Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding
Friction stir welding (FSW) is one of the solid state welding coming from a combination of heat and pressure in order to obtain the joining by stated process. However, there is very lack of information regarding to the studies of Bobbin Friction Stir Welding (BFSW). Therefore, this studies are to in...
Saved in:
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English English |
| Published: |
2017
|
| Subjects: | |
| Online Access: | http://eprints.utem.edu.my/id/eprint/22404/1/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding%20-%20Mohammad%20Khairul%20Azmi%20Mohd%20Kassim%20-%2024%20Pages.pdf http://eprints.utem.edu.my/id/eprint/22404/2/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding.pdf |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| id |
my-utem-ep.22404 |
|---|---|
| record_format |
uketd_dc |
| institution |
Universiti Teknikal Malaysia Melaka |
| collection |
UTeM Repository |
| language |
English English |
| advisor |
Sued, Mohammad Kamil |
| topic |
T Technology (General) T Technology (General) |
| spellingShingle |
T Technology (General) T Technology (General) Mohd Kassim, Mohammad Khairul Azmi Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| description |
Friction stir welding (FSW) is one of the solid state welding coming from a combination of heat and pressure in order to obtain the joining by stated process. However, there is very lack of information regarding to the studies of Bobbin Friction Stir Welding (BFSW). Therefore, this studies are to investigate the mechanical properties of thick and thin materials welded focusing on BFSW technique. The material that used for this study was Aluminum Alloy 1100 with the thickness 3mm and 6mm. In the meantime, the design of tool might give a huge contribution to the final welded product. The parameters that has be applied for this study are the spindle speed and welding speed. All of the welding process using CNC Milling Machine. There is only 2 set of parameters that used which are 900 rpm and 310 mm/min for spindle speed and welding speed. The other parameters are 1440 rpm for spindle speed and 190 mm/min for welding speed. The final product are testing by using tensile test, micro hardness, and XRD analysis. Result of this testing shows the properties of the welded materials by applying set of parameters that have been decided. By the end of this studies, thin materials not acquire the suitable parameters since the final product still showing sign of defect such as open tunnel and entry issues. Moreover, thin material are rarely to complete the joining process since specimen tend to broke during experiment. While for thick material, the parameters can be accepted because of the tensile, hardness, and XRD analysis. Future work studies still need to be conducted in order to overcome the problem that occur on thin materials. One of the idea are by studying the influence of tool design in BFSW. |
| format |
Thesis |
| qualification_name |
Master of Philosophy (M.Phil.) |
| qualification_level |
Master's degree |
| author |
Mohd Kassim, Mohammad Khairul Azmi |
| author_facet |
Mohd Kassim, Mohammad Khairul Azmi |
| author_sort |
Mohd Kassim, Mohammad Khairul Azmi |
| title |
Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| title_short |
Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| title_full |
Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| title_fullStr |
Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| title_full_unstemmed |
Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding |
| title_sort |
mechanical properties of aluminium alloy 1100 series thick and thin materials welded using bobbin friction stir welding |
| granting_institution |
Universiti Teknikal Malaysia Melaka |
| granting_department |
Faculty of Manufacturing Engineering |
| publishDate |
2017 |
| url |
http://eprints.utem.edu.my/id/eprint/22404/1/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding%20-%20Mohammad%20Khairul%20Azmi%20Mohd%20Kassim%20-%2024%20Pages.pdf http://eprints.utem.edu.my/id/eprint/22404/2/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding.pdf |
| _version_ |
1747834017999224832 |
| spelling |
my-utem-ep.224042022-03-14T14:46:42Z Mechanical Properties Of Aluminium Alloy 1100 Series Thick And Thin Materials Welded Using Bobbin Friction Stir Welding 2017 Mohd Kassim, Mohammad Khairul Azmi T Technology (General) TN Mining engineering. Metallurgy Friction stir welding (FSW) is one of the solid state welding coming from a combination of heat and pressure in order to obtain the joining by stated process. However, there is very lack of information regarding to the studies of Bobbin Friction Stir Welding (BFSW). Therefore, this studies are to investigate the mechanical properties of thick and thin materials welded focusing on BFSW technique. The material that used for this study was Aluminum Alloy 1100 with the thickness 3mm and 6mm. In the meantime, the design of tool might give a huge contribution to the final welded product. The parameters that has be applied for this study are the spindle speed and welding speed. All of the welding process using CNC Milling Machine. There is only 2 set of parameters that used which are 900 rpm and 310 mm/min for spindle speed and welding speed. The other parameters are 1440 rpm for spindle speed and 190 mm/min for welding speed. The final product are testing by using tensile test, micro hardness, and XRD analysis. Result of this testing shows the properties of the welded materials by applying set of parameters that have been decided. By the end of this studies, thin materials not acquire the suitable parameters since the final product still showing sign of defect such as open tunnel and entry issues. Moreover, thin material are rarely to complete the joining process since specimen tend to broke during experiment. While for thick material, the parameters can be accepted because of the tensile, hardness, and XRD analysis. Future work studies still need to be conducted in order to overcome the problem that occur on thin materials. One of the idea are by studying the influence of tool design in BFSW. 2017 Thesis http://eprints.utem.edu.my/id/eprint/22404/ http://eprints.utem.edu.my/id/eprint/22404/1/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding%20-%20Mohammad%20Khairul%20Azmi%20Mohd%20Kassim%20-%2024%20Pages.pdf text en public http://eprints.utem.edu.my/id/eprint/22404/2/Mechanical%20Properties%20Of%20Aluminium%20Alloy%201100%20Series%20Thick%20And%20Thin%20Materials%20Welded%20Using%20Bobbin%20Friction%20Stir%20Welding.pdf text en validuser https://plh.utem.edu.my/cgi-bin/koha/opac-detail.pl?biblionumber=108991 mphil masters Universiti Teknikal Malaysia Melaka Faculty of Manufacturing Engineering Sued, Mohammad Kamil 1. Aval, H.J., 2015. Influences of pin profile on the mechanical and microstructural behaviors in dissimilar friction stir welded AA6082–AA7075 butt joint. Materials & Design, 67, pp.413-421. 2. Boumerzoug, Z. and Helal, Y., 2017. Friction Stir Welding of Dissimilar Materials Aluminum AL6061-T6 to Ultra Low Carbon Steel. Metals, 7(2), p.42. 3. Bussu, G., and Irving, P. E., 2003. The role of residual stress and heat affected zone properties on fatigue crack propagation in friction stir welded 2024-T351 aluminium joints. International Journal of Fatigue, 25(1), pp.77-88. 4. Cavaliere, P., Nobile, R., Panella, F. W., and Squillace, A., 2006. Mechanical and microstructural behaviour of 2024–7075 aluminium alloy sheets joined by friction stir welding. International Journal of Machine Tools and Manufacture, 46(6), 588- 594. 5. Chen, C.M. and Kovacevic, R., 2003. Finite element modeling of friction stir welding— thermal and thermomechanical analysis. International Journal of Machine Tools and Manufacture, 43(13), pp.1319-1326. 6. Chen, S., Lu, A., Yang, D., Lu, S., Dong, J. and Dong, C., 2013. Analysis on flow pattern of bobbin tool Friction Stir Welding for 6082 Aluminum. In Proceedings of the 1st International Joint Symposium on Joining and Welding, Vol. 6, pp. 353-358. 7. Chinchanikar, S. and Choudhury, S.K., 2015. Machining of hardened steel—experimental investigations, performance modeling and cooling techniques: a review. International Journal of Machine Tools and Manufacture, 89, pp.95-109. 8. Colligan, K.J., O’Donnell, A.K., Shevock, J.W., Smitherman, M.T. and Hostetter, G.J., 2012, May. Friction stir welding of thin aluminium using fixed gap bobbin tools. 9. In 9th International Symposium of Friction Stir Welding, Von Braun Center, Huntsville, Alabama, USA. 10. Dawood, H. I., Mohammed, K. S., Rahmat, A., and Uday, M. B., 2015. Effect of small tool pin profiles on microstructures and mechanical properties of 6061 aluminum alloy by friction stir welding. Transactions of Nonferrous Metals Society of China, 25(9), pp. 2856-2865. 11. Elangovan, K., and Balasubramanian, V., 2008. Influences of tool pin profile and welding speed on the formation of friction stir processing zone in AA2219 aluminium alloy. Journal of Materials Processing Technology, 200(1–3), pp.163-175. 12. Entezami, S.S. and Honarpisheh, M., 2016. A Study on the Hardness of 7075 and 5052 Aluminum Alloys in the Equal Channel Angular Rolling Process. Bulletin de la Société Royale des Sciences de Liège, 85, pp.879-889. 13. Esmaily, M., Mortazavi, N., Osikowicz, W., Hindsefelt, H., Svensson, J. E., Halvarsson, M., Johansson, L. G., 2016. Bobbin and conventional friction stir welding of thick extruded AA6005-T6 profiles. Materials & Design, 108, pp.114-125. 14. Gibson, B.T., Lammlein, D.H., Prater, T.J., Longhurst, W.R., Cox, C.D., Ballun, M.C., Dharmaraj, K.J., Cook, G.E. and Strauss, A.M., 2014. Friction stir welding: process, automation, and control. Journal of Manufacturing Processes, 16(1), pp.56-73. 15. Godiganur, V.S. and Biradar, S., 2014. Comparison of friction stirs welding technique with conventional welding methods. International Journal of Research in Engineering and Technology, 3, pp.572-576. 16. Guillo, M., and Dubourg, L., 2016. Impact & improvement of tool deviation in friction stir welding: Weld quality & real-time compensation on an industrial robot. Robotics and Computer-Integrated Manufacturing, 39, pp.22-31. 17. Guo, N., Fu, Y., Wang, Y., Meng, Q. and Zhu, Y., 2017. Microstructure and mechanical properties in friction stir welded 5A06 aluminum alloy thick plate. Materials & Design, 113, pp.273-283. 18. Hattingh, D.G., Blignault, C., Van Niekerk, T.I. and James, M.N., 2008. Characterization of the influences of FSW tool geometry on welding forces and weld tensile strength using an instrumented tool. Journal of Materials Processing Technology, 203(1), pp.46-57. 19. Heirani, F., Abbasi, A. and Ardestani, M., 2017. Effects of processing parameters on microstructure and mechanical behaviors of underwater friction stir welding of Al5083 alloy. Journal of Manufacturing Processes, 25, pp.77-84. 20. Hejazi, I., and Mirsalehi, S. E., 2016. Effect of pin penetration depth on double-sided friction stir welded joints of AA6061-T913 alloy. Transactions of Nonferrous Metals Society of China, 26(3), pp.676-683. 21. Hilgert, J., Schmidt, H. N. B., dos Santos, J. F., and Huber, N., 2011. Thermal models for bobbin tool friction stir welding. Journal of Materials Processing Technology, 211(2), pp.197-204. 22. Infante, V., Braga, D. F. O., Duarte, F., Moreira, P. M. G., de Freitas, M., and de Castro, P. M. S. T., 2016. Study of the fatigue behaviour of dissimilar aluminium joints produced by friction stir welding. International Journal of Fatigue, 82, Part 2, pp.310-316. 23. Karami, S., Jafarian, H., Eivani, A.R. and Kheirandish, S., 2016. Engineering tensile properties by controlling welding parameters and microstructure in a mild steel processed by friction stir welding. Materials Science and Engineering: A, 670, pp.68-74. 24. Kumar, K. and Kailas, S.V., 2008. The role of friction stir welding tool on material flow and weld formation. Materials Science and Engineering: A, 485(1), pp.367-374. 25. Lammlein, D.H., DeLapp, D.R., Fleming, P.A., Strauss, A.M. and Cook, G.E., 2009. The application of shoulderless conical tools in friction stir welding: An experimental and theoretical study. Materials & Design, 30(10), pp.4012-4022. 26. Liu, G., Murr, L.E., Niou, C.S., McClure, J.C. and Vega, F.R., 1997. Microstructural aspects of the friction-stir welding of 6061-T6 aluminum. Scripta materialia, 37(3), pp.355- 361. 27. McNelley, T.R., Swaminathan, S. and Su, J.Q., 2008. Recrystallization mechanisms during friction stir welding/processing of aluminum alloys. Scripta Materialia, 58(5), pp.349-354. 28. Mehta, K. P., & Badheka, V. J. (2016). Effects of Tool Pin Design on Formation of Defects in Dissimilar Friction Stir Welding. Procedia Technology, 23, pp.513-518. 29. Minton, T.J., 2010. Friction stir welding of commercially available superplastic aluminium (Doctoral dissertation, Brunel University School of Engineering and Design PhD Theses) 30. Mishra, R.S. and Ma, Z.Y., 2005. Friction stir welding and processing. Materials Science and Engineering: R: Reports, 50(1), pp.1-78. 31. Moshwan, R., Yusof, F., Hassan, M.A. and Rahmat, S.M., 2015. Effect of tool rotational speed on force generation, microstructure and mechanical properties of friction stir welded Al–Mg–Cr–Mn (AA 5052-O) alloy. Materials & Design (1980-2015), 66, pp.118-128. 32. Patel, A.K.M., Ghetiya, B.N.D. and Makvana, C.S.J., Influence of Friction Stir Welding Parameters on Tensile Strength of AA8011 Aluminium. Nirma University, Ahmedabad. 33. Piccini, J.M. and Svoboda, H.G., 2015. Effect of the tool penetration depth in Friction Stir Spot Welding (FSSW) of dissimilar aluminum alloys. Procedia Materials Science, 8, pp.868-877. 34. Ramachandran, K.K., Murugan, N. and Kumar, S.S., 2015. Effect of tool axis offset and geometry of tool pin profile on the characteristics of friction stir welded dissimilar joints of aluminum alloy AA5052 and HSLA steel. Materials Science and Engineering: A, 639, pp.219-233. 35. Saeid, T., Abdollah-zadeh, A., and Sazgari, B., 2010. Weldability and mechanical properties of dissimilar aluminum–copper lap joints made by friction stir welding. Journal of Alloys and Compounds, 490(1–2), pp.652-655. 36. Sahu, P. K., Pal, S., Pal, S. K., and Jain, R., 2016. Influence of plate position, tool offset and tool rotational speed on mechanical properties and microstructures of dissimilar Al/Cu friction stir welding joints. Journal of Materials Processing Technology, 235, pp.55-67. 37. Schmidt, H., Hattel, J. and Wert, J., 2003. An analytical model for the heat generation in friction stir welding. Modelling and Simulation in Materials Science and Engineering, 12(1), p.143. 38. Scialpi, A., De Giorgi, M., De Filippis, L.A.C., Nobile, R. and Panella, F.W., 2008. Mechanical analysis of ultra-thin friction stir welding joined sheets with dissimilar and similar materials. Materials & Design, 29(5), pp.928-936. 39. Sued, M.K. and Pons, D.J., 2016. Dynamic Interaction between Machine, Tool, and Substrate in Bobbin Friction Stir Welding. International Journal of Manufacturing Engineering, 2016. 40. Sued, M. K., Pons, D., Lavroff, J., and Wong, E. H., 2014. Design features for bobbin friction stir welding tools: Development of a conceptual model linking the underlying physics to the production process. Materials & Design (1980-2015), 54, pp.632-643. 41. Sued, M.K., 2015. Fixed bobbin friction stir welding of marine grade aluminium. 42. Tavares, S.M.O., Castro, R.A.S., Richter-Trummer, V., Vilaça, P., Moreira, P.M.G.P. and de Castro, P.M.S.T., 2010. Friction stir welding of T-joints with dissimilar aluminium alloys: mechanical joint characterisation. Science and Technology of Welding and Joining, 15(4), pp.312-318. 43. Thomas, W.M., Johnson, K.I. and Wiesner, C.S., 2003. Friction stir welding–recent developments in tool and process technologies. Advanced Engineering Materials, 5(7), pp.485-490. 44. Threadgill, P.L., Ahmed, M.M.Z., Martin, J.P., Perrett, J.G. and Wynne, B.P., 2010. The use of bobbin tools for friction stir welding of aluminium alloys. In Materials Science Forum (Vol. 638, pp. 1179-1184). Trans Tech Publications. 45. Wang, F.F., Li, W.Y., Shen, J., Hu, S.Y. and dos Santos, J.F., 2015. Effect of tool rotational speed on the microstructure and mechanical properties of bobbin tool friction stir welding of Al–Li alloy. Materials & Design, 86, pp.933-940. 46. Zhang, H.J., Wang, M., Zhu, Z., Zhang, X., Yu, T. and Yang, G.X., 2016. Improving the structure-property of aluminum alloy friction stir weld by using a non-shoulder- plunge welding tool. The International Journal of Advanced Manufacturing Technology, 87(1-4), pp.1095-1104. |