Effect of Nanometer-Sized Carbides and Grain Boundary Density on Performance of Fe-C-Mo-M(M=Nb, V or Ti) Fire Resistant Steels

doi:10.11901/1005.3093.2014.789

Chinese Journal of Materials Research

2015, Vol. 29

Issue (4): 269-276 DOI: 10.11901/1005.3093.2014.789

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Effect of Nanometer-Sized Carbides and Grain Boundary Density on Performance of Fe-C-Mo-M(M=Nb, V or Ti) Fire Resistant Steels

Zhengyan ZHANG^1,²,Xinjun SUN¹,Zhaodong LI¹,Xiaojiang WANG³,Qilong YONG^1,^**(

),Guodong WANG²

1. Department of Structurale Steels, Central Iron and Steel Research Institute, Beijing 100081, China
2. State key Laboratory of Rolling and Automation, Northeastern University, Shenyang 110004, China.
3. Department of Materials Science and Engineering, Kunming University of Science and Technology, Kunming 650093, China

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Zhengyan ZHANG,Xinjun SUN,Zhaodong LI,Xiaojiang WANG,Qilong YONG,Guodong WANG. Effect of Nanometer-Sized Carbides and Grain Boundary Density on Performance of Fe-C-Mo-M(M=Nb, V or Ti) Fire Resistant Steels. Chinese Journal of Materials Research, 2015, 29(4): 269-276.

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Abstract

Fe-C-Mo-M steels (where M is Nb, V or Ti, ~0.1%, and Mo ≤0.2% ) were produced by thermal mechanical control processing (TMCP), and then their performance was characterized in terms of failure temperature by means of constant load tensile test while heating from ambient temperature up to 800^oC with a heating rate 28^oC/min. The boundary misorientation of the steels after TMCP was examined by electron back scattered diffraction (EBSD), and the precipitates of MC type carbides were characterized by transmission electron microscopy (TEM). The results show that the addition of 0.2% Mo in Fe-C-Nab/V steels increases the failure temperature of steels by 40℃. It is believed that the low-angle grain boundary provided the favorable nucleation site for MC type carbides, which in turn will accelerate the kinetics of precipitation process. The fine and dispersed precipitates of MC type carbides induce significant precipitation strengthening for the steels during the constant load tensile process, thus resulting in higher failure temperature. Among the tested steels, the failure temperature of Ti-Mo steel is the highest due to its highest low-angle grain boundary density which results in the fast precipitation of MC type carbides. The failure temperature of Nb-Mo steel comes the second and that of the V-Mo steels is the lowest because of its lowest low angle grain boundary density leading to the lowest density of precipitated MC type carbides.

Key words: metallic material intelligent fire resistant steel failure temperature precipitation strengthening low-angle grain boundary density nanometer-sized carbide

Received: 30 December 2014

Fund: *Supported by National Basic Research Program of China No. 2010CB630805 and National Natural Science Foundation of China No. 51201036.

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	Zhengyan ZHANG
	Xinjun SUN
	Zhaodong LI
	Xiaojiang WANG
	Qilong YONG
	Guodong WANG

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https://www.cjmr.org/EN/10.11901/1005.3093.2014.789 OR https://www.cjmr.org/EN/Y2015/V29/I4/269

Table 1 Chemical composition of tested steels (%, mass fraction)

Fig.1 Stain-Temperature curves of tested steels

Table 2 Microstructure amount of MC phase (at 600℃) and the failure temperature of tested steels

Fig.2 SEM images for different tested steels (a) V, (b) V-Mo, (c) Nb, (d) Nb-Mo, (e) Ti-Mo, (f) Low-Nb-Mo

Fig.3 Grain boundary distribution of tested steels (a) V, (b) V-Mo, (c) Nb, (d) Nb-Mo, (e) Ti-Mo, (f) Low-Nb-Mo

Fig.4 Total grain boundary density of tested steels VS the misorientation of ferrite grain ranged of 0~61°, in step of 5°(the inserted figture shows the grain boundary density of tested steels VS the misorientation of ferrite grain ranged of 0-15°, in step of 2°)

Fig.5 TEM images of precipitates in rolled samples for (a) Nb-Mo steel, (c) V-Mo steel, (e) Ti-Mo steel and in constant load tensile samples for (b) Nb-Mo steel, (d) V-Mo steel, (f) Ti-Mo steel

Fig.6 Distribution density of precipitates in (a) Nb-Mo, (b) V-Mo, (c) Ti-Mo steels after constant load tensile

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