The influence of ultrasonic shot peening on the surface roughness, microstructure, and mechanical properties of TC2 thin-sheet

Xu, Qingze; Cao, Yi; Jin, Chengyan; Yu, Jianfeng; Si, Chaorun

doi:10.1016/j.jmrt.2021.08.029

Cited by 22 publications

(1 citation statement)

References 39 publications

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“…To date, several surface treatments have been adopted to improve the undesirable outcomes and corrosion behavior of PM-processed Ti alloys [10,11]. Additionally, peeningbased methods such as laser peening [12][13][14], ultrasonic peening [15,16] and shot peening [1,[17][18][19][20] have recently been applied to both conventional and powder metallurgical Ti alloys to enhance their mechanical, tribological, biological, and corrosion properties [12,[14][15][16][17][18][19][20]. More importantly, it has been recently demonstrated that peening methods, such as laser peening [21], ultrasonic shot peening [15,22], and pneumatic shot peening [23], can enhance the corrosion resistance of the Ti6Al4V alloy [15,[21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Corrosion Behavior of Shot-Peened Ti6Al4V Alloy Produced via Pressure-Assisted Sintering

Avcu,

Abakay,

Yıldıran Avcu

et al. 2023

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For the first time, the present study investigates the corrosion, surface, and subsurface properties of a shot-peened Ti6Al4V powder metallurgical alloy produced via pressure-assisted sintering. Shot peening yielded a fine-grained microstructure beneath the surface down to 100 microns, showing that it caused severe plastic deformation. XRD analysis revealed that the sizes of the crystallites in unpeened and shot-peened Ti6Al4V alloy samples were 48.59 nm and 27.26 nm, respectively, indicating a substantial reduction in crystallite size with shot peening. Cross-sectional hardness maps of shot-peened samples showed a work-hardened surface layer, indicating a ~17% increase in near-surface hardness relative to unpeened samples. Three-dimensional surface topographies showed that shot peening yielded uniform peaks and valleys, with a maximum peak height of 4.83 μm and depth of 6.56 μm. With shot peening, the corrosion potential shifted from −0.386 V to −0.175 V, showing that the passive layer developed faster and was more stable than the unpeened sample, improving corrosion resistance. As determined via XRD analysis, the increased grain refinement (i.e., the number of grain boundaries) and the subsequent accumulation of TiO2 and Al5Ti3V2 compounds through shot peening also suggested the effective formation of a protective passive layer. As demonstrated via electrochemical impedance spectroscopy, the formation of this passive film improved the corrosion resistance of the alloy. The findings will likely advance surface engineering and corrosion research, enabling safer and more productive shot peening in corrosion-critical applications.

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