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Abstract

This study investigates the combined effect of severe plastic deformation via multi-axial compression (MAC) and subsequent double-step aging on the microstructure and mechanical properties of annealed 7075 Al alloy. Three distinct processes were employed: (1) double-step aging on the annealed sample, (2) double-step aging on the six-MAC pass processed sample, and (3) double-step aging without solutionization on the six-MAC pass sample. Process (2) yielded the most significant improvements in mechanical properties. Compared to the annealed sample, the six-MAC pass, double-step aged sample exhibited an average ultimate tensile strength increase of 134% and an average Vickers micro-hardness (HV) increase of 209%. This superior performance is likely attributable to the synergistic effect of grain refinement induced by MAC and precipitate hardening achieved through double-step aging. A comprehensive analysis of microstructure evolution, mechanical properties, fractography, and the relationship between them was conducted for all three processes. This in-depth examination provided valuable insights into the mechanisms governing the observed property enhancements, particularly in process (2). Additionally, a variety of characterization techniques were employed to comprehensively evaluate the material's mechanical and microstructural characteristics.

Keywords

Multi-axial compression Vickers micro-hardness double-step aging strain-induced precipitation precipitation hardening

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References

Huo

Hou

Lang

, et al. Improved thermo-mechanical processing for effective grain refinement of high-strength AA 7050 Al alloy. Mater Sci Eng A 2015; 626: 86–93.

Avcu

. The influences of ECAP on the dry sliding wear behaviour of AA7075 aluminium alloy. Tribol Int 2017; 110: 173–184.

Padap

Chaudhari

Nath

, et al. Ultrafine-grained steel fabricated using warm multiaxial forging: microstructure and mechanical properties. Mater Sci Eng A 2009; 527: 110–117.

Emani

Benedyk

Nash

, et al. Double aging and thermomechanical heat treatment of AA7075 aluminum alloy extrusions. J Mater Sci 2009; 44: 6384–6391.

Aoba

Kobayashi

Miura

. Effects of aging on mechanical properties and microstructure of multi-directionally forged 7075 aluminum alloy. Mater Sci Eng A 2017; 700: 220–225.

Cherukuri

Srinivasan

. Properties of AA6061 processed by multi-axial compressions/forging (MAC/F). Mater Manuf Processes 2006; 21: 519–525.

Stemler

Flausino

Pereira

, et al. Mechanical behavior and microstructures of aluminum in the multi-axial compression (MAC) with and without specimen re-machining. Mater Lett 2019; 237: 84–87.

Chen

Gao

Sha

, et al. Microstructural evolution, strengthening and thermal stability of an ultrafine-grained Al–Cu–Mg alloy. Acta Mater 2016; 109: 202–212.

Xia

Ming

Fu-you

, et al. Microstructure and mechanical properties of isothermal multi-axial forging formed AZ61 Mg alloy. Trans Nonferrous Met Soc China 2013; 23: 3186–3192.

10.

Kumar

Owolabi

Jayaganthan

. Al 6082 alloy strengthening through low strain multi-axial forging. Mater Charact 2019; 155: 109761.

11.

Fan

Tang

Wang

, et al. Comparisons of age hardening and precipitation behavior in 7075 alloy under single and double-stage aging treatments. Met Mater Int 2021; 27: 4204–4215.

12.

Huo

Hou

Cui

, et al. Fine-grained AA 7075 processed by different thermo-mechanical processings. Mater Sci Eng A 2014; 618: 244–253.

13.

Waldman

Sulinski

Markus

. The effect of ingot processing treatments on the grain size and properties of Al alloy 7075. Metall Mater Trans B 1974; 5: 573–584.

14.

Wert

Paton

Hamilton

, et al. Grain refinement in 7075 aluminum by thermomechanical processing. Metall Trans A 1981; 12: 1267–1276.

15.

Dehghani

. Bake hardening of nanograin AA7075 aluminum alloy. Mater Sci Eng A 2011; 530: 618–623.

16.

Yadav

Padap

. Optimization of precipitate hardening parameters of 7075 aluminum alloy using response surface methodology. Proc Inst Mech Eng, Part C: J Mech Eng Sci 2022; 236: 7999–8011.

17.

Shaeri

Salehi

Seyyedein

, et al. Microstructure and mechanical properties of Al-7075 alloy processed by equal channel angular pressing combined with aging treatment. Mater Des 2014; 57: 250–257.

18.

Manjunath

Preetham Kumar

Udaya Bhat

, Evolution of tribological properties of cast Al–10Zn–2Mg alloy subjected to severe plastic deformation, In Structural Integrity Assessment: Proceedings of ICONS 2018, pp. 165–175, Springer Singapore, 2020.

19.

Yildirim

Özyürek

Gürü

. The effects of precipitate size on the hardness and wear behaviors of aged 7075 aluminum alloys produced by powder metallurgy route. Arab J Sci Eng 2016; 41: 4273–4281.

20.

Fan

Jiang

Meng

, et al. Evolution of eutectic structures in Al-Zn-Mg-Cu alloys during heat treatment. Trans Nonferrous Met Soc China 2006; 16: 577–581.

21.

Kamiya

Yakou

. Role of second-phase particles in chip breakability in aluminum alloys. Int J Mach Tools Manuf 2008; 48: 688–697.

22.

Dieter

. Mechanical Metallurgy. Chennai, India: McGraw-Hill, https://books.google.co.in/books?id=_PibPwAACAAJ (1986).

23.

Yadav

Padap

. Optimization of dry sliding wear parameters through RSM approach of fine-grained 7075 al alloy developed by MAC. Proc Inst Mech Eng, Part C: J Mech Eng Sci 2023; 237: 09544062231158958.

24.

Al-Lubani

Ateyat

, Double aging of heat-treated aluminum alloy of (7075) and (6061) to increase the hardness number, In Advanced Problems in Mechanics: Proceedings of the XLVII International Summer School-Conference “Advanced Problems in Mechanics”, June 24-29, 2019, St. Petersburg, Russia, pp. 42–52. Springer International Publishing, 2020.

25.

Lloyd

Chaturvedi

. A calorimetric study of aluminium alloy AA-7075. J Mater Sci 1982; 17: 1819–1824.

26.

Andersen

Marioara

Friis

, et al. Precipitates in aluminium alloys. Adv Phys: X 2018; 3: 1479984.

27.

Tash

Alkahtani

. Aging and mechanical behavior of be-treated 7075 aluminum alloys. Int J Mater Metall Eng 2015; 8: 252–256.

28.

Dehghani

Nekahi

Mirzaie

MAM

. Optimizing the bake hardening behavior of Al7075 using response surface methodology. Mater Des 2010; 31: 1768–1775.

29.

Forouzesh

Kazeminezhad

. On the solution treatment of severely deformed AA2024-O and subsequent natural aging. J Mater Res Technol 2022; 20: 1558–1569.

30.

Rohrer

. Introduction to grains, phases, and interfaces—an interpretation of microstructure. Trans AIME 1948; 175: 15–51., by CS Smith, Metallurgical and Materials Transactions B 41 (2010): 457–494.

31.

Callister

Rethwisch

. Materials Science and Engineering. New Delhi, India: Wiley, https://books.google.co.in/books?id=99UeMAEACAAJ , 2014.

32.

Rajan

TVS

Rajan

Sharma

, et al. Heat Treatment: Principles and Techniques. New Delhi, India: PHI Learning, https://books.google.co.in/books?id=RMpW7fl85WEC , 2011.

33.

Birol

. Restoration of the bake hardening response in a naturally aged twin-roll cast AlMgSi automotive sheet. Scr Mater 2006; 54: 2003–2008.

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Effects of multi-axial compression and double-step aging on the microstructure and mechanical properties of Al alloy 7075

Abstract

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