钛对非调质塑料模具钢奥氏体晶粒长大规律的影响<sup>*</sup>

doi:10.11896/j.issn.1005-023X.2017.08.017

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Abstract The demand of automotive and appliance industry for high-quality large section plastic mold steel is gradually increased. However, with the increase of the thickness of plastic mold steel, the possibility of the occurrence of coarse grain is also increased, which calls for a reasonable design of heat treatment process. The austenite grain growth behavior during high temperature treatment was hindered by adding titanium, and the effects of Ti addition on austenite grain growth behavior of non-quenched and tempered (NQT) plastic mold steel were emphatically studied. The results show that the NQT plastic mold steel containing 0.03% Ti has better resistance to grain coarsening when the homogenization temperature is higher than 1 050 ℃, due to the Ti(C, N) precipitation disperse around the grain boundaries. Based on the experimental results, the mathematical models of grain growth were established, which can be used to predict the austenite grain growth of NQT plastic mold steel during high temperature homogenization.

Key words： micro-alloying non-quenched and tempered steel austenization precipitation

Published: 25 April 2017 Online: 2018-05-02

CLC number:

TG142.1

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	Articles by authors
	ZHENG Yafeng
	LI Xiaocheng
	WU Riming
	WU Xiaochun

Cite this article:

ZHENG Yafeng,LI Xiaocheng,WU Riming, et al. Influence of Ti on Grain Growth Behavior of Non-quenched and Tempered Plastic Mold Steel[J]. Materials Reports, 2017, 31(8): 82-87.

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https://www.mater-rep.com/EN/10.11896/j.issn.1005-023X.2017.08.017 OR https://www.mater-rep.com/EN/Y2017/V31/I8/82

1 Duan L L, Zhang Z, Li X C, et al. Transformation process and kinetics in a new plastic mould of bainite steel SDP2[J]. Trans Mater Heat Treatment,2015,36(8):174(in Chinese).
段丽丽, 张铮, 李晓成, 等. SDP2新型贝氏体模具钢的相变及动力学[J]. 材料热处理学报,2015,36(8):174.
2 Wu R M, Zheng Y F, Wu X C, et al. Effect of titanium on the microstructure and hardness uniformity of non-quenched and tempered pre-hardened steel for large-section plastic mould[J]. Ironmaking Steelmaking,2017,44(1):17.
3 Zhang Z, Wu X C, Zhou Q, et al. Effect of microstructure on the impact toughness of a bainitic steel bloom for large plastic molds[J]. Int J Mine Metal Mater,2015,22(8):842.
4 Wu X C, Cui K. Effect of V, Ti on the microstructures and mecha-nical properties of unquenched and un-tempered die steel for plastic mold[J]. Mater Mech Eng,1997,21(6):16(in Chinese).
吴晓春, 崔崑.钒、钛对非调质塑料模具钢组织与性能的影响[J]. 机械工程材料,1997,21(6):16.
5 Wu X C, Cui K. Preciptated phase in unquenched and un-tempered die steel for plastic mould[J]. Iron Steel,1998,33(6):50(in Chinese).
吴晓春, 崔崑. 非调质塑料模具钢中析出相的研究[J]. 钢铁,1998,33(6):50.
6 Luo Y, Wu X C, Wang H B, et al. Study on microstructure and hardness uniformity of non-quenched prehardened steel for large section plastic mould[J]. Mater Sci Eng A,2008,492:205.
7 Luo Y, Wu X C, Wang H B, et al. A comparative study on non-quenched and quenched prehardened steel for large section plastic mould[J]. J Mater Process Technol,2009,209:5437.
8 Luo Y, Peng J M, Wang H B, et al. Effect of tempering on microstructure and mechanical properties of a non-quenched bainitic steel[J]. Mater Sci Eng A,2010,527:3433.
9 Zhang Z, Wu X C, Li N, et al. Alloy optimisation of bainitic steel for large plastic mould[J]. Mater Sci Technol,2015,31(14):1706.
10 Ma H, Liao S L. Effect of Ti on austenite grain growth behavior in high carbon steels[J]. J Iron Steel Res Int,2014,21(7):702.
11 Gomez M, Rancel L, Escudero E, et al. Phase transformation under continuous cooling conditions in medium carbon micro-alloyed steels[J]. J Mater Sci Technol,2014,30(5):511.
12 Gu Y, Tian P, Wang X, et al. Non-isothermal prior austenite grain growth of a high-Nb X100 pipeline steel during a simulated welding heat cycle process[J]. Mater Des,2016,89:589.
13 Olasolo M, Uranga P, Rodriguez-Ibabe J M, et al. Effect of auste-nite microstructure and cooling rate on transformation characteristics in a low carbon Nb-V micro-alloyed steel[J]. Mater Sci Eng A,2011,528:2559.
14 Pous-Romero H, Lonardelli I, et al. Austenite grain growth in a nuclear pressure vessel steel[J]. Mater Sci Eng A,2013,567:72.
15 Fu L M, Shan A D, Wang W. Effect of Nb solute drag and NbC precipitate pinning on the recrystallization grain growth in low carbon Nb-micro-alloyed steel[J]. Acta Metall Sinica,2010,46(7):832(in Chinese).
付立铭, 单爱党, 王巍. 低碳Nb微合金钢中Nb溶质拖曳和析出相NbC钉扎对再结晶晶粒长大的影响[J]. 金属学报,2010,46(7):832.
16 Geng W, Sun X J, Yong Q L, et al. Austenite grain refinement and isothermal growth behavior in a low carbon vanadium micro-alloyed steel[J]. J Iron Steel Res Int,2014,21(8):757.
17 Sha Q Y, Sun Z Q. Grain growth behavior of coarse-grained auste-nite in a Nb-V-Ti micro-alloyed steel[J]. Mater Sci Eng A,2009,523(1-2):77.
18 Duan L N, Wang L M, Liu Q Y, et al. Austenite grain growth behavior of X80 pipeline steel in heating process[J]. J Iron Steel Res Int,2010,17(3):62.
19 Sun L F, Wang F M, Tao S F, et al. Austenite grain growth beha-vior of locomotive wheel steel[J]. J University of Science and Technology Beijing,2014,36(3):301(in Chinese).
孙乐飞, 王福明, 陶素芬, 等. 机车车轮用钢奥氏体晶粒的长大行为[J]. 北京科技大学学报,2014,36(3):301.
20 Li W, Chen W L, Wu Y, et al. Austenite grain growth of 42CrMo steel during heating[J]. Trans Mater Heat Treatment,2015,36(1):104(in Chinese).
李伟, 陈文琳, 吴跃, 等. 42CrMo钢加热时奥氏体晶粒长大演化规律[J]. 材料热处理学报,2015,36(1):104.
21 Zhang S S, Li M Q, Liu Y G, et al. The growth behavior of auste-nite grain in the heating process of 300M steel[J]. Mater Sci Eng A,2011,528:4967.
22 Shi Z R, Yang C F, Wang R Z, et al. Effect of nitrogen on the microstructures and mechanical properties in simulated CGHAZ of vanadium micro-alloyed steel varied with different heat inputs[J]. Mater Sci Eng A,2016,649:270.
23 Zhang L, Kannengiesser T. Austenite grain growth and microstructure control in simulated heat affected zones of micro-alloyed HSLA steel[J]. Mater Sci Eng A,2014,613:326.
24 Moon J, Lee C. Pinning efficiency of austenite grain boundary by a cubic shaped TiN particle in hot rolled HSLA steel[J]. Mater Cha-ract,2013,73:31.
25 Herbst S, Besserer H B B. Holistic consideration of grain growth behavior of tempering steel 34CrNiMo6 during heating processes[J]. J Mater Process Technol,2016,229:61.
26 Li J R, Song M Q, Gong C, et al. Grain growth behavior of blade steel KT5331 for ultra-super critical units[J]. Chinese J Eng,2015,37(12):1570(in Chinese).
李俊儒, 宋明强, 龚臣, 等. 超超临界机组叶片钢KT5331晶粒长大行为[J]. 工程科学学报,2015,37(12):1570.