Interface Evolution During Rolling of Ni-clad Stainless Steel Plate

doi:10.11901/1005.3093.2020.168

Chinese Journal of Materials Research

2021, Vol. 35

Issue (7): 493-500 DOI: 10.11901/1005.3093.2020.168

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Interface Evolution During Rolling of Ni-clad Stainless Steel Plate

FAN Jinhui¹, LI Pengfei¹^,², LIANG Xiaojun³, LIANG Jiangping²(

), XU Changzheng³, JIANG Li², YE Xiangxi², LI Zhijun²

^1.College of Mechanical Engineering, Donghua University, Shanghai 201620, China
^2.Shanghai Institute of Applied Physics, Dalian National Laboratory for Clean Energy Chinese Academy of Sciences (CAS), Shanghai 201800, China
^3.Baoshan Iron&Steel Co. , Ltd. , Shanghai 201900, China

Cite this article:

FAN Jinhui, LI Pengfei, LIANG Xiaojun, LIANG Jiangping, XU Changzheng, JIANG Li, YE Xiangxi, LI Zhijun. Interface Evolution During Rolling of Ni-clad Stainless Steel Plate. Chinese Journal of Materials Research, 2021, 35(7): 493-500.

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Abstract

Plate of Ni-clad 316H stainless steel was prepared via hot rolling process after pre-heating at 1200^oC for 120 minutes, then concurrently the rolling process was interrupted after rolling for 3, 5, and 7 passes respectively, while the relevant samples are taken and water-quenched for subsequent characterization in terms of the evolution of their interface-composition and -morphology, as well as the formed oxides there. Results show that until the 3rd rolling pass, the rolling plate temperature was about 1000°C, the two metals were closely bounded with equiaxed grains of slightly distorted microstructure on both sides of the interface and the inter-diffusion of elements for the two metals was not obvious; Until the 5th rolling pass, the plate temperature was about 940°C, the grains of 316H were elongated with significant lattice distortion, whereas, obvious inter-diffusion can be found near the interface; Until the 7th rolling pass, the plate temperature was about 880°C, large number of elongated and distorted grains were observed on the 316H steel side and a fine grain structure crushed by hot rolling distributed near the interface. The elements of Ni, Fe and Cr were fully inter-diffused near the interface, but the less motionable Mo enriched at the 316H side. The grains of Ni layer coarsened obviously. The interface evolution of Ni/stainless steel composite plate during the rolling process follows the so called three-stage theory and N. Bay's theory. The physical contact stage and the physical-chemical contact stage happened between the 3rd and 5th pass. Then the rolling from 5th to 7th pass was the final physical-chemical contact phase, whilst the inter-diffusion begins, that is, the "bulk" mutual phase begins. In the high-temperature and low-oxygen environment, the Mn oxides near the interface might form during the rolling process. The oxide was crushed and squeezed toward the substrate by the rolling force, therefore distributed in chains near the interface eventually.

Key words: surface and interface in the materials Ni-stainless steel clad plate microstructure hot rolling interface

Received: 19 May 2020

ZTFLH:

TG166.7

Fund: Natural Science Foundation of Shanghai(18ZR1448000);Shanghai Sailing Program(19YF1458300);National Natural Science Foundation of China(51671154);National Key Research and Development Program of China(2016YFB0700404);Youth Innovation Promotion Association of Chinese Academy of Science(2019264);Strategic Priority Research Program of Chinese Academy of Sciences(XD02004210)

About author: LIANG Jianping, Tel: (021)39191042, E-mail: liangjianping@sinap.ac.cn

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	Jinhui FAN
	Pengfei LI
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	Jiangping LIANG
	Changzheng XU
	Li JIANG
	Xiangxi YE
	Zhijun LI

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https://www.cjmr.org/EN/10.11901/1005.3093.2020.168 OR https://www.cjmr.org/EN/Y2021/V35/I7/493

Table 1 Composition of UNS N02201 sheet (mass fraction)

Table 2 Composition of UNS S31609 sheet (mass fraction)

Fig.1 Schematic diagram of the group blank process

Table 3 Rolling process reduction ratio

Fig.2 SEM photograph of the interface after rolling (a) 3 passes, (b) 5 passes, (c)7 passes

Fig.3 EBSD mapping after rolling (a) 3 passes, (b) 5 passes, (c) 7 passes

Fig.4 Mapping analysis of EPMA after rolling 3 passes

Fig.5 Mapping analysis of EPMA after rolling 5 passes

Fig.6 Mapping analysis of EPMA after rolling 7 passes

Chemical formula	$Δ f H m Θ$ /kJ·mol^-1	$Δ f G m Θ$ /kJ·mol^-1	$S m Θ$ /J·mol^-1·K^-1	$C p, m Θ$ /J·mol^-1·K^-1
O₂	0	0	205.1	29.3
Fe	0	0	27.3	25.1
Fe₂O₃	-824.2	-742.2	87.4	103.8
Fe₃O₄	-1118.4	-1015.4	146.4	143.4
FeO	-266.5	-244.3	54.0	51.1
Ni	0	0	29.9	26.1
NiO	-244.3	-211.7	38.0	24. 9
Cr	0	0	23.8	23.4
Cr₂O₃	-1139.7	-1058.1	81.2	118.7
Mn	0	0	32.0	26.3
MnO	-384.9	-362.9	59.7	24.9

Table 4 Thermodynamic parameters of the substance formulas at 298.15 K ^{[19, 20]}

Fig.7 Gibbs free energy of reverse oxidation with temperature

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