Microstructural evolution of GCr15 steel during austenitizing and quenching considering C and Cr content

Qing-long Liu; Dong-sheng Qian; Wen-ting Wei

doi:10.1007/s11771-016-3308-5

Journal of Central South University ›› 2016, Vol. 23 ›› Issue (10) : 2492 -2499. DOI: 10.1007/s11771-016-3308-5

Materials, Metallurgy, Chemical and Environmental Engineering

Microstructural evolution of GCr15 steel during austenitizing and quenching considering C and Cr content

Author information +

History +

PDF

Abstract

Microstructural evolution of GCr15 steels with different C and Cr contents during austenitizing and quenching was studied. Thermodynamic analysis of cementite dissolution was implied to obtain the critical temperature. The coordination number x in Fe_xCr_3-xC and the volume fraction of undissolved cementite were computed according to element conservation and equilibrium phase diagram. The M_S (martensite transformation temperature) was calculated by using empirical formula. The retained austenite content was calculated with further consideration of quenching temperature. The results showed that the coordination number and the undissolved cementite content were promoted by the austenitizing temperature and carbon content of the steel. Increasing Cr element reduced the coordination number.GCr15 steels with different components had nearly the same M_S when austenitization at 830 °C to 860 °C. The interaction of C and Cr complicated the evolution of M_S and retained austenite content. The results were in good agreement with the literature, which could guide to obtain specified retained austenite and/or carbides.

Keywords

GCr15 steel / austenitization / quenching / thermodynamic calculation / kinetics

Cite this article

Download citation ▾

Qing-long Liu, Dong-sheng Qian, Wen-ting Wei. Microstructural evolution of GCr15 steel during austenitizing and quenching considering C and Cr content. Journal of Central South University, 2016, 23(10): 2492-2499 DOI:10.1007/s11771-016-3308-5

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	ChakrabortyJ, ChattopadhyayP P, BhattacharjeeD, MannaI. Microstructural refinement of bainite and martensite for enhanced strength and toughness in high-carbon low-alloy steel [J]. Metallurgical & Materials Transactions A, 2010, 41(11): 2871-2879

[2]	BarrowA T W, KangJ H, Rivera-Díaz-Del-CastilloP E J. The ∈→η→ε transition in 100Cr6 and its effect on mechanical properties [J]. Acta Materialia, 2012, 60(s6/7): 2805-2815

[3]	BhadeshiaH K D H. Steels for bearings [J]. Progress in Materials Science, 2012, 57(2): 268-435

[4]	MirandaR. Phase transformations in steels, Volume 1: Fundamentals and diffusion-controlled transformations [J]. International Journal of Environmental Studies, 2013, 70(2): 337-338

[5]	SongW, ChoiP P, IndenG, PrahlU, RaabeD, BleckW. On the spheroidized carbide dissolution and elemental partitioning in high carbon bearing steel 100Cr6 [J]. Metallurgical & Materials Transactions A, 2014, 45(2): 595-606

[6]	BeswickJ M. The effect of chromium in high carbon bearing steels [J]. Metallurgical & Materials Transactions A, 1987, 18(11): 1897-1906

[7]	MaQ, LuX-m, ZhangWen. Influence of quenching medium temperature on microstructure and mechanical properties of GCr15 steel [J]. Heat Treatment of Metals, 2011, 36(1): 80-83

[8]	DongX-ping. Duplex quenched structure of steel GCr15 and its influence on mechanical properties [J]. Bearing, 2013, 8: 33-38

[9]	MasonP W, PrevéyP S. Iterative taguchi analysis: Optimizing the austenite content and hardness in 52100 steel [J]. Journal of Materials Engineering & Performance, 2001, 10(1): 14-21

[10]	ZhouZ-f, WangX-y, GuJ-feng. Numerical simulation of eccentric cylinder quenching process [J]. Journal of Mechanical Engineering, 2011, 47(12): 62-63

[11]	YaoX, GuJ-f, HuM-j, ZhangWei. Numerical simulation of the quenching process of GCr15 steel tube [J]. Transactions of Metal Heat Treatment, 2003, 24(1): 78-81

[12]	ZhuLi. Simulation and analysis of quenching process for hollow cylindrical steel casting [J]. Foundry Technology, 2014, 35(1): 63-65

[13]	PerezM, SidoroffC, VincentA, EsnoufC. Microstructural evolution of martensitic 100Cr6 bearing steel during tempering: From thermoelectric power measurements to the prediction of dimensional changes [J]. Acta Materialia, 2009, 57(11): 3170-3181

[14]	LuzginovaN, ZhaoL, SietsmaJ. Evolution and thermal stability of retained austenite in SAE 52100 bainitic steel [J]. Materials Science & Engineering A, 2007, 448(s1/2): 104-110

[15]	PreciadoM, PellizzariM. Influence of deep cryogenic treatment on the thermal decomposition of Fe–C martensite [J]. Journal of Materials Science, 2014, 49(23): 8183-8191

[16]	MorraP V, BöttgerA J, MittemeijerE J. Decomposition of iron-based martensite: A kinetic analysis by means of differential scanning calorimetry and dilatometry [J]. Journal of Thermal Analysis & Calorimetry, 2001, 64(3): 905-914

[17]	YongQ-longThe second phases in steel and iron [M], 2006BeijingMetallurgical Industry Press

[18]	XuZ-yaoMartensitic transformation and martensite [M], 1980BeijingScience Press

[19]	WengW-shan. Experimental studies on the heat treatment process and performance of GCr4 and GCr15 steels [J]. Bearing, 1986, 2: 23-28

[20]	YeJ-y, GaoY-a, XieQian. Comparing analysis on impact toughness and contact fatigue life of GCr4 and GCr15 steels [J]. Bearing, 2003, 2: 30-32

[21]	LiC, WangJ-li. Research on bainite + martensite duplex microstructure and its mechanical properties in SAE 52100 bearing steel [J]. Iron and Steel, 1989, 24(5): 45-49