Laser surface treatment of α - β itanium alloy to develop a β-rich phase with very high hardness

The α - β titanium alloy VT31 is used in the aerospace industry due to its high strength to weight ratio and good mechanical properties at elevated temperatures. Surface microstructure plays an important role in the mechanical behavior of the material, especially fatigue. In this work, VT3-1 α - β t...

Full description

Saved in:
Bibliographic Details
Published in:Journal of materials processing technology 2021-02, Vol.288, p.1
Main Authors: Chauhan, Alok Singh, Jha, Jyoti S, Telrandhe, Sagar, Srinivas, V, Gokhale, Amol A, Mishra, Sushil K
Format: Article
Language:English
Subjects:
Aerospace industry
Alloying elements
Electron backscatter diffraction
Finite element method
Hardness
Heat treatment
High temperature
Lasers
Mechanical properties
Microstructure
Phase transitions
Process parameters
Scanning
Strength to weight ratio
Surface layers
Surface roughness
Surface treatment
Titanium alloys
Titanium base alloys
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The α - β titanium alloy VT31 is used in the aerospace industry due to its high strength to weight ratio and good mechanical properties at elevated temperatures. Surface microstructure plays an important role in the mechanical behavior of the material, especially fatigue. In this work, VT3-1 α - β titanium alloy surface microstructure was modified using laser surface heat treatment. Laser surface treatment (LST) was carried out at various laser powers (100−250 W) and scanning speeds (150−500 mm/min). Laser affected zones, surfaces and sub-surfaces were characterized using different techniques. Electron backscatter diffraction (EBSD) analysis of the laser affected zone exhibits a distinct microstructure across the depth of the specimen, and it changes with laser power and scanning speed. At a lower scanning speed and high laser power (200−250 W); almost complete β-containing microstructure was developed at the surface with very high hardness. At an intermediate power (150−200 W), a β -rich surface layer with dendritic features followed by a layer of martensitic microstructure was evident. Interestingly, at high power (250 W) a distinct shiny surface with a lower surface roughness was observed. Moreover, the microstructure under this condition corresponds to an α-phase (transformed microstructure) which is typical of melted and fast cooled α - β titanium alloy. Finite element analysis of the LST was also carried out to predict thermal history based on which the extent of the laser affected zone across the depth was predicted for various processing parameters and correlated with the hardness variation.
ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2020.116873