Effect of Surface Decarburization on Corrosion Behavior of GH3535 Alloy in Molten Fluoride Salts

doi:10.1007/s40195-018-0814-5

Abstract

Abstract:

Corrosion test of a Ni-16Mo-7Cr alloy with a decarburized layer was conducted in FLiNaK salt at 700 °C. A detailed microstructure study was performed to investigate the corrosion behavior and mechanisms. The results show that the Fe-rich layers were formed on the corroded alloys with and without decarburization. The surface decarburization had little influence on the corrosion resistance of the alloy, whereas it caused more M₂C carbide formation beneath the corrosion layer. That is attributed to the higher concentration of C gradient near the alloy surface, which was resulted from the increase in C content liberated from graphite crucible wall during the corrosion process.

Key words: Molten salt, Corrosion, Ni-based superalloys, Decarburization

Juan Hou, Fen-Fen Han, Xiang-Xi Ye, Bin Leng, Min Liu, Yan-Ling Lu, Xing-Tai Zhou. Effect of Surface Decarburization on Corrosion Behavior of GH3535 Alloy in Molten Fluoride Salts[J]. Acta Metallurgica Sinica (English Letters), 2019, 32(3): 401-412.

Figures/Tables 14

Table 1 Actual chemical compositions of alloy used in this study (wt%)

Ni	Mo	Cr	Fe	Mn	Si	C	Impurity element (ppm)
Ni	Mo	Cr	Fe	Mn	Si	C	S	P	O	N
Bal.	17.3	7.0	3.9	0.60	0.45	0.055	< 10	< 20	11	10

Table 2 Contents of trace impurities in as-received FLiNaK before exposing test (unit: ppm; mg/kg)

Fe	Ni	Cr	Mn	Mo
149.5 ± 7.5	60.8 ± 10.4	26.3 ± 0.6	12.9 ± 0.4	21.4 ± 3.0

Fig. 1 Schematic of experimental equipment

Fig. 2 Microstructures of a alloy 1, b alloy 2, c alloy 3 with different surface condition

Fig. 3 Cross section morphology and element distributions of alloy 2 after heat treatment at 1177 °C for 2 h (the color bar represents the degree of element enrichment)

Fig. 4 XRD analysis for surfaces of alloy 1, alloy 2, alloy 3 after corrosion

Fig. 5 Surface morphologies of a alloy 1, b alloy 2, c alloy 3 after corrosion at 700 °C for 400 h in FLiNaK salt and EDS analysis for d point A and e point B in a

Fig. 6 Cross section morphology and element distributions of alloy 1 after corrosion at 700 °C for 400 h in FLiNaK salt

Fig. 7 Cross section morphology and element distributions of alloy 2 after corrosion at 700 °C for 400 h in FLiNaK salt

Fig. 8 Cross section morphology and element distributions of alloy 3 after corrosion at 700 °C for 400 h in FLiNaK salt

Fig. 9 Cr element distributions of a alloy 1, b alloy 2, c alloy 3 from surface to substrate after corrosion at 700 °C for 400 h in FLiNaK salt

Fig. 10 TEM analysis for alloy 3 corroded at 700 °C for 400 h in FLiNaK salt: a FIB-SEM image and sampling position; b TEM image of subsurface area (5-6 μm away from surface, marked as “CD” in a; c SAED pattern for precipitates shown in b; d EDS analysis for precipitates shown in b

Fig. 11 TEM image and element distribution maps of rectangle area for alloy 3 corroded at 700 °C for 400 h in FLiNaK salt

Fig. 12 Schematic of M2C formation in decarburized layer: a microstructure and element distribution before corrosion test; b diffusion direction of elements during corrosion process; cM2C formation beneath corrosion layer

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