Abstract
Near α titanium alloys have demonstrated a sensitivity to fatigue loading when incorporating a dwell period at peak applied stress under room temperature. Historically, this was first reported for the relatively coarse grained variant IMI685 and later exemplified when characterising TIMETAL® 834 (Ti-834). Various mechanical factors have been identified as key drivers for the phenomenon, including time on load and high R ratios. This indicates that sub-critical damage is accumulated via creep style mechanisms and has led to analogies with “cold creep” behaviour. The propensity of quasi-cleavage faceting at the initiation sites of fatigue cracks formed under dwell conditions eventually led to an understanding of stress redistribution between strong and weak grains. This mechanism can be accentuated by more extensive regions of common crystallographic grain orientation in the form of “macrozones”. Through this fundamental understanding, new alloys can now be developed with the intent to circumvent dwell sensitivity. The present paper will focus on the fatigue performance of TIMETAL® 575 (Ti-575), a recently developed alloy optimised for aero-engine applications. Ti-575 was designed for improved strength and fatigue performance. The alloy’s susceptibility to dwell fatigue has been avoided through control of the microstructural evolution kinetics and associated thermo-mechanical process route to induce fine scaled, bi-modal microstructure containing equiaxed primary grains and secondary α laths with inherent random grain orientations, thus minimising the formation of macrozones. This work will detail the dwell fatigue testing, interpretation of data and associated microstructural characterisation, including EBSD, and compare this analysis with similar results from more conventional alloys such as Ti-6Al-4V and Ti-834.
Highlights
The phenomenon of cold dwell fatigue sensitivity can be traced back to the seminal research conducted at the Royal Aircraft Establishment (RAE) at Farnborough in the United Kingdom
Following in-service fan disc failures occurring in RB-211 engines during the early 1970s [1], Evans and Gostelow eventually published the results of their detailed fatigue assessment in 1978, focussed upon the near alloy IMI685 [2]
The LCF data measured from TIMETAL® 575 (Ti-575) specimens are plotted in Figure 4 enabling a comparison between cyclic (15 cpm) and dwell (2 minutes) results
Summary
The phenomenon of cold dwell fatigue sensitivity can be traced back to the seminal research conducted at the Royal Aircraft Establishment (RAE) at Farnborough in the United Kingdom. The work demonstrated that fatigue performance was adversely affected by the imposition of dwell periods at the peak of the load cycle and in selected microstructural variants of the alloy a reduction in fatigue life greater than an order of magnitude could be induced. Various features of those original studies at the RAE went on to form “standard practise” for subsequent practitioners investigating the dwell effect, not least the employment of a 2 minute hold time at peak load/stress to characterise dwell performance. A dwell fatigue assessment has since become an essential consideration for all new disc alloy development programmes
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
