1987). The Taguchi approach to parameter design. Quality Progress, 20 (12), 19-26.
Çaydaş, U., & Hasçalık, A. (2008). Use of the grey relational analysis to determine optimum laser cutting parameters with multi-performance characteristics. Optics & Laser Technology, 40(7), 987-994.
Deng, J. (1982). Control problems of grey systems. System and Control Letters, 1(5), 288-294.
Deng, J. (1989). Introduction to grey system Theory. The Journal of Grey System, 1(1), 1-24.
Esmaeili, A., Besharati Givi, M. K., & Zareie Rajani, H. R. (2012). Experimental investigation of material flow and welding defects in friction stir welding of aluminum to brass. Materials and Manufacturing Processes, 27(12), 1402-1408.
Fukuda, T. (2001). Friction stir welding process. Welding International, 15(8), 611-615.
Gemme, F., Verreman, Y., Dubourg, L., & Jahazi, M. (2010). Numerical analysis of the dwell phase in friction stir welding and comparison with experimental data. Materials Science and Engineering: A, 527(16), 4152-4160.
Gungor, B., Kaluc, E., Taban, E., & Sik, A. (2014). Mechanical, fatigue and microstructural properties of friction stir welded 5083-H111 and 6082-T651 aluminum alloys. Materials & Design, 56, 84-90.
Hassan, A. M., Almomani, M., Qasim, T., & Ghaithan, A. (2012). Effect of processing parameters on friction stir welded aluminum matrix composites wear behavior. Materials and Manufacturing Processes, 27(12), 1419-1423.
Hassan, A. M., Qasim, T., & Ghaithan, A. (2012). Effect of pin profile on friction stir welded aluminum matrix composites. Materials and Manufacturing Processes, 27(12), 1397-1401.
Jangra, K. K., Sharma, N., Khanna, R., & Matta, D. (2016). An experimental investigation and optimization of friction stir welding process for AA6082 T6 (cryogenic treated and untreated) using an integrated approach of Taguchi, grey relational analysis and entropy method. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 230(2), 454-469.
Kandasamy, J., Hussain, M. M., & Rajesham, S. (2012). Heterogeneous friction stir welding: Improved properties in dissimilar aluminum alloy joints through insertion of copper coupled with external heating. Materials and Manufacturing Processes, 27(12), 1429-1436.
Khanna, R., Kumar, A., Garg, M. P., Singh, A., & Sharma, N. (2015). Multiple performance characteristics optimization for Al 7075 on electric discharge drilling by Taguchi grey relational theory. Journal of Industrial Engineering International, 11(4), 459-472.
Kumar, A., & Raju, L. S. (2012). Influence of tool pin profiles on friction stir welding of copper. Materials and Manufacturing Processes, 27(12), 1414-1418.
Kumar, P. (1993). Optimization of process variables affecting the quality of A141% Si alloy casting produced by v-process.
Kundu, J., & Singh, H. (2016). Friction stir welding of dissimilar Al alloys: effect of process parameters on mechanical properties. Engineering Solid Mechanics, 4(3), 125-132.
Kundu, J., & Singh, H. (2017). Friction stir welding process: An investigation of microstructure and mechanical properties of Al Alloy AlMg4. 5Mn joint. Engineering Solid Mechanics, 5(2), 145-154.
Mathers, G. (2002). The welding of aluminium and its alloys. New York: CRC Press.
Mirjalili, A., Serajzadeh, S., Jamshidi Aval, H., & Kokabi, A. H. (2013). Modeling and experimental study on friction stir welding of artificially aged AA2017 plates. Materials and Manufacturing Processes, 28(6), 683-688.
Mohammad Aliha, M. R., Fotouhi, Y., & Berto, F. (2017). Experimental notched fracture resistance study for the interface of Al–Cu bimetal joints welded by friction stir welding. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 0954405416688935.
Okamura, H., & Aota, K. (2004). Joining of dissimilar materials with friction stir welding. Welding international, 18(11), 852-860.
Palanivel, R., Mathews, P. K., Dinaharan, I., & Murugan, N. (2014). Mechanical and metallurgical properties of dissimilar friction stir welded AA5083-H111 and AA6351-T6 aluminum alloys. Transactions of Nonferrous Metals Society of China, 24(1), 58-65.
Palanivel, R., Mathews, P. K., Murugan, N., & Dinaharan, I. (2012). Effect of tool rotational speed and pin profile on microstructure and tensile strength of dissimilar friction stir welded AA5083-H111 and AA6351-T6 aluminum alloys. Materials & Design, 40, 7-16.
Ross, P.J. (1988). Taguchi techniques for quality engineering. New York: McGraw-Hill Book Company.
Roy, R.K. (1990). A primer on Taguchi method. New York: Van Nostr and Reinhold.
Sarsılmaz, F., & Çaydaş, U. (2009). Statistical analysis on mechanical properties of friction-stir-welded AA 1050/AA 5083 couples. The International Journal of Advanced Manufacturing Technology, 43(3), 248-255.
Sharma, N., & Khanna, R. (2011). Optimization of process parameters of cryogenic treated D-3 in WEDM by Taguchi Approach. International Journal of Engineering Research and Applications, 1(3), 546-553.
Sharma, N., Kumar, K., Raj, T., & Kumar, V. (2016). Porosity exploration of SMA by Taguchi, regression analysis and genetic programming. Journal of Intelligent Manufacturing, 1-8.
Shtrikman, M. M., Filatov, A. A., Gel'man, A. A., & Ber, L. B. (2005). Special features of the formation of the joints in dissimilar aluminium alloys D19 and 1420 in the friction welding of linear joints. Welding international, 19(6), 478-483.
Soundararajan, V., Yarrapareddy, E., & Kovacevic, R. (2007). Investigation of the friction stir lap welding of aluminum alloys AA 5182 and AA 6022. Journal of Materials Engineering and Performance, 16(4), 477-484.
Tanaka, S., & Kumagai, M. (2010). Effect of welding direction on joining dissimilar alloys between AA5083 and A6N01 by friction stir welding. Welding International, 24(2), 77-80.
Zna, N., Pomi, I.T., & Zvarov, N. (2011). The tensile behavior of friction-stir-welded dissimilar aluminum alloys. Materiali in Tehnologije, 45(6), 623-626.
Aliha, M. R. M., Shahheidari, M., Bisadi, M., Akbari, M., & Hossain, S. (2016). Mechanical and metallurgical properties of dissimilar AA6061-T6 and AA7277-T6 joint made by FSW technique. The International Journal of Advanced Manufacturing Technology, 86(9-12), 2551-2565.
Antony, J. (2001). Simultaneous optimisation of multiple quality characteristics in manufacturing processes using Taguchi's quality loss function. The International Journal of Advanced Manufacturing Technology, 17(2), 134-138.
Bahemmat, P., Haghpanahi, M., Givi, M. K. B., & Seighalani, K. R. (2012). Study on dissimilar friction stir butt welding of AA7075-O and AA2024-T4 considering the manufacturing limitation. The International Journal of Advanced Manufacturing Technology, 59(9-12), 939-953.
Baratzadeh, F., Handyside, A. B., Boldsaikhan, E., Lankarani, H., Carlson, B., & Burford, D. (2011, February). Microstructural and mechanical properties of friction stir welding joints of 6082-T6 with 6063-T6. In Friction stir welding and processing VI. Held during the TMS 2011 Annual Meeting and Exhibition (pp. 229-236).
Baratzadeh, F., Widener, C. A., Lankarani, H. M., & Burford, D. A. (2012). Methods to increase the fatigue life of friction stir lap welds in no-load transfer coupons using a retractable pin tool. Journal of ASTM International, 9(5), 1-16.
Barker, T.B. (1990). Engineering quality by design. New York: Marcel Dekker Inc.
Behnagh, R. A., Besharati Givi, M. K., & Akbari, M. (2012). Mechanical properties, corrosion resistance, and microstructural changes during friction stir processing of 5083 aluminum rolled plates. Materials and Manufacturing Processes, 27(6), 636-640.
Byrne, D.M., & Taguchi, S. (1987). The Taguchi approach to parameter design. Quality Progress, 20 (12), 19-26.
Çaydaş, U., & Hasçalık, A. (2008). Use of the grey relational analysis to determine optimum laser cutting parameters with multi-performance characteristics. Optics & Laser Technology, 40(7), 987-994.
Deng, J. (1982). Control problems of grey systems. System and Control Letters, 1(5), 288-294.
Deng, J. (1989). Introduction to grey system Theory. The Journal of Grey System, 1(1), 1-24.
Esmaeili, A., Besharati Givi, M. K., & Zareie Rajani, H. R. (2012). Experimental investigation of material flow and welding defects in friction stir welding of aluminum to brass. Materials and Manufacturing Processes, 27(12), 1402-1408.
Fukuda, T. (2001). Friction stir welding process. Welding International, 15(8), 611-615.
Gemme, F., Verreman, Y., Dubourg, L., & Jahazi, M. (2010). Numerical analysis of the dwell phase in friction stir welding and comparison with experimental data. Materials Science and Engineering: A, 527(16), 4152-4160.
Gungor, B., Kaluc, E., Taban, E., & Sik, A. (2014). Mechanical, fatigue and microstructural properties of friction stir welded 5083-H111 and 6082-T651 aluminum alloys. Materials & Design, 56, 84-90.
Hassan, A. M., Almomani, M., Qasim, T., & Ghaithan, A. (2012). Effect of processing parameters on friction stir welded aluminum matrix composites wear behavior. Materials and Manufacturing Processes, 27(12), 1419-1423.
Hassan, A. M., Qasim, T., & Ghaithan, A. (2012). Effect of pin profile on friction stir welded aluminum matrix composites. Materials and Manufacturing Processes, 27(12), 1397-1401.
Jangra, K. K., Sharma, N., Khanna, R., & Matta, D. (2016). An experimental investigation and optimization of friction stir welding process for AA6082 T6 (cryogenic treated and untreated) using an integrated approach of Taguchi, grey relational analysis and entropy method. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 230(2), 454-469.
Kandasamy, J., Hussain, M. M., & Rajesham, S. (2012). Heterogeneous friction stir welding: Improved properties in dissimilar aluminum alloy joints through insertion of copper coupled with external heating. Materials and Manufacturing Processes, 27(12), 1429-1436.
Khanna, R., Kumar, A., Garg, M. P., Singh, A., & Sharma, N. (2015). Multiple performance characteristics optimization for Al 7075 on electric discharge drilling by Taguchi grey relational theory. Journal of Industrial Engineering International, 11(4), 459-472.
Kumar, A., & Raju, L. S. (2012). Influence of tool pin profiles on friction stir welding of copper. Materials and Manufacturing Processes, 27(12), 1414-1418.
Kumar, P. (1993). Optimization of process variables affecting the quality of A141% Si alloy casting produced by v-process.
Kundu, J., & Singh, H. (2016). Friction stir welding of dissimilar Al alloys: effect of process parameters on mechanical properties. Engineering Solid Mechanics, 4(3), 125-132.
Kundu, J., & Singh, H. (2017). Friction stir welding process: An investigation of microstructure and mechanical properties of Al Alloy AlMg4. 5Mn joint. Engineering Solid Mechanics, 5(2), 145-154.
Mathers, G. (2002). The welding of aluminium and its alloys. New York: CRC Press.
Mirjalili, A., Serajzadeh, S., Jamshidi Aval, H., & Kokabi, A. H. (2013). Modeling and experimental study on friction stir welding of artificially aged AA2017 plates. Materials and Manufacturing Processes, 28(6), 683-688.
Mohammad Aliha, M. R., Fotouhi, Y., & Berto, F. (2017). Experimental notched fracture resistance study for the interface of Al–Cu bimetal joints welded by friction stir welding. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 0954405416688935.
Okamura, H., & Aota, K. (2004). Joining of dissimilar materials with friction stir welding. Welding international, 18(11), 852-860.
Palanivel, R., Mathews, P. K., Dinaharan, I., & Murugan, N. (2014). Mechanical and metallurgical properties of dissimilar friction stir welded AA5083-H111 and AA6351-T6 aluminum alloys. Transactions of Nonferrous Metals Society of China, 24(1), 58-65.
Palanivel, R., Mathews, P. K., Murugan, N., & Dinaharan, I. (2012). Effect of tool rotational speed and pin profile on microstructure and tensile strength of dissimilar friction stir welded AA5083-H111 and AA6351-T6 aluminum alloys. Materials & Design, 40, 7-16.
Ross, P.J. (1988). Taguchi techniques for quality engineering. New York: McGraw-Hill Book Company.
Roy, R.K. (1990). A primer on Taguchi method. New York: Van Nostr and Reinhold.
Sarsılmaz, F., & Çaydaş, U. (2009). Statistical analysis on mechanical properties of friction-stir-welded AA 1050/AA 5083 couples. The International Journal of Advanced Manufacturing Technology, 43(3), 248-255.
Sharma, N., & Khanna, R. (2011). Optimization of process parameters of cryogenic treated D-3 in WEDM by Taguchi Approach. International Journal of Engineering Research and Applications, 1(3), 546-553.
Sharma, N., Kumar, K., Raj, T., & Kumar, V. (2016). Porosity exploration of SMA by Taguchi, regression analysis and genetic programming. Journal of Intelligent Manufacturing, 1-8.
Shtrikman, M. M., Filatov, A. A., Gel'man, A. A., & Ber, L. B. (2005). Special features of the formation of the joints in dissimilar aluminium alloys D19 and 1420 in the friction welding of linear joints. Welding international, 19(6), 478-483.
Soundararajan, V., Yarrapareddy, E., & Kovacevic, R. (2007). Investigation of the friction stir lap welding of aluminum alloys AA 5182 and AA 6022. Journal of Materials Engineering and Performance, 16(4), 477-484.
Tanaka, S., & Kumagai, M. (2010). Effect of welding direction on joining dissimilar alloys between AA5083 and A6N01 by friction stir welding. Welding International, 24(2), 77-80.
Zna, N., Pomi, I.T., & Zvarov, N. (2011). The tensile behavior of friction-stir-welded dissimilar aluminum alloys. Materiali in Tehnologije, 45(6), 623-626.