Top

Journal of Iron and Steel Research International

Published in:

06-09-2022 | Original Paper

Effects of nano-ceramic additives on high-temperature mechanical properties and corrosion behavior of 310S austenitic stainless steel

Authors: Rong Zhu, Mai Wang, Zhen-li Mi, Qi Zhang, Xiao-yu Yang, Yong-gang Yang, Yan-xin Wu

Published in: Journal of Iron and Steel Research International | Issue 3/2023

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

A novel approach to reduce Ni content for the 310S austenitic stainless steel was proposed. The nano-ceramic additive (L) was applied to 310S steel to replace part of Ni element and reduce the cost. By means of thermal simulation, X-ray diffraction, field emission scanning electron microscopy, and electron backscattered diffraction, the effects of nano-ceramic additives on high-temperature mechanical properties and corrosion behavior of the 310S steel were studied. The results indicate that the morphology and density of the (Fe, Cr)₂₃C₆ carbides are varied, which play an important role in the high-temperature mechanical properties and corrosion behavior. After adding nano-ceramic additives, the high-temperature tensile strength and yield strength are improved simultaneously, in spite of a slight decrease in the total elongation. During high-temperature corrosion process, the mass gain of all the samples is parabolic with time. The mass gain is increased in the 310S steel with nano-ceramic additive, while the substrate thickness is significantly larger than 310S steel. The more stable and adherent FeCr₂O₄ spinel form is the reason why the high-temperature corrosion resistance was increased. The (Fe, Cr)₂₃C₆ carbides distribution along grain boundaries is detrimental to the high-temperature corrosion resistance.

previous article Insight on corrosion behavior of a Cu–P–Cr–Ni steel with different Ni contents by electrochemical and periodic immersion corrosion experiments

next article Effect of boron addition on microstructure and mechanical properties of an additively manufactured superalloy

[1]

Z. Zhang, Z.F. Hu, H.Y. Tu, S. Schmauder, G.X. Wu, Mater. Sci. Eng. A 681 (2017) 74–84.CrossRef

[2]

Y. Xiong, T.T. He, J.B. Wang, Y. Lu, L.F. Chen, F.Z. Ren, Y.L. Liu, A.A. Volinsky, Mater. Des. 88 (2015) 398–405.CrossRef

[3]

Y.G. Yang, W.Z. Mu, X.Q. Li, H.T. Jiang, M. Wang, Z.L. Mi, X.P. Mao, J. Iron Steel Res. Int. 29 (2022) 316–326.CrossRef

[4]

X.L. Song, C.H. Huang, J. Jia, J. Liu, J. Iron Steel Res. Int. 29 (2022) 1004–1011.CrossRef

[5]

X.G. Li, Z.P. Cai, X. Chen, S.Q. Dong, W.H. Cai, Y. Zhang, S.L. Li, K.J. Li, S.S. Rui, J.L. Pan, J. Iron Steel Res. Int. 28 (2021) 1439–1450.CrossRef

[6]

A. Col, V. Parry, C. Pascal, Corros. Sci. 114 (2017) 17–27.CrossRef

[7]

D. Singh, F. Cemin, M.J.M. Jimenez, V. Antunes, F. Alvarez, D. Orlov, C.A. Figueroa, S.S. Hosmani, Appl. Surf. Sci. 581 (2022) 152437.CrossRef

[8]

H.B. Wu, D. Wang, P.C. Zhang, J.M. Liang, S. Liu, D. Tang, J. Iron Steel Res. Int. 23 (2016) 231–237.CrossRef

[9]

A. Hayashi, N. Hiraide, Y. Inoue, Oxid. Met. 85 (2016) 87–101.CrossRef

[10]

N. Birks, G.H. Meier, F.S. Pettit, High-Temperature oxidation of metals, 2nd ed., Cambridge University Press, New York, USA, 2006.CrossRef

[11]

F. Yang, Y.L. Zhang, Y.N. Ren, W.M. Li, Welding of new heat resistant steel, China Electric Power Press, Beijing, China, 2006.

[12]

W.G. Zhai, W. Zhou, S.M.L. Nai, Mater. Sci. Eng. A 832 (2022) 142460.CrossRef

[13]

X. Han, Z.P. Zhang, S.J. Thrush, G.C. Barber, H.W. Qu, Wear 452–453 (2020) 203264.CrossRef

[14]

H. Zhang, W.X. Wang, F. Chang, C.L. Li, S.L. Shu, Z.F. Wang, X. Han, Q. Zou, F. Qiu, Q.C. Jiang, Mater. Sci. Eng. A 822 (2021) 141693.CrossRef

[15]

N. Li, C.X. Cui, Y.Q. Zhao, Q.X. Zhang, L.N. Bai, Mater. Sci. Eng. A 738 (2018) 63–74.CrossRef

[16]

Y.L. Han, T.L. Sun, X.G. Yuan, Ceramic nanoparticles additions for heat-resistant steel and preparation process, Chinese Patent, CN1876877, 2006.

[17]

D.Y. Qu, A high-temperature heat-resistant alloy and its preparation method, Chinese Patent, CN103088265B, 2015.

[18]

Z.Y. Zhang, Y.L. Gong, X.L. Wan, C.Z. Yang, Y.P. Xiao, Modern Cast Iron 29 (2009) No. 5, 50–52.

[19]

X.H. Liu, F.J. Wu, H.B. Wu, X.P. Ren, Hot Working Technology 42 (2013) No. 14, 60–63+70.

[20]

L.G. Zheng, X.Q. Hu, X.H. Kang, D.Z. Li, Acta Metall. Sin. 49 (2013) 1081–1088.CrossRef

[21]

Y.H. Deng, Y.H. Yang, C.B. Pu, K. Ni, X.Y. Pan, Acta Metall. Sin. 56 (2020) 949–959.

[22]

J. Li, Study on the preparation, structure and properties of new resource-saving high-Mn-N duplex stainless steels, Shanghai University, Shanghai, China, 2011.

[23]

Y.H. Park, Z.H. Lee, Mater. Sci. Eng. A 297 (2001) 78–84.CrossRef

[24]

S. Wang, Y. Wu, C.S. Ni, Y. Niu, Corros. Sci. 51 (2009) 511–517.CrossRef

[25]

J. Bischoff, A.T. Motta, J. Nucl. Mater. 424 (2012) 261–276.CrossRef

[26]

D. Young, High temperature oxidation and corrosion of metals, 2nd ed., Elsevier, Oxford, 2008.

[27]

M. Nezakat, H. Akhiani, S. Penttilä, J. Szpunar, ASME J. Nuclear Rad. Sci. 2 (2016) 021008.CrossRef

[28]

X.W. Cheng, Z.Y. Jiang, D.B. Wei, J.W. Zhao, B.J. Monaghan, R.J. Longbottom, L.Z. Jiang, Met. Mater. Int. 21 (2015) 251–259.CrossRef

[29]

L. Sun, J. Alloy. Compd. 875 (2021) 160065.CrossRef

[30]

D. West, J. Hulance, R.L. Higginson, G.D. Wilcox, Mater. Sci. Tech.-Lond. 29 (2013) 835–842.CrossRef

Title: Effects of nano-ceramic additives on high-temperature mechanical properties and corrosion behavior of 310S austenitic stainless steel
Authors: Rong Zhu
Mai Wang
Zhen-li Mi
Qi Zhang
Xiao-yu Yang
Yong-gang Yang
Yan-xin Wu
Publication date: 06-09-2022
Publisher: Springer Nature Singapore
Published in: Journal of Iron and Steel Research International / Issue 3/2023
Print ISSN: 1006-706X
Electronic ISSN: 2210-3988
DOI: https://doi.org/10.1007/s42243-022-00828-x

Springer Professional

Effects of nano-ceramic additives on high-temperature mechanical properties and corrosion behavior of 310S austenitic stainless steel

Abstract

Premium Partners

Springer Professional

Abstract

Please log in to get access to your license.

Other articles of this Issue 3/2023

Insight on corrosion behavior of a Cu–P–Cr–Ni steel with different Ni contents by electrochemical and periodic immersion corrosion experiments

Mineralization characteristics of pellets prepared by ultrafine magnetite concentrate: influence on metallurgical property and improving method

Effect of boron addition on microstructure and mechanical properties of an additively manufactured superalloy

MDA-JITL model for on-line mechanical property prediction

Strain hardening rate dependency of deformation shape, strain distribution, and contact pressure during wire flat rolling

Effects of MgO/Al2O3 and CaO/SiO2 ratios on viscosity of high titanium-bearing blast furnace slag

Premium Partners