Strain controlled fatigue testing of the metastable β-titanium alloy Ti–6.8Mo–4.5Fe–1.5Al (Timetal LCB)

“…The hysteresis loops at different cycles of dissimilar joint were basically symmetrical (Fig.8) in spite of the hexagonal close-packed crystal structure of the titanium alloys, unlike those of extruded magnesium alloys [39][40][41][42]. Symmetrical hysteresis loops in titanium alloys were also reported in [22,43,44]. Fig.9 shows the effect of total strain amplitudes on the shape of hysteresis loops at the mid-life cycle.…”

Tensile and fatigue behavior of electron beam welded dissimilar joints of Ti–6Al–4V and IMI834 titanium alloys

“…The hysteresis loops at different cycles of dissimilar joint were basically symmetrical (Fig.8) in spite of the hexagonal close-packed crystal structure of the titanium alloys, unlike those of extruded magnesium alloys [39][40][41][42]. Symmetrical hysteresis loops in titanium alloys were also reported in [22,43,44]. Fig.9 shows the effect of total strain amplitudes on the shape of hysteresis loops at the mid-life cycle.…”

Tensile and fatigue behavior of electron beam welded dissimilar joints of Ti–6Al–4V and IMI834 titanium alloys

“…Fe is a common element which is much cheaper than V, Nb, and Mo and has the ability to stabilize β phase. A few Fe alloyed near-β titanium alloys, such as Ti-1.5 Al-6.8 Mo-4.5 Fe, have been developed and demonstrated excellent mechanical properties [10,11,12]. Moreover, the addition of Fe facilitates thermo-mechanical processing by reducing flow stress [13], thus saves heat and electric consumption.…”

Optimization of Low-Cost Ti-35421 Titanium Alloy: Phase Transformation, Bimodal Microstructure, and Combinatorial Mechanical Properties

Comparative Study of the Effect of Isothermal Exposure on Metastable β-Titanium Alloy Mechanical Properties