New-emerging approach for fabrication of near net shape aluminum matrix composites/nanocomposites: Ultrasonic additive manufacturing
Journal of Ultrafine Grained and Nanostructured Materials
مقاله 7 ، دوره 52، شماره 2 ، اسفند 2019، صفحه 188-196 787.26 K )
نوع مقاله: Research Paper
شناسه دیجیتال (DOI): 10.22059/jufgnsm.2019.02.07 نویسندگان
Mir Saman Safavi* 1 Abolfazl Azarniya 2 Mohammad Farshbaf Ahmadipour 3 Mogalahalli Venkatesh Reddy 4 1 Faculty of Materials Engineering, Research Center for Advanced Materials, Sahand University of Technology, Tabriz, Iran.2 Department of Materials Science and Engineering, Sharif University of Technology, Tehran, Iran. Department of Materials Science and Engineering, National University of Singapore, Singapore.3 Department of Materials Science and Engineering, Sharif University of Technology, Tehran, Iran.4 Department of Materials Science and Engineering, National University of Singapore, Singapore. Center of Excellence in Transportation Electrification and Energy Storage (CETEES), Hydro-Quebec, 1806, Lionel-Boulet Blvd., Varennes, QC J3X 1S1, Canada.چکیده Recently, high-performance lightweight materials with outstanding mechanical properties have opened up their way to some sophisticated industrial applications. As one of these systems, aluminum matrix composites/nanocomposites (AMCs) offer an outstanding combination of relative density, hardness, wear resistance, and mechanical strength. Until now, several additive manufacturing methods have been developed for fabrication of 3D metallic components among them, selective laser melting (SLM), electron beam melting (EBM), laser metal deposition (LMD), Wire+Arc additive manufacturing (WAAM), and ultrasonic additive manufacturing (UAM) are of prime significance. Unlike other methods, in ultrasonic additive manufacturing, the ultrasonic waves are used instead of applying the sintering process. This technique is well-known for its ability to produce 3D components by repeating the alternative welding and machining procedures at low temperatures. This is why it can overcome the technological issues arisen from the high-temperature sintering. The present review strives to provide an inclusive introduction to the principles of ultrasonic additive manufacturing method and recent advances in ultrasonic additive manufacturing of aluminum matrix composites/nanocomposites. Also, the challenges of this new emerging technique, i.e. its dependence to the applied weld power, is addressed in the paper. The authors attempt to give some perspectives to the researchers for further investigations in this new-emerging field. کلیدواژهها
3D printing ؛ ultrasonic additive manufacturing ؛ metal matrix composites ؛ microstructural features ؛ mechanical properties ؛ microstructure evolution
مراجع
1. Azarniya A, Azarniya A, Abdollah‐zadeh A, Madaah Hosseini HR, Ramakrishna S. In Situ Hybrid Aluminum Matrix Composites: A Review of Phase Transformations and Mechanical Aspects. Advanced Engineering Materials. 2019; 21(7): 1801269.
2. Azarniya A, Taheri AK, Taheri KK. Recent advances in ageing of 7xxx series aluminum alloys: a physical metallurgy perspective. Journal of Alloys and Compounds. 2018; 781: 945-983.
3. Xu T, Li G, Xie M, Liu M, Zhang D, Zhao Y, Chen G, Kai X. Microstructure and mechanical properties of in-situ nano γ-Al2O3p/A356 aluminum matrix composite. Journal of Alloys and Compounds. 2019; 787: 72-85.
4. Sharma, P., G. Chauhan, and N. Sharma, Production of AMC by stir casting–an overview. International Journal of Contemporary Practices, 2011. 2(1): p. 23-46.
5. Marami, G., S.M. Saman, and M.A.S. Sadigh, Enhanced mechanical properties of pure aluminium: Experimental investigation of effects of different parameters. Journal of Central South University, 2018. 25(3): p. 561-569.
6. Bharath, V., et al., Characterization and Mechanical Properties of 2014 Aluminum Alloy Reinforced with Al2O3p Composite Produced by Two-Stage Stir Casting Route. Journal of The Institution of Engineers (India): Series C, 2018. 100(2): p. 277-282.
7. Poovazhagan L, Kalaichelvan K, Shanmugasundaram D. Tensile Properties, Hardness and Micro Structural Analysis of Al 6061–SiCP Metal Matrix Composites Fabricated by Ultrasonic Cavitation Approach. In Advanced Materials Research. 2013; 622: 1275-1279.
8. Chen, L.Q., et al., Synthesis of TiC/Mg composites with interpenetrating networks by in situ reactive infiltration process. Materials Science and Engineering: A, 2005. 408(1-2): p. 125-130.
9. Lee, M., et al., Effect of aluminum carbide on thermal conductivity of the unidirectional CF/Al composites fabricated by low pressure infiltration process. Composites Science and Technology, 2014. 97: p. 1-5.
10. Kumar, S., V. Subramaniya Sarma, and B.S. Murty, Functionally Graded Al Alloy Matrix In-Situ Composites. Metallurgical and Materials Transactions A, 2009. 41(1): p. 242-254.
11. Rajan, T.P.D., R.M. Pillai, and B.C. Pai, Characterization of centrifugal cast functionally graded aluminum-silicon carbide metal matrix composites. Materials Characterization, 2010. 61(10): p. 923-928.
12. Huang, X., et al., Aluminum alloy pistons reinforced with SiC fabricated by centrifugal casting. Journal of Materials Processing Technology, 2011. 211(9): p. 1540-1546.
13. Mahdavi, S. and F. Akhlaghi, Effect of the Graphite Content on the Tribological Behavior of Al/Gr and Al/30SiC/Gr Composites Processed by In Situ Powder Metallurgy (IPM) Method. Tribology Letters, 2011. 44(1): p. 1-12.
14. Ahmadvand, M.S., A. Azarniya, and H.R. Madaah Hosseini, Thermomechanical synthesis of hybrid in-situ Al-(Al3Ti+Al2O3) composites through nanoscale Al-Al2TiO5 reactive system. Journal of Alloys and Compounds, 2019. 789: p. 493-505.
15. Azarniya, A., et al., Thermal decomposition of nanostructured Aluminum Titanate in an active Al matrix: A novel approach to fabrication of in situ Al/Al2O3–Al3Ti composites. Materials & Design, 2015. 88: p. 932-941.
16. Azarniya, A. and H.R. Madaah Hosseini, A new method for fabrication of in situ Al/Al 3 Ti–Al 2 O 3 nanocomposites based on thermal decomposition of nanostructured tialite. Journal of Alloys and Compounds, 2015. 643: p. 64-73.
17. Koch, C.C., Nanostructured materials: processing, properties and applications . 2006: William Andrew.
18. Zhao, N., P. Nash, and X. Yang, The effect of mechanical alloying on SiC distribution and the properties of 6061 aluminum composite. Journal of Materials Processing Technology, 2005. 170(3): p. 586-592.
19. Pérez-Bustamante, R., et al., Microstructural and hardness behavior of graphene-nanoplatelets/aluminum composites synthesized by mechanical alloying. Journal of Alloys and Compounds, 2014. 615: p. S578-S582.
20. Xu, Z.-F., et al., Mechanical and Thermal Properties of Vapor-Grown Carbon Fiber Reinforced Aluminum Matrix Composites by Plasma Sintering. MATERIALS TRANSACTIONS, 2010. 51(3): p. 510-515.
21. Azarniya, A., et al., Physicomechanical Properties of Porous Materials by Spark Plasma Sintering. Critical Reviews in Solid State and Materials Sciences, 2019: p. 1-44.
22. Azarniya, A., et al., Physicomechanical properties of spark plasma sintered carbon nanotube-reinforced metal matrix nanocomposites. Progress in Materials Science, 2017. 90: p. 276-324.
23. Azarniya, A., et al., Metallurgical Challenges in Carbon Nanotube-Reinforced Metal Matrix Nanocomposites. Metals, 2017. 7(10): p. 384.
24. Gui M, Kang SB. Dry sliding wear behavior of plasma-sprayed aluminum hybrid composite coatings. Metallurgical and Materials Transactions A. 2001;32(9): 2383-2392.
25. Cannillo, V., et al., Surface modification of Al–Al2O3 composites by laser treatment. Optics and Lasers in Engineering, 2010. 48(12): p. 1266-1277.
26. Sahu, J.K., C.K. Sahoo, and M. Masanta, In-Situ TiB2–TiC–Al2O3Composite Coating on Aluminum by Laser Surface Modification. Materials and Manufacturing Processes, 2015. 30(6): p. 736-742.
27. Mishra, R.S. and Z.Y. Ma, Friction stir welding and processing. Materials Science and Engineering: R: Reports, 2005. 50(1-2): p. 1-78.
28. Farshbaf Ahmadipour, M., M. Movahedi, and A.H. Kokabi, Microstructural Evaluation and Mechanical Properties of Al1050/TiO2-Graphite Hybrid Nanocomposite Produced Via Friction Stir Processing. Metallurgical and Materials Transactions A, 2019. 50(5): p. 2443-2461.
29. Lim, D.K., T. Shibayanagi, and A.P. Gerlich, Synthesis of multi-walled CNT reinforced aluminium alloy composite via friction stir processing. Materials Science and Engineering: A, 2009. 507(1-2): p. 194-199.
30. Wong, K.V. and A. Hernandez, A Review of Additive Manufacturing. ISRN Mechanical Engineering, 2012. 2012: p. 1-10.
31. Murr, L.E. and W.L. Johnson, 3D metal droplet printing development and advanced materials additive manufacturing. Journal of Materials Research and Technology, 2017. 6(1): p. 77-89.
32. Wohlers, T., Tracking Global Growth in Industrial-Scale Additive Manufacturing. 3D Printing and Additive Manufacturing, 2014. 1(1): p. 2-3.
33. Cooper, K., Rapid Prototyping Technology . 2001: CRC Press.
34. Zenou, M. and L. Grainger, Additive manufacturing of metallic materials , in Additive Manufacturing . 2018, Elsevier. p. 53-103.
35. Giannatsis, J. and V. Dedoussis, Additive fabrication technologies applied to medicine and health care: a review. The International Journal of Advanced Manufacturing Technology, 2009. 40(1-2): p. 116-127.
36. Wohlers T, Caffrey T. Additive manufacturing and 3D printing state of the industry: annual worldwide progress report. Wohlers Associates Inc., Colorado. 2011.
37. Ciurana J. Designing, prototyping and manufacturing medical devices: an overview. International Journal of Computer Integrated Manufacturing. 2014; 27(10): 901-918.
38. Uriondo, A., M. Esperon-Miguez, and S. Perinpanayagam, The present and future of additive manufacturing in the aerospace sector: A review of important aspects. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 2015. 229(11): p. 2132-2147.
39. Frazier, W.E., Metal Additive Manufacturing: A Review. Journal of Materials Engineering and Performance, 2014. 23(6): p. 1917-1928.
40. Kruth, J.P., Material Incress Manufacturing by Rapid Prototyping Techniques. CIRP Annals, 1991. 40(2): p. 603-614.
41. Yang, L., et al., Additive Manufacturing of Metals: The Technology, Materials, Design and Production , in Springer Series in Advanced Manufacturing . 2017, Springer International Publishing.
42. Guo, H., et al., Joining of carbon fiber and aluminum using ultrasonic additive manufacturing (UAM). Composite Structures, 2019. 208: p. 180-188.
43. Wu, W., et al., Ultrasonic additive manufacturing of bulk Ni-based metallic glass. Journal of Non-Crystalline Solids, 2019. 506: p. 1-5.
44. Hehr, A., et al., Selective Reinforcement of Aerospace Structures Using Ultrasonic Additive Manufacturing. Journal of Materials Engineering and Performance, 2018. 28(2): p. 633-640.
45. Ward, A.A. and Z.C. Cordero, Junction growth and interdiffusion during ultrasonic additive manufacturing of multi-material laminates. Scripta Materialia, 2020. 177: p. 101-105.
46. Wohlers, T. and T. Gornet, History of additive manufacturing. Wohlers Report: Additive Manufacturing and 3D Printing State of the Industry Annual Worldwide Progress Report, 2011.
47. Griffiths, R.J., et al., A Perspective on Solid-State Additive Manufacturing of Aluminum Matrix Composites Using MELD. Journal of Materials Engineering and Performance, 2018. 28(2): p. 648-656.
48. Bourell, D., et al., Materials for additive manufacturing. CIRP Annals, 2017. 66(2): p. 659-681.
49. Bournias-Varotsis, A., et al., Ultrasonic Additive Manufacturing as a form-then-bond process for embedding electronic circuitry into a metal matrix. Journal of Manufacturing Processes, 2018. 32: p. 664-675.
50. Wang, Y., et al., Microstructure and mechanical properties of amorphous strip/aluminum laminated composites fabricated by ultrasonic additive consolidation. Materials Science and Engineering: A, 2019. 749: p. 74-78.
51. DebRoy, T., et al., Additive manufacturing of metallic components – Process, structure and properties. Progress in Materials Science, 2018. 92: p. 112-224.
52. Kong, C.Y., R.C. Soar, and P.M. Dickens, Characterisation of aluminium alloy 6061 for the ultrasonic consolidation process. Materials Science and Engineering: A, 2003. 363(1-2): p. 99-106.
53. Rathee, S., et al., Friction Based Additive Manufacturing Technologies: Principles for Building in Solid State, Benefits, Limitations, and Applications . 2018: CRC Press.
54. Yu, H.Z., et al., Non-beam-based metal additive manufacturing enabled by additive friction stir deposition. Scripta Materialia, 2018. 153: p. 122-130.
55. Janaki Ram, G.D., et al., Use of ultrasonic consolidation for fabrication of multi‐material structures. Rapid Prototyping Journal, 2007. 13(4): p. 226-235.
56. Sriraman, M.R., et al., Thermal transients during processing of materials by very high power ultrasonic additive manufacturing. Journal of Materials Processing Technology, 2011. 211(10): p. 1650-1657.
57. Hahnlen, R. and M.J. Dapino, Stress-induced tuning of ultrasonic additive manufacturing Al-NiTi composites , in Behavior and Mechanics of Multifunctional Materials and Composites 2012 . 2012, SPIE.
58. Hopkins, C.D., M.J. Dapino, and S.A. Fernandez, Statistical Characterization of Ultrasonic Additive Manufacturing Ti/Al Composites. Journal of Engineering Materials and Technology, 2010. 132(4).
59. Hahnlen, R. and M.J. Dapino, Active metal-matrix composites with embedded smart materials by ultrasonic additive manufacturing , in Industrial and Commercial Applications of Smart Structures Technologies 2010 . 2010, SPIE.
60. Deng, Z., et al., Yttria-stabilized zirconia-aluminum matrix composites via ultrasonic additive manufacturing. Composites Part B: Engineering, 2018. 151: p. 215-221.
61. Wolcott, P.J., A. Hehr, and M.J. Dapino, Optimal welding parameters for very high power ultrasonic additive manufacturing of smart structures with aluminum 6061 matrix , in Industrial and Commercial Applications of Smart Structures Technologies 2014 . 2014, SPIE.
62. Kong, C.Y. and R.C. Soar, Fabrication of metal–matrix composites and adaptive composites using ultrasonic consolidation process. Materials Science and Engineering: A, 2005. 412(1-2): p. 12-18.
63. Siggard, E.J., Investigative research into the structural embedding of electrical and mechanical systems using ultrasonic consolidation (UC) . 2007: Utah State University.
64. Hahnlen, R. and M.J. Dapino, NiTi–Al interface strength in ultrasonic additive manufacturing composites. Composites Part B: Engineering, 2014. 59: p. 101-108.
65. Sridharan, N., et al., Microstructure and texture evolution in aluminum and commercially pure titanium dissimilar welds fabricated using ultrasonic additive manufacturing. Scripta Materialia, 2016. 117: p. 1-5.
66. Friel, R.J. and R.A. Harris, Ultrasonic Additive Manufacturing – A Hybrid Production Process for Novel Functional Products. Procedia CIRP, 2013. 6: p. 35-40.
67. Dehoff, R.R. and S.S. Babu, Characterization of interfacial microstructures in 3003 aluminum alloy blocks fabricated by ultrasonic additive manufacturing. Acta Materialia, 2010. 58(13): p. 4305-4315.
68. Schick, D., et al., Microstructural Characterization of Bonding Interfaces in Aluminum 3003 Blocks Fabricated by Ultrasonic Additive Manufacturing-Methods were examined to link microstructure and linear weld density to the mechanical properties of ultrasonic additive manufacturing. Welding Journal, 2010. 89(5): p. 105S.
69. Janaki Ram, G.D., Y. Yang, and B.E. Stucker, Effect of process parameters on bond formation during ultrasonic consolidation of aluminum alloy 3003. Journal of Manufacturing Systems, 2006. 25(3): p. 221-238.
70. Kong, C.Y., R.C. Soar, and P.M. Dickens, Optimum process parameters for ultrasonic consolidation of 3003 aluminium. Journal of Materials Processing Technology, 2004. 146(2): p. 181-187.
71. Graff, K., M. Short, and M. Norfolk. Very high power ultrasonic additive manufacturing (VHP UAM) . in International Solid Freeform Fabrication Symposium, Austin, TX . 2011.
72. Hehr, A. and M.J. Dapino, Dynamics of ultrasonic additive manufacturing. Ultrasonics, 2017. 73: p. 49-66.
73. Hehr, A. and M.J. Dapino, Interfacial shear strength estimates of NiTi–Al matrix composites fabricated via ultrasonic additive manufacturing. Composites Part B: Engineering, 2015. 77: p. 199-208.
74. Dittmer, R., et al., Large blocking force in Bi1/2Na1/2TiO3-based lead-free piezoceramics. Scripta Materialia, 2012. 67(1): p. 100-103.
75. Chen, X., et al., Deformation Mechanisms in NiTi-Al Composites Fabricated by Ultrasonic Additive Manufacturing. Shape Memory and Superelasticity, 2015. 1(3): p. 294-309.
76. Yang Y, Ram GJ, Stucker BE. An Experimental Determination of Optimum Processing Parameters for Al∕ SiC Metal Matrix Composites Made Using Ultrasonic Consolidation. Journal of engineering materials and technology. 2007; 129(4): 538-549.
77. Safavi, M.S. and A. Rasooli, Ni-P-TiO2 nanocomposite coatings with uniformly dispersed Ni3Ti intermetallics: Effects of current density and post heat treatment. Surface and Coatings Technology, 2019. 372: p. 252-259.
78. Safavi, M.S. and A. Rasooli, Ni-P-TiO2 nanocomposite coatings with uniformly dispersed Ni3Ti intermetallics: effects of TiO2 nanoparticles concentration. Surface Engineering, 2019. 35(12): p. 1070-1080.
79. Safavi, M.S. and M. Etminanfar, A review on the prevalent fabrication methods, microstructural, mechanical properties, and corrosion resistance of nanostructured hydroxyapatite containing bilayer and multilayer coatings used in biomedical applications. Journal of Ultrafine Grained and Nanostructured Materials, 2019. 52(1): p. 1-17.
80. Safavi, M.S., et al., Incorporation of Y2O3 nanoparticles and glycerol as an appropriate approach for corrosion resistance improvement of Ni-Fe alloy coatings. Ceramics International, 2019. 45(8): p. 10951-10960.
81. Rasooli, A., M.S. Safavi, and M. Kasbkar Hokmabad, Cr2O3 nanoparticles: A promising candidate to improve the mechanical properties and corrosion resistance of Ni-Co alloy coatings. Ceramics International, 2018. 44(6): p. 6466-6473.
82. Abele, L., et al., Superoleophobic surfaces via functionalization of electrophoretic deposited SiO2 spheres on smart aluminum substrates. Applied Surface Science, 2019. 490: p. 56-60.
83. Yang, Z.W., et al., Design of reinforced interfacial structure in brazed joints of C/C composites and Nb by pre-oxidation surface treatment combined with in situ growth of CNTs. Carbon, 2019. 143: p. 494-506.
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