Influence of Filler on the Microstructure, Mechanical Properties and Residual Stresses in TIG Weldments of Dissimilar Titanium Alloys

Abstract: https://orcid.org/0000-0001-7010-8285 (2021) Influence of filler on the microstructure, mechanical properties and residual stresses in TIG weldments of dissimilar titanium alloys. Acta Metallurgica Sinica (English Letters).

“…The assessment of mechanical behavior of these weld joints under different loading conditions and environment has always been the prime focus of the research intended for different industries such as process plants, power plants, aerospace and automobile sectors. [1][2][3][4] Different characterization techniques such as residual stresses measurement, 5 hardness profile, 6 single-notch, double notch and smooth tensile testing, 7 impact toughness, 8 low cycle fatigue testing 9 etc are used to assess the mechanical behavior of weldments. These tests primarily indicate the time-independent strength of the specimens due to which the creep performance of the welded joints are important to assess as they represent the timedependent mechanical behavior of fabricated components.…”

“…Different characterization techniques such as residual stresses measurement, 5 hardness profile, 6 single-notch, double notch and smooth tensile testing, 7 impact toughness, 8 low cycle fatigue testing 9 etc are used to assess the mechanical behavior of weldments. These tests primarily indicate the time-independent strength of the specimens due to which the creep performance of the welded joints are important to assess as they represent the time-dependent mechanical behavior of fabricated components.…”

Indentation creep behavior of pulsed Tungsten inert gas welded Ti-5Al-2.5Sn alloy joints by nanoindentation and atomic force microscopy

“…The assessment of mechanical behavior of these weld joints under different loading conditions and environment has always been the prime focus of the research intended for different industries such as process plants, power plants, aerospace and automobile sectors. [1][2][3][4] Different characterization techniques such as residual stresses measurement, 5 hardness profile, 6 single-notch, double notch and smooth tensile testing, 7 impact toughness, 8 low cycle fatigue testing 9 etc are used to assess the mechanical behavior of weldments. These tests primarily indicate the time-independent strength of the specimens due to which the creep performance of the welded joints are important to assess as they represent the timedependent mechanical behavior of fabricated components.…”

“…Different characterization techniques such as residual stresses measurement, 5 hardness profile, 6 single-notch, double notch and smooth tensile testing, 7 impact toughness, 8 low cycle fatigue testing 9 etc are used to assess the mechanical behavior of weldments. These tests primarily indicate the time-independent strength of the specimens due to which the creep performance of the welded joints are important to assess as they represent the time-dependent mechanical behavior of fabricated components.…”

Indentation creep behavior of pulsed Tungsten inert gas welded Ti-5Al-2.5Sn alloy joints by nanoindentation and atomic force microscopy

“…6–9 The use of tungsten inert gas (TIG) welding for autogenous welding of titanium or nickel-based alloys is extensively reported in the literature. 10–16 In the TIG welding process, a nonconsumable tungsten electrode is used to generate an electric arc between the electrode tip and workpiece material. To protect the welded metal from atmospheric contamination, a shielding gas such as argon or helium is used which also provides a medium for the transport of electrons from the electrode to the workpiece material.…”

Dissimilar tungsten inert gas welding between Inconel 718 and commercially pure titanium using a vanadium interlayer

Enhancing the Mechanical Properties Induced by Ta Microalloying in TIG-Welded Ti2AlNb-Based Intermetallic Alloy