Abstract
Shot peening influence on alloys based on iron, aluminum, and titanium was studied using positron annihilation lifetime spectroscopy (PALS) and residual stress measurements. The PALS spectra were analyzed assuming two lifetime components. While the residual stresses change in a similar way in all the samples, the PALS results show an opposite tendency of a component relative intensities change with the time of shot peening for the Ti alloy as compared to steel or the Al alloy. A comparison between the depth profiles of positron implantation and the residual stress distribution reveals that the positron range covers a whole depth where residual stress is observed only in the Ti alloy. Based on this observation, the evolution of the defect concentration is presumed, consisting in migration of large defects away from the surface, while only smaller ones remain close to the surface. Furthermore, the positron lifetime distribution in the Al alloy was determined using the MELT program. The results showed that the initial single, wide distribution of lifetime splits into two narrower ones with increasing shot peening time.
Highlights
The safety of large-scale structures attracts considerable attention
Shot peening influence on alloys based on iron, aluminum, and titanium was studied using positron annihilation lifetime spectroscopy (PALS) and residual stress measurements
While the residual stresses change in a similar way in all the samples, the PALS results show an opposite tendency of a component relative intensities change with the time of shot peening for the Ti alloy as compared to steel or the Al alloy
Summary
The safety of large-scale structures (e.g., nuclear reactors or aircrafts) attracts considerable attention. An effective method for improving the properties of the surface layer of machine elements is shot peening. Shot peening plays a very important role in increasing the fatigue strength of machine elements made of various materials such as iron, aluminum, titanium, magnesium, and nickel. Its sensitivity to the size and concentration of defects predispose PALS for the study of shot-peened materials. It is confirmed by the results of our previous investigation that PALS is suitable to study the modifications of the steel surface layer [11, 12]. The positron energy spectrum and the properties of the studied material determine the positron implantation depth profile, which usually does not overlap the range of changes caused by shot peening. Measurements for samples after various periods of shot peening allow us to examine the change in the structure of the defects during the surface treatment, as made visible by PALS
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