Quantitative Characterization of the Changes in Surface Topography of Austenitic Stainless Steel under Low Cycle Fatigue Loading

Abstract

Low-cycle fatigue tests of SUS316NG austenitic stainless steel were conducted for several strain ranges (0.76, 1.26, 2.1, 4.1, and 8.1%) in which the specimen’s surface topography was regularly measured using a laser scanning microscope. The surface topographies obtained were analyzed by frequency analysis to separate the surface relief due to persistent slip bands (PSBs) from that due to crystal grain deformation. The PSBs-induced surface relief evolution and the grain-deformation-induced one were quantitatively evaluated by using arithmetic mean roughness R_a and arithmetic mean waviness W_a, respectively. The ΔR_a and ΔW_a, the increments in R_a and W_a from the initial values, increased with the usage factor (UF) for each strain range. Moreover, the rates of increase in ΔR_a and ΔW_a with respect to UF increased with the strain range. ΔW_a/ΔR_a was larger for higher strain ranges. This tendency of ΔW_a/ΔR_a indicates that the surface relief due to grain deformation develops more prominently than that due to PSBs for larger strain ranges. The results for R_a and W_a agree with the results of surface topography observation. On the basis of these results, a method was developed for estimating the UF of fatigued material and the applied strain range by using only the measured R_a and W_a.