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Combining manufacturing of titanium alloy through direct energy deposition and laser shock peening processes

Jiaxuan Chi, Zhongyi Cai, Hepeng Zhang, Hongqiang Zhang, Wei Guo, Zhandong Wan, Guofeng Han, Peng Peng, Zhi Zeng

2021Materials & Design80 citationsDOIOpen Access PDF

Abstract

Combined manufacturing of direct energy deposition (DED) and laser shock peening (LSP) exhibits great potentials in repairing titanium alloy components and improving their mechanical properties. In this study, a DEDed repaired sample was fabricated by depositing TA15 powders on a forged TC17 plate, and subjected to a following LSP treatment. The effects of LSP on microstructures, residual stress, and tensile properties of DEDed samples were evaluated. After LSP, a high-level compressive residual stress state (maximum =−596 MPa) and microstructure refinement were induced in the treated surface. The average α phase area decreased from 1.88 μm2 to 0.73 μm2, and much more low angle grain boundaries were induced after LSP. Meanwhile, the corresponding ultimate tensile strength (UTS) was improved by 12.46%.

Topics & Concepts

Materials sciencePeeningResidual stressMicrostructureUltimate tensile strengthTitanium alloyLaser peeningShot peeningMetallurgyShock (circulatory)Deposition (geology)AlloyTitaniumComposite materialGrain sizeCompressive strengthMedicineBiologySedimentInternal medicinePaleontologySurface Treatment and Residual StressHigh-Velocity Impact and Material BehaviorMetal and Thin Film Mechanics
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