Phase transformation behaviours and mechanical properties of Ti6Al4V-0.55Fe alloy during continuous cooling

Abstract: The phase transformation and mechanical properties of Ti6Al4V-0.55Fe alloy were investigated during the continuous cooling process. The curves of α phase precipitation exhibit a typical S-shaped pattern, which indicated that β→α phase transformation is a nucleation-growth-controlled process. The average activation energy is 231 kJ mol−1 calculated by Kissinger–Akahira–Sunose method. The Avrami exponent during β→α transformation significantly changes with the increasing transformed volume fraction. It is found … Show more

“…In previous studies, a novel low-cost titanium alloy, Ti6Al4V-0.55Fe, with a good combination of strength-plasticity and a high level of toughness was prepared [22,23]. This alloy also has a better LCF life than that of Ti6Al4V alloy [24], showing promising application potential for deep-sea equipment manufacturing.…”

Low-Cycle Corrosion Fatigue Deformation Mechanism for an α+β Ti-6Al-4V-0.55Fe Alloy

“…In previous studies, a novel low-cost titanium alloy, Ti6Al4V-0.55Fe, with a good combination of strength-plasticity and a high level of toughness was prepared [22,23]. This alloy also has a better LCF life than that of Ti6Al4V alloy [24], showing promising application potential for deep-sea equipment manufacturing.…”

Low-Cycle Corrosion Fatigue Deformation Mechanism for an α+β Ti-6Al-4V-0.55Fe Alloy

Solidification Microstructure Reconstruction and Its Effects on Phase Transformation, Grain Boundary Transformation Mechanism, and Mechanical Properties of TC4 Alloy Welded Joint

Low cycle fatigue behavior and deformation mechanism of Ti–6Al–4V-0.55Fe alloy under the control of strain and stress amplitudes