王明明,肖亚茹,琚立颖,徐连波,张好强,侯锁霞,李耀刚

• 1:华北理工大学机械工程学院

摘要(Abstract)：

高强度轨道用钢包括钢轨钢、辙叉钢等,传统的珠光体钢轨钢及奥氏体辙叉钢已经无法满足高速重载铁路的发展,取而代之的必将是新型高强度贝氏体钢。本文是在高强度贝氏体钢中的残留奥氏体(Ⅰ)的基础上,以轨道用钢为研究对象,详细综述了贝氏体钢中残留奥氏体对轨道用钢使用性能的影响,主要包括残留奥氏体对贝氏体轨道钢常规性能、抗滚动接触疲劳性能、耐磨性能以及拉压疲劳性能的影响,使得贝氏体钢中的残留奥氏体得到重视并为高强度贝氏体轨道钢的研发提供依据。

关键词(KeyWords)： 贝氏体钢;残留奥氏体;强度;韧性;耐磨性

Abstract:

Keywords:

基金项目(Foundation): 河北省教育厅青年拔尖人才计划项目(BJ2019010)

作者(Author): 王明明,肖亚茹,琚立颖,徐连波,张好强,侯锁霞,李耀刚

DOI: 10.13289/j.issn.1009-6264.2019-0213

参考文献(References)：

• [1] Wang M,Zhang F,Yang Z. Effects of high-temperature deformation and cooling process on the microstructure and mechanical properties of an ultrahigh-strength pearlite steel[J].Materials and Design,2017,114:102-110.
• [2] Chen C,Lv B,Wang F,et al.Low-cycle fatigue behaviors of pre-hardening hadfield steel[J].Materials Science and Engineering A,2017,695:144-153.
• [3] Clayton P,Devanathan R.Rolling sliding wear behavior of a chromium molybdenum rail steel in pearlitic and bainitic conditions[J].Wear,1992,156(1):121-131.
• [4] Hui W,Xu Z,Zhang Y,et al.Hydrogen embrittlement behavior of high strength rail steels:A comparison between pearlitic and bainitic microstructures[J].Materials Science and Engineering A,2017,704:199-206.
• [5] Kang J,Zhang F C,Long X Y,et al. Low cycle fatigue behavior in a medium-carbon carbide-free bainitic steel[J]. Materials Science and Engineering A,2016,666:88-93.
• [6] Zhang F C,Long X Y,Kang J,et al.Cyclic deformation behaviors of a high strength carbide-free bainitic steel[J].Materials and Design,2016,94:1-8.
• [7] Bhadeshia H K D H.Steels for rails,Novel[J].Encyclopedia of Materials Science and Technology,2002:1-7.
• [8] Tan Z L,Wang K K,Gao G H,et al.Mechanical properties of steels treated by Q-P-T process incorporating carbide-free-bainite/martensite multiphase microstructure[J].Journal of Iron and Steel Research International,2014,21(2):191-196.
• [9] Wang Y,Zhang K,Guo Z H,et al.A new effect of retained austenite on ductility enhancement in high strength bainitic steel[J].Materials Science and Engineering A,2012,552(34):288-294.
• [10] Wang K,Tan Z,Gao G,et al.Ultrahigh strength-toughness combination in Bainitic rail steel:The determining role of austenite stability during tempering[J].Materials Science and Engineering A,2016,662:162-168.
• [11] Gao G,Zhang H,Gui X,et al.Tempering behavior of ductile 1700 MPa Mn-Si-Cr-C steel treated by quenching and partitioning process incorporating bainite formation[J].Journal of Materials Science and Technology,2015,31(2):199-204.
• [12] Zhou S,Zhang K,Wang Y,et al. High strength-elongation product of Nb-microalloyed low-carbon steel by a novel quenchingpartitioning-tempering process[J].Materials Science and Engineering A,2011,528(27):8006-8012.
• [13] Zhou Q,Qian L H,Tan J,et al. Inconsistent effects of mechanical stability of retained austenite on ductility and toughness of transformation-induced plasticity steels[J].Materials Science and Engineering A,2013,578:370-376.
• [14] De Meyer M,De Cooman B C,Vanderschueren D.The influence of Al on the properties of cold rolled C-Mn-Si TRIP steels[J].Iron and Steelmaker,2000,27(2):55-63.
• [15] Timokhina I B,Hodgson P D,Pereloma E V.Effect of deformation schedule on the microstructure and mechanical properties of a thermomechanically processed C-Mn-Si transformation-induced plasticity steel[J]. Metallurgical and Materials Transactions A,2003,34(8):1599-1609.
• [16] Caballero F G,Bhadeshia H K D H,Mawella K J A,et al.Design of novel high strength bainitic steels:Part 2[J].Materials Science and Technology,2001,17(5):517-522.
• [17] Rao P P,Putatunda S K. Influence of microstructure on fracture toughness of austempered ductile iron[J]. Metallurgical and Materials Transactions A,1997,28(7):1457-1470.
• [18] Zhang M X,Kelly P M.Stress-induced martensitic transformation and impact toughness of cast irons and high-carbon Fe-Ni-C steel[J].Metallurgical and Materials Transactions A,2001,32(11):2695-2708.
• [19] Shiue R K,Lan K C,Chen C.Toughness and austenite stability of modified 9Cr-1Mo welds after tempering[J].Materials Science and Engineering A,2000,287(1):10-16.
• [20] Qian L H,Zhou Q,Zhang F C,et al.Microstructure and mechanical properties of a low carbon carbide-free bainitic steel co-alloyed with Al and Si[J].Materials and Design,2012,39:264-268.
• [21] Gao G H,Zhang H,Gui X L,et al.Enhanced ductility and toughness in an ultrahigh-strength Mn-Si-Cr-C steel:The great potential of ultrafine filmy retained austenite[J].Acta Materialia,2014,76:425-433.
• [22] Li Y C,Zhang Y S,Li D Q.Shrinkage analysis of injection-compression molding for transparent plastic panel by 3D simulation[J].Applied Mechanics and Materials,2010,44-47:1029-1033.
• [23] Bhadeshia H K D H,Edmonds D V.Bainite in silicon steels:new composition-property approach Part 1[J].Metal Science,2013,17(9):411-419.
• [24] Bhadeshia H K D H,Edmonds D V.Bainite in silicon steels:new composition-property approach Part 2[J].Metal Science,2013,17(9):420-425.
• [25] Hasan S M,Chakrabarti D,Singh S B.Dry rolling/sliding wear behaviour of pearlitic rail and newly developed carbide-free bainitic rail steels[J].Wear,2018,408-409:151-159.
• [26] Chang L C.The rolling/sliding wear performance of high silicon carbide-free bainitic steels[J].Wear,2005,258(5/6):730-743.
• [27] Viafara C C,Castro M I,Velez J M,et al.Unlubricated sliding wear of pearlitic and bainitic steels[J].Wear,2005,259(1/6):405-411.
• [28] Zheng C L,Dan R,Zhang F C,et al.Effects of retained austenite and hydrogen on the rolling contact fatigue behaviours of carbide-free bainitic steel[J].Materials Science and Engineering A,2014,594:364-371.
• [29] Leiro A,Vuorinen E,Sundin K G,et al.Wear of nano-structured carbide-free bainitic steels under dry rolling-sliding conditions[J].Wear,2013,298-299:42-47.
• [30] Leiro A,Kankanala A,Vuorinen E,et al.Tribological behaviour of carbide-free bainitic steel under dry rolling/sliding conditions[J].Wear,2011,273(1):2-8.
• [31] Solano-Alvarez W,Pickering E J,Bhadeshia H K D H.Degradation of nanostructured bainitic steel under rolling contact fatigue[J].Materials Science and Engineering A,2014,617:156-164.
• [32] Solano-Alvarez W,Pickering E J,Peet M J,et al.Soft novel form of white-etching matter and ductile failure of carbide-free bainitic steels under rolling contact stresses[J].Acta Materialia,2016,121:215-226.
• [33] Bhadeshia H K D H.Steels for bearings[J].Progress in Materials Science,2012,57(2):268-435.
• [34] Solano-Alvarez W,Duff J,Smith M C,et al.Elucidating white-etching matter through high-strain rate tensile testing[J]. Metal Science Journal,2016,33(3):307-310.
• [35] Zhang F C,Lv B,Zheng C L,et al.Microstructure of the worn surfaces of a bainitic steel railway crossing[J].Wear,2010,268(11/12):1243-1249.
• [36] Wang J,Wolf D,Phillpot S R,et al.Computer simulation of the structure and thermo-elastic properties of a model nanocrystalline material[J].Philosophical Magazine A,1996,73(3):517-555.
• [37] Jang J S C,Koch C C. Amorphization and disordering of the Ni3Al ordered intermetallic by mechanical milling[J]. Journal of Materials Research,1990,5(3):498-510.
• [38] Padmanabhan K A,Sankaran S.Fatigue behavior of a multiphase medium carbon V-bearing microalloyed steel processed through two thermomechanical routes[J].Journal of Materials Processing Technology,2008,207(1/3):293-300.
• [39] Sankaran S,Subramanya Sarma V,Padmanabhan K A. Low cycle fatigue behavior of a multiphase microalloyed medium carbon steel:comparison between ferrite-pearlite and quenched and tempered microstructures[J]. Materials Science and Engineering A,2003,345(1/2):328-335.
• [40] Branco R,Costa J D,Antunes F V.Low-cycle fatigue behaviour of 34CrNiMo6 high strength steel[J].Theoretical and Applied Fracture Mechanics,2012,58(1):28-34.
• [41] Zhou Q,Qian L H,Meng J Y,et al.Low-cycle fatigue behavior and microstructural evolution in a low-carbon carbide-free bainitic steel[J].Materials and Design,2015,85:487-496.
• [42] Hilditch T,Beladi H,Hodgson P,et al.Role of microstructure in the low cycle fatigue of multi-phase steels[J].Materials Science and Engineering A,2012,534:288-296.

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