A new approach for fabrication of bulk MMCs using Accumulative Channel-die Compression Bonding (ACCB)
الموضوعات :Alireza Babaei 1 , Hosein Jafarzadeh 2 , V. Zakeri Mehrabad 3
1 - Department of Mechanical Engineering, Tabriz Branch, Islamic Azad University, Tabriz, Iran
2 - Department of Mechanical Engineering, Islamic Azad university, Tabriz branch, Tabriz, Iran
3 - Department of Mechanical Engineering,Tabriz Branch,Islamic Azad University,Tabriz,Iran
الکلمات المفتاحية: mechanical properties, Microstructure, ACCB process, MMCs,
ملخص المقالة :
A new severe plastic deformation (SPD) based technique entitled Accumulative channel-die compression bonding (ACCB) is proposed for the fabrication of high strength multi-layered Al/Cu composites for the first time. In order to primarily demonstrate the capabilities of ACCB in the fabrication of metal matrix composites (MMCs), AA 1050 and pure Cu strips were processed. The primary Al/Cu sandwich was prepared and subsequently 50% thickness reduction was applied per cycle. The experimental results reveal that thickness of Al and Cu layers decreased by increasing ACCB cycles to where the Cu layers started to neck and eventually rupture. An Al/Cu bulk composite was successfully processed with homogeneous distribution of fragmented Cu layers in the aluminum matrix after 6 ACCB cycles (correspond to effective plastic strain of 5.6). The microstructure evolution and mechanical properties of the processed specimens were evaluated at different ACCB cycles. The results show that microhardness, strength and elongation of the ACCB processed composites increase with increase in the number of cycles. The capability of ACCB in processing bulk multilayered MMCs was proved.
- R. Z. Valiev and T. G. Langdon, “Principles of equal-channel angular pressing as a processing tool for grain refinement”, Prog. Mater. Sci., 51 2006, 881-981.
- G. Sakai, Z. Horita and T. G. Langdon, “Grain refinement and superplasticity in an aluminum alloy processed by high-pressure torsion”, Materials Science and Engineering: A, 393, 2005, 344-351.
- M. Shaarbaf and M. R. Toroghinejad, “Nano-grained copper strip produced by accumulative roll bonding process”, Materials Science and Engineering: A, 473, 2008, 28-33.
- G. Faraji, A. Babaei, M. M. Mashhadi and K. Abrinia, “Parallel tubular channel angular pressing (PTCAP) as a new severe plastic deformation method for cylindrical tubes”, Materials Letters, 77, 2012, 82-85.
- G. Faraji and M. M. Mashhadi, “Plastic deformation analysis in parallel tubular channel angular pressing (PTCAP) ”, Journal of Advanced Materials and Processing, 1, 2013, 23-32.
- G. Faraji, F. Reshadi and M. Baniasadi, “A new approach for achieving excellent strain homogeneity in tubular channel angular pressing (TCAP) process”, Journal of Advanced Materials and Processing, 2, 2014, 3-12.
- A. Babaei, G. Faraji, M. M. Mashhadi and M. Hamdi, “Repetitive forging (RF) using inclined punches as a new bulk severe plastic deformation method”, Materials Science and Engineering: A, 558, 2012, 150-157.
- G. Faraji and H. Jafarzadeh, “Accumulative Torsion Back (ATB) Processing as a New Plastic Deformation Technique”, Materials and Manufacturing Processes, 27, 2011, 507-511.
- N. Kamikawa and T. Furuhara, “Accumulative channel-die compression bonding (ACCB): A new severe plastic deformation process to produce bulk nanostructured metals”, Journal of Materials Processing Technology, 213, 2013,
1412-1418.
10. R. Z. Valiev, “Nanostructuring of Metals by Severe Plastic Deformation for Advanced Properties”, Nature Materials, 3, 2004, 511-516.
11. R. Z. Valiev, A. V. Korznikov and R. R. Mulyukov, “Structure and properties of ultrafine-grained materials produced by severe plastic deformation”, Materials Science and Engineering: A, 168, 1993, 141-148.
12. B. A. Movchan and F. D. Lemkey, “Mechanical properties of fine-crystalline two-phase materials”, Materials Science and Engineering: A, 224, 1997, 136-145.
13. R. Jamaati, S. Amirkhanlou, M. R. Toroghinejad and B. Niroumand, “CAR process: A technique for significant enhancement of as-cast MMC properties”, Materials Characterization, 62, 2011,
1228-1234.
14. A. K. Srivastava, K. Yu-Zhang, L. Kilian, J. M. Frigério and J. Rivory, “Interfacial diffusion effect on phase transitions in Al/Mn multilayered thin films”, Journal of Materials Science, 42, 2007, 185-190.
15. S. Amirkhanlou and B. Niroumand, “Effects of reinforcement distribution on low and high temperature tensile properties of Al356/SiCp cast composites produced by a novel reinforcement dispersion technique”, Materials Science and Engineering: A, 528, 2011, 7186-7195.
16. Y. Saito, H. Utsunomiya, N. Tsuji and T. Sakai, “Novel ultra-high straining process for bulk materials—development of the accumulative roll-bonding (ARB) process”, Acta Materialia, 47, 1999, 579-583.
17. X. Sauvage, G. P. Dinda and G. Wilde, “Non-equilibrium intermixing and phase transformation in severely deformed Al/Ni multilayers”, Scripta Materialia, 56, 2007, 181-184.
18. M. Tayyebi and B. Eghbali, “Study on the microstructure and mechanical properties of multilayer Cu/Ni composite processed by accumulative roll bonding”, Materials Science and Engineering: A, 559, 2013, 759-764.
19. M. Eizadjou, H. D. Manesh and K. Janghorban, “Microstructure and mechanical properties of ultra-fine grains (UFGs) aluminum strips produced by ARB process”, Journal of Alloys and Compounds, 474, 2009, 406-415.
20. G. Min, J. M. Lee, S. B. Kang and H. W. Kim, “Evolution of microstructure for multilayered Al/Ni composites by accumulative roll bonding process”, Materials Letters, 60, 2006, 3255-3259.
21. J. Gubicza, N. Q. Chinh, T. Csanádi, T. G. Langdon and T. Ungár, “Microstructure and strength of severely deformed fcc metals”, Materials Science and Engineering: A, 462, 2007, 86-90.
22. X. Huang, N. Kamikawa and N. Hansen, “Strengthening mechanisms in nanostructured aluminum”, Materials Science and Engineering: A, 483–484, 2008, 102-104.
23. R. Jamaati and M. R. Toroghinejad, “Manufacturing of high-strength aluminum/alumina composite by accumulative roll bonding”, Materials Science and Engineering: A, 527, 2010, 4146-4151.
24. A. Mozaffari, H. Danesh Manesh and K. Janghorban, “Evaluation of mechanical properties and structure of multilayered Al/Ni composites produced by accumulative roll bonding (ARB) process”, Journal of Alloys and Compounds, 489, 2010,
103-109.
25. Y. F. Sun, N. Tsuji, H. Fujii and F. S. Li, “Cu/Zr nanoscaled multi-stacks fabricated by accumulative roll bonding”, Journal of Alloys and Compounds, 504, Supplement 1, 2010, S443-S447.
26. W. Wang and R. N. Singh, “Influence of the microstructure on the mechanical properties of Ni/Sn multilayered composites”, Materials Science and Engineering: A, 271, 1999, 306-314.
27. K. T. Park, H. J. Kwon, W. J. Kim and
Y. S. Kim, “Microstructural characteristics and thermal stability of ultrafine grained 6061 Al alloy fabricated by accumulative roll bonding process”, Materials Science and Engineering: A, 316, 2001, 145-152.
28. Z. P. Xing, S. B. Kang and H. W. Kim, “Softening behavior of 8011 alloy produced by accumulative roll bonding process”, Scripta Materialia, 45, 2001, 597-604.
