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Materials Science and Technology Volume 39, 2023 - Issue 15
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Research Article

The microstructure and mechanical properties of 2219 alloy during ultrasonic treatment

An-qing Lia Light Alloy Research Institutes, Central South University, Changsha, People’s Republic of China;b State Key Laboratory of High Performance Complex Manufacturing, Changsha, People’s Republic of ChinaView further author information
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Ri-peng Jianga Light Alloy Research Institutes, Central South University, Changsha, People’s Republic of China;b State Key Laboratory of High Performance Complex Manufacturing, Changsha, People’s Republic of ChinaCorrespondence[email protected]
View further author information
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Rui-qing Lia Light Alloy Research Institutes, Central South University, Changsha, People’s Republic of China;b State Key Laboratory of High Performance Complex Manufacturing, Changsha, People’s Republic of ChinaORCID Iconhttps://orcid.org/0000-0002-0098-1385View further author information
ORCID Icon &
Li-hua Zhanga Light Alloy Research Institutes, Central South University, Changsha, People’s Republic of China;b State Key Laboratory of High Performance Complex Manufacturing, Changsha, People’s Republic of China;c College of Mechanical and Electrical Engineering, Central South University, Changsha, People’s Republic of ChinaView further author information
Pages 2135-2146 | Received 04 Feb 2023, Accepted 17 Mar 2023, Published online: 06 Apr 2023

References

  • Zhang L, Jiang R, Li X, et al. Microstructure modification for 2219 Al alloy through ultrasonic treatment and fast cooling. Mater Sci Technol [J]. 2019;35(11):1392–1400.
  • Li R, Liu Z, Dong F, et al. Grain refinement of a large-scale Al alloy casting by introducing the multiple ultrasonic generators during solidification. Metall Mater Trans A[J]. 2016;47(8):3790–3796.
  • He H, Yi Y, Huang S, et al. An improved process for grain refinement of large 2219 Al alloy rings and its influence on mechanical properties. J Mater Sci Technol [J]. 2019;35(1):55–63.
  • Huang M, Li Z. Size effects on stress concentration induced by a prolate ellipsoidal particle and void nucleation mechanism. Int J Plastic [J]. 2005;21(8):1568–1590.
  • Lebon GSB, Tzanakis I, Pericleous K, et al. Ultrasonic liquid metal processing: the essential role of cavitation bubbles in controlling acoustic streaming. Ultrason Sonochem[J]. 2019;55:243–255.
  • Liu Z, Li R, Jiang R, et al. Scalable ultrasound-assisted casting of ultra-large 2219 Al alloy ingots. Metall Mater Trans A[J]. 2019;50(3):1146–1152.
  • Khan AS, Liu H. A new approach for ductile fracture prediction on Al 2024-T351 alloy. Int J Plastic [J]. 2012;35:1–12.
  • Eskin GI. Principles of ultrasonic treatment: application for light alloys melts. Adv Perform Mater [J]. 1997;4(5):10.
  • Eskin GI ED. Ultrasonic treatment of light alloy melts. 2014.
  • Dogan H, Popov V. Numerical simulation of the nonlinear ultrasonic pressure wave propagation in a cavitating bubbly liquid inside a sonochemical reactor. Ultrason Sonochem[J]. 2016;30:87–97.
  • Peng K, Qin FGF, Jiang R, et al. Production and dispersion of free radicals from transient cavitation bubbles: an intergrated numerical scheme and applications. Ultrason Sonochemistry[J]. 2022;88(6.
  • Xu H, Han Q, Meek TT. Effects of ultrasonic vibration on degassing of aluminum alloys. Mater Sci Eng A[J]. 2008;473(1-2):96–104.
  • Sharma VMJ, Kumar KS, Rao BN, et al. Effect of microstructure and strength on the fracture behavior of AA2219 alloy. Mater Sci Eng A[J]. 2009;502(1-2):45–53.
  • Tian Y, Xiaoqian Li ZL, Zhang L, et al. The cavitation erosion of ultrasonic sonotrde during large-scale metallic casting:experiment and simulation. Ultrason Sonochem [J]. 2018;43(2):9.
  • Zou H, Pan Q-l, Shi Y-j, et al. Effect of ultrasonic field on microstructure and mechanical properties of as-cast 7085 aluminum alloy. J Cent South Univ [J]. 2018;25(6):1285–1294.
  • Wang F, Chiu Y-L, Eskin D, et al. A grain refinement mechanism of cast commercial purity aluminium by vanadium. Mater Charact [J]. 2021;181:12.
  • Eskin DG, Tzanakis I, Wang F, et al. Fundamental studies of ultrasonic melt processing. Ultrason Sonochem [J]. 2019;52:455–467.
  • Tzanakis I, Lebon GS, Eskin DG, et al. Characterizing the cavitation development and acoustic spectrum in various liquids. Ultrason Sonochem [J]. 2017;34:651–662.
  • Xiao P, Gao Y, Yang C, et al. Microstructure, mechanical properties and strengthening mechanisms of Mg matrix composites reinforced with in situ nanosized TiB2 particles. Mater Sci Eng A[J]. 2018;710:251–259.
  • Zhang L, Li R, Jiang R, et al. A comparative study on the effect of four-source ultrasonic power on the microstructure and mechanical properties of large-scale 2219 aluminum ingots. Jom[J]. 2019;71(6):2063–2071.
  • Martinez R, Russier V, Couzinié JP, et al. Modeling of the influence of coarsening on viscoplastic behavior of a 319 foundry aluminum alloy. Mater Sci Eng A[J]. 2013;559:40–48.
  • Zhang L, Li X, Jiang R, et al. Effect of ultrasonic treatment on grain structure, eutectic phase and mechanical properties of an Al–6.2 wt% Cu alloy. Metal Mater Int [J]. 2019;27(5):1282–1295.
  • Zhang L, Li X, Li R, et al. Effects of high-intensity ultrasound on the microstructures and mechanical properties of ultra-large 2219 Al alloy ingot. Mater Sci Eng A[J]. 2019;763.
  • Patel B, Chaudhari GP, Bhingole PP. Microstructural evolution in ultrasonicated AS41 magnesium alloy. Mater Lett [J]. 2012;66(1):335–338.
  • Surekha K, Murty BS, Prasad Rao K. Comparison of corrosion behaviour of friction stir processed and laser melted AA 2219 aluminium alloy. Mater Design [J]. 2011;32(8-9):4502–4508.
  • Wang H, Yi Y, Huang S. Microstructure evolution and mechanical properties of 2219 Al alloy during aging treatment. J Mater Eng Perform [J]. 2017;26(4):1475–1482.
  • Wang P-S, Lee S-L, Lin J-C, et al. Effects of solution temperature on mechanical properties of 319.0 aluminum casting alloys containing trace beryllium. J Mater Res [J]. 2011;15(9):2027–2035.
  • Wang QG. Microstructural effects on the tensile and fracture behavior of aluminum casting alloys A356/357. Metall Mater Trans A[J]. 2003;34(6):13.
  • Louisnard O. A viable method to predict acoustic streaming in presence of cavitation. Ultrason Sonochem[J]. 2017;35(Pt A):518–524.
  • Wu Z, Li Y, Tang J, et al. Ultrasound-assisted preparation of chitosan/nano-silica aerogel/tea polyphenol biodegradable films: physical and functional properties. Ultrason Sonochem[J]. 2022;87:106052.
  • Jinshan Z. Liquid metal forming principle. BeiJing: Chemical Industry Press; 2011.pp. 400.
  • F, M.L., Structure and Properties of Aluminum Alloys. Butterworths Press. 2001, London. 200-400.
  • I, E.G. Principles of ultrasonic treatment application for light alloys melts. Adv Perform Mater [J]. 1997;4(2):7.
  • Tzanakis I, Lebon GSB, Eskin DG, et al. Investigation of the factors influencing cavitation intensity during the ultrasonic treatment of molten aluminium. Mater Design [J]. 2016;90:979–983.
  • Song B, Yao P, Zhang Y, et al. Ultrasound pretreatment prior to spray drying improve the flowability and water sorption properties of micellar casein concentrate. Ultrason Sonochem[J]. 2022;87:106049.
  • Eskin DG, Tzanakis I. High-frequency vibration and ultrasonic processing. Springer Seri Mater Sci [J]. 2018;10(8):1–52.
  • Xie Z, Jiang R, Li X, et al. Microstructural evolution and mechanical properties of TiB(2)/2195 composites fabricated by ultrasonic-assisted in-situ casting. Ultrason Sonochem[J]. 2022;90:1–12.
  • Hansen N. Hall–petch relation and boundary strengthening. Scripta Mater [J]. 2004;51(8):801–806.
  • X, N.M. Cavution prevention with roughened surface. J Hydraul Eng [J]. 2015;127(10):878–880.
  • Moussa ME, Waly MA, Amin M. Effect of high intensity ultrasonic treatment on microstructural modification and hardness of a nickel-aluminum bronze alloy. J Alloy Comp [J]. 2018;741:804–813.
  • Kamal Babu K, Panneerselvam K, Sathiya P, et al. Influences of metastable θ″, θ′ and stable θ intermetallics formed during cryorolling and friction stir welding process on AA2219. J Alloy Comp [J]. 2018;732:624–629.
  • Jung J-G, Ahn T-Y, Cho Y-H, et al. Synergistic effect of ultrasonic melt treatment and fast cooling on the refinement of primary Si in a hypereutectic Al–Si alloy. Acta Mater [J]. 2018;144:31–40.

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