Browse > Article
http://dx.doi.org/10.9729/AM.2016.46.1.45

Deformation Behavior of Corrosion-Resistant Fe-Cr Alloy  

Era, Hidenori (Department Materials Science and Engineering, Kyushu Institute of Technology)
Kono, Yusuke (Graduate School, Kyushu Institute of Technology)
Sasabuchi, Ryota (Graduate School, Kyushu Institute of Technology)
Miyoshi, Noriko (Graduate School, Kyushu Institute of Technology)
Tokunaga, Tatsuya (Department Materials Science and Engineering, Kyushu Institute of Technology)
Shinozaki, Nobuya (Department of Life Science and Systems Engineering, Kyushu Institute of Technology)
Lee, Je-Hyun (School of Materials Science and Engineering, Changwon National University)
Shimozaki, Toshitada (Engineering Research Center, Changwon National University)
Publication Information
Applied Microscopy / v.46, no.1, 2016 , pp. 45-50 More about this Journal
Abstract
Iron containing a high amount of chromium is known to be inferior to ductility due to ${\sigma}$ phase formation so that it is generally difficult to apply the plastic deformation process although the alloy possesses a superior characteristics of an excellent corrosion resistance. In this study, Fe-50mass%Cr alloy was melted using high purity powder and the deformation behavior has been investigated by cold rolling and tensile test. The tensile test yielded that the alloy revealed a serration at an early stage of tensile deformation and then the serrated flow vanished to change to a normal work hardening flow at the later stage. The former was governed by twin formation process, the latter by dislocation multiplication one, bringing about a high ductility of 20% or over. The reduction ratio in cold rolling was attained as high as 90%, thus the high corrosion-resistant alloy is able to possess a high ductility.
Keywords
Iron chromium alloy; Laser melting; Deformation behavior; Corrosion resistance;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Abiko K (1995) Research on high purity Fe-Cr alloys. In: Ultra High Purity Base Metals, Proceedings of the First International Conference on Ultra-High Purity Base Metals (UHPM-1994), eds. Abiko K, Hirokawa K, and Takaki S, pp. 522-523, (The Japan Institute of Metals, Sendai).
2 Abiko K and Kato Y (1998) Properties of a high-purity Fe-50 mass% Cr alloy. Phys. Stat. Sol. (a) 167, 449-461.   DOI
3 Fukuda T, Kataura Y, and Ototani T (1990) Effects of carbide and nitride precipitates on mechanical properties of Fe-30%Cr alloys. J. Jpn. Inst. Metals 54, 93-100.   DOI
4 Kako K, Isozaki S, Takaki S, and Abiko K (1998) Deformation mechanisms in high-purity Fe-50Cr(-5W) alloys at elevated temperatures. Phys. Stat. Sol. (a) 167, 481-494.   DOI
5 Kato Y, Ujiro T, Satoh S, Yamato K, and Abiko K (1995) Influence of carbon and nitrogen on corrosion resistance of high purity Fe-50mass%Cr alloy. J. Physique IV 5, C7-403-407.
6 Leslie W C (1981) The Physical Metallurgy of Steels, pp. 337-340, (McGraw-Hill, New York).
7 Maykuth D J and Jaffee R J (1955) Ductile Chromium and Its Alloys, p. 229, (ASM, Materials Park).
8 Takaku H, Kato S, Tani J, and Abiko K (1995) Stress corrosion cracking sensitivity of high purity Fe-Cr alloys in high temperature water. J. Physique IV 5, C7-397-402.   DOI
9 Tetsui T, Shinohara M, and Abiko K (1997) Aging properties of ultra-highpurity Fe-High-Cr alloys. Phys. Stat. Sol. (a) 160, 459-467.   DOI
10 Yano K and Abiko K (1997) Formation of ${\sigma}$ phase in highly purified Fe-Cr alloys. Phys. Stat. Sol. (a) 160, 449-457.   DOI
11 Yokota T, Satoh S, Kato Y, and Abiko K (1998) Corrosion resistance of a high purity Fe-50 mass% Cr alloy. Phys. Stat. Sol. (a) 167, 495-502.   DOI