Effect of laser shock processing on oxidation resistance of laser additive manufactured Ti6Al4V titanium alloy
Corrosion Science, 2020•Elsevier
The high-temperature oxidation resistance of laser additive manufactured (LAM) Ti6Al4V
before and after laser shock processing (LSP) was investigated. The samples were oxidized
at 400− 800° C for 1− 50 h in air. The results revealed that the rate of weight gain of the
Ti6Al4V fabricated through LAM decreased, and LSP had a positive effect on increasing the
oxidation resistance. At an oxidation temperature of 700° C, an aluminum-rich layer was
observed in the cross-section before LSP. After LSP, the aluminum-rich layer changed to …
before and after laser shock processing (LSP) was investigated. The samples were oxidized
at 400− 800° C for 1− 50 h in air. The results revealed that the rate of weight gain of the
Ti6Al4V fabricated through LAM decreased, and LSP had a positive effect on increasing the
oxidation resistance. At an oxidation temperature of 700° C, an aluminum-rich layer was
observed in the cross-section before LSP. After LSP, the aluminum-rich layer changed to …
Abstract
The high-temperature oxidation resistance of laser additive manufactured (LAM) Ti6Al4V before and after laser shock processing (LSP) was investigated. The samples were oxidized at 400−800 °C for 1−50 h in air. The results revealed that the rate of weight gain of the Ti6Al4V fabricated through LAM decreased, and LSP had a positive effect on increasing the oxidation resistance. At an oxidation temperature of 700 °C, an aluminum-rich layer was observed in the cross-section before LSP. After LSP, the aluminum-rich layer changed to three layers. The aluminum-rich layer prevented the diffusion of oxygen, which improved the oxidation resistance of the Ti6Al4V.
Elsevier
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