Effects of cutting parameter on microstructure and corrosion behavior of 304 stainless steel in simulated primary water

doi:10.1016/j.jmst.2021.04.081

Abstract

Abstract:

The influence of surface conditions on the corrosion behavior of engineering structures has been paid more attention. However, there is still a lack of systematic research on the effect of cutting parameters on material's microstructure and performance in service. In this paper, the effect of cutting parameters on microstructure and corrosion behaviors of 304 stainless steel in simulated primary water is well investigated. The results show that different cutting parameters can cause the superficial layer a gradient microstructure with nanocrystalized layer on top and deformation band structures underneath. With the similar surface roughness, the deformation microstructure can be very different due to the different cutting parameters. The effect degree on the depth of deformation zone is feed rate > cutting depth > cutting speed. The larger feed rate, lower cutting depth, lower cutting rate may induce a deeper deformation zone. With the increasing depth away from the machined surface, the localized corrosion rate is decreased, and at the same depth the localized corrosion rate along the deformation bands is higher than that along the grain boundaries (GBs). The nanocrystalized surface has a smallest general corrosion rate due to the quick formation of Cr rich oxide film. However, once the corrosion penetrates through this nanocrystalized layer, subsequent preferential corrosion at deformation bands and GBs will dominate and may lead to the significant increase of corrosion rate of the component in high temperature pressurized water.

Key words: Stainless steel, Transmission electron microscopy (TEM), High temperature corrosion, Cutting parameter

Honglin Yan, Jianqiu Wang, Zhiming Zhang, Bright O. Okonkwo. Effects of cutting parameter on microstructure and corrosion behavior of 304 stainless steel in simulated primary water[J]. J. Mater. Sci. Technol., 2022, 122: 219-230.

Figures/Tables 17

Table 1. Chemical composition of 304SS (wt.%).

C	Cr	Ni	N	Mn	Si	S	P	Fe
0.053	18.45	8.30	0.057	1.59	0.47	0.004	0.022	Bal.

Table 2. Cutting parameters and the corresponding surface roughness (Ra).

Num.	Feed rate(mm/r)	Cutting speed(r/min)	Cutting depth(mm)	Ra(μm)
1	0.50	140	1	74.7
2	0.15	140	1	14.1
3	0.20	140	1	30.2
4	0.20	280	1	17.4
5	0.20	450	1	27.1
6	0.20	450	0.5	16.3
7	0.20	450	0.2	25.2

Fig. 1. (a) Machining cutting process of NG 304 SS. Cutting fluid was used to avoid overheat of the sample surface; (b) test samples. All the samples were cut from the same position of the machined plates.

Fig. 2 Three-dimensional morphology of the machined samples. (a)-(g) are the machined samples labeled #1 to #7 respectively. Machining characters like peak, valley and feed direction are denoted by arrows.

Fig. 3. (a)-(g) Cross-sectional metallographs of machined samples, with numbered #1 to #7 respectively. Machining-produced characteristics such as “peak”, “valley”, slip band, deformed GB, broken chip are all identified in the photograph.

Fig. 4. EBSD analysis of cross-sectional deformation of the machined samples, including (a) band contrast (BC) map, (b) inverse pole figure (IPF), and (c) kernel average misorientation (KAM) map. Samples from #1 to #7 are arranged in order from left to right.

Fig. 5. (a) Effect of feed rate on the distribution of the cross-sectional hardness. The cutting speed (Vc) is 140 r/min, the cutting depth (ap) is 1 mm, and the feed rate (f) is 0.50 m m/r, 0.20 mm/r, 0.15 mm/r respectively; (b) Effect of cutting speed on the cross-sectional hardness. The feed rate is 0.20 m m/r, the cutting depth is 1 mm, and the cutting speed is 450 r/min, 300 r/min, 140 r/min respectively; (c) Effect of cutting speed on the cross-sectional hardness. The cutting speed is 450 r/min, the feed rate is 0.20 mm/r, and the cutting depth is 1.0 mm, 0.5 mm, and 0.2 mm respectively.

Fig. 6. (a) Schematic diagram of sampling in different areas of Sample #5. Samples are taken from the surface, the deformation zone about 50 μm from the surface, and the substrate 300 μm from the surface; (b) The sample preparation process using FIB, where b-1, b-2, b-3 is the ion beam cutting process at three sampling positions.

Fig. 7. (a) Bright field (BF) micrograph of the microstructure of the machined surface; (b) Selected electron diffraction of the nanocrystalline region; (c) Dark-field micrograph of the nanocrystalline region; (d) Local BF micrograph of the nanocrystalline region and the corresponding SADP.

Fig. 8. (a) The bright-field micrograph of the FIB sample in the machining-affected zone (MAZ); (b) The corresponding selected area electron diffraction of the deformation bands; (c) Dark field image of the twin.

Fig. 9. Bright field TEM micrograph representative of 304 stainless steel substrate (operating vector g = 200).

Fig. 10. (a) FIB sampling of the surface of Sample #5; (b) TEM bright field scanning transmission micrograph of the corrosion sample with big oxide particle on top and SADP of the area below big particle; (c) Selected area electron diffraction of the big oxide particle and the corresponding EDS analysis; (d) TEM dark field scanning transmission micrograph of the corrosion sample; (e) EDS line scan analysis on the cross-section oxide film. In scanning transmission mode, the electron beam spot size is 1.5 nm, and the scanning step size is 2 nm.

Fig. 11. (a) Morphology and FIB sampling at the deformed area of Sample #5 after corrosion; (b) TEM bright-field scanning transmission micrograph; (c) TEM dark-field scanning transmission micrograph.

Fig. 12. (a) BF micrograph shows corrosion morphology of the grain boundary in the deformed area of Sample #5; (b) high magnification of oxides morphology at the tip of grain boundary corrosion front; (c) EDS mapping results of Cr, Fe, Ni, O elements in GB corrosion area.

Fig. 13. (a) TEM bright-field corrosion morphology at the deformed zone of Sample #5, with the inserted selected area electron diffraction pattern; (b) high-angle annular dark field (HAADF) image of the deformation twin corrosion area; (c) EDS mapping analysis of Cr, Fe, Ni, and O elements; (d) EDS line scan analysis across the corroded deformation twin. Under scanning transmission mode, the electron beam spot size is 1.5 nm, and the scanning step size is 2 nm.

Fig. 14. (a) Schematic diagram of FIB sampling of the cross-section of Sample #5; (b) the cross-sectional morphology after the FIB milling; (c)-(e) the high-magnification photo of the I, II, and III regions in (b).

Fig. 15. Comparison of the corrosion behaviors of different microstructure of Sample #5. A, B&E represent the general corrosion rate of the fine-grain region, plastic deformation region and substrate material respectively. C&D represent the localized corrosion rate along grain boundary, deformation bands in the same depth of deformation region.

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