γ'相对镍基高温合金强度、疲劳与蠕变性能影响的研究进展
Research Progress on Effect of γ' Phase on Strength, Fatigue and Creep Properties of Nickel-Based Superalloys
摘 要
独特的γ'相使镍基高温合金具有良好的疲劳和蠕变性能,在航空航天和高参数发电等领域具有广阔的应用前景。从γ'相的尺寸、含量和位错强化方面介绍了γ'相对镍基高温合金强化行为的影响以及位错与析出相交互作用的剪切、Orowan绕过和攀移等强化机制,阐述了γ'相对镍基高温合金疲劳和蠕变性能的影响。最后,对镍基高温合金中γ'相的优化及相关性能调控进行了展望。
镍基高温合金
疲劳
蠕变
位错
γ' phase
nickel-based superalloy
fatigue
creep
dislocation
Abstract
Nickel-based superalloys have good fatigue and creep properties due to their unique γ' phase, and have wide application in aerospace and high-parameter power generation industries. The effect of γ' phase on the strengthening behavior of nickel-based superalloys from aspects of size and content of γ' phase and dislocation strengthening, and the strengthening mechanisms of interaction between dislocations and precipitates, including shear, Orowan bypass and climb, are described. The influence of γ' phase on fatigue and creep properties of nickel-based superalloys is discussed. Finally, the optimization of γ' phase and associated performance control of nickel-based superalloys are prospected.
中图分类号 TG146.1 DOI 10.11973/jxgccl202306001
所属栏目 综述
基金项目 上海市教育委员会科研创新计划资助项目(2023-05-49)
收稿日期 2022/9/1
修改稿日期 2023/5/16
网络出版日期
作者单位点击查看
联系人作者朱明亮
备注朱金群(1997-),男,安徽安庆人,硕士研究生
引用该论文: ZHU Jinqun,AN Chunxiang,LU Yixin,ZHU Mingliang,XUAN Fuzhen. Research Progress on Effect of γ' Phase on Strength, Fatigue and Creep Properties of Nickel-Based Superalloys[J]. Materials for mechancial engineering, 2023, 47(6): 1~7
朱金群,安春香,陆翌昕,朱明亮,轩福贞. γ'相对镍基高温合金强度、疲劳与蠕变性能影响的研究进展[J]. 机械工程材料, 2023, 47(6): 1~7
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参考文献
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【6】MUKHERJEE S,BARAT K,SIVAPRASAD S,et al.Elevated temperature low cycle fatigue behaviour of Haynes 282 and its correlation with microstructure:Effect of ageing conditions[J].Materials Science and Engineering:A,2019,762:138073.
【7】宋晓庆,唐丽英,陈铮.新型镍基高温合金Haynes 282的特点及应用[J].材料导报,2016,30(11):116-120. SONG X Q,TANG L Y,CHEN Z.Characteristics and applications of a new Ni-based superalloy Haynes 282[J].Materials Review,2016,30(11):116-120.
【8】WANG W Z,HONG H U,KIM I S,et al.Influence of γ' and grain boundary carbide on tensile fracture behaviors of Nimonic 263[J].Materials Science and Engineering:A,2009,523(1/2):242-245.
【9】MACIEJEWSKI K,JOUIAD M,GHONEM H.Dislocation/precipitate interactions in IN100 at 650℃[J].Materials Science and Engineering:A,2013,582:47-54.
【10】GAYDA J,MINER R V.Fatigue crack initiation and propagation in several nickel-base superalloys at 650℃[J].International Journal of Fatigue,1983,5(3):135-143.
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【12】BARAT K,GHOSH M,SIVAPRASAD S,et al.High-temperature low-cycle fatigue behavior in HAYNES 282:Influence of initial microstructure[J].Metallurgical and Materials Transactions A,2018,49(10):5211-5226.
【13】FENG Y F,ZHOU X M,ZOU J W,et al.Effect of cooling rate during quenching on the microstructure and creep property of nickel-based superalloy FGH96[J].International Journal of Minerals,Metallurgy,and Materials,2019,26(4):493-499.
【14】THÉBAUD L,VILLECHAISE P,CROZET C,et al.Is there an optimal grain size for creep resistance in Ni-based disk superalloys? [J].Materials Science and Engineering:A,2018,716:274-283.
【15】ABE F.Research and development of heat-resistant materials for advanced USC power plants with steam temperatures of 700℃ and above[J].Engineering,2015,1(2):211-224.
【16】RAI R K,SAHU J K,DAS S K,et al.Creep-fatigue deformation micromechanisms of a directionally solidified nickel-base superalloy at 850℃[J].Fatigue & Fracture of Engineering Materials & Structures,2020,43(1):51-62.
【17】刘健,叶飞,王旭青,等.粉末高温合金Udimet720Li γ'强化相析出行为[J].粉末冶金技术,2021,39(6):499-504. LIU J,YE F,WANG X Q,et al.Precipitation behavior of γ' phase in P/M superalloy Udimet720Li[J].Powder Metallurgy Technology,2021,39(6):499-504.
【18】TELESMAN J,GABB T P,GARG A,et al.Effect of microstructure on time dependent fatigue crack growth behavior in a P/M turbine disk alloy[C]//11th International Symposium Superalloys 2008.Warrendale, PA:TMS,2008:20080047674.
【19】PALMERT F,MOVERARE J,GUSTAFSSON D,et al.Fatigue crack growth behaviour of an alternative single crystal nickel base superalloy[J].International Journal of Fatigue,2018,109:166-181.
【20】WANG S A,WANG L,LIU Y,et al.Effect of long-term aging on the fatigue crack growth rate of a nickel-based superalloy[J].Materials Science and Engineering:A,2011,528(4/5):2110-2117.
【21】GAYDA J, MINER R V. The effect of microstructure on 650℃ fatigue crack growth in P/M astroloy[J]. Metallurgical Transactions A, 1983, 14(11): 2301-2308.
【22】JOSEPH C,PERSSON C,HÖRNQVIST COLLIANDER M.Influence of heat treatment on the microstructure and tensile properties of Ni-base superalloy Haynes 282[J].Materials Science and Engineering:A,2017,679:520-530.
【23】PANG H T,REED P A S.Microstructure variation effects on room temperature fatigue threshold and crack propagation in Udimet 720Li Ni-base superalloy[J].Fatigue & Fracture of Engineering Materials & Structures,2009,32(8):685-701.
【24】XIAO G F,JIANG J F,WANG Y,et al.Microstructure and mechanical properties of thixoformed GH4037 parts before and after heat treatment[J].Materials Science and Engineering:A,2021,815:141304.
【25】HU Y L,LIN X,LI Y L,et al.Effect of heat treatment on the microstructural evolution and mechanical properties of GH4099 additive-manufactured by directed energy deposition[J].Journal of Alloys and Compounds,2019,800:163-173.
【26】DEL VALLE J A,PICASSO A C,ROMERO R.Work-hardening in Inconel X-750:Study of stage II[J].Acta Materialia,1998,46(6):1981-1988.
【27】SUN F,TONG J Y,FENG Q,et al.Microstructural evolution and deformation features in gas turbine blades operated in-service[J].Journal of Alloys and Compounds,2015,618:728-733.
【28】KOZAR R W,SUZUKI A,MILLIGAN W W,et al.Strengthening mechanisms in polycrystalline multimodal nickel-base superalloys[J].Metallurgical and Materials Transactions A,2009,40(7):1588-1603.
【29】DU B N,YANG J X,CUI C Y,et al.Effects of grain refinement on the microstructure and tensile behavior of K417G superalloy[J].Materials Science and Engineering:A,2015,623:59-67.
【30】HUTHER W,REPPICH B.Interaction of dislocations with coherent,stress-free,ordered particles[J].International Journal of Materials Research,1978,69(10):628-634.
【31】PENG Z C,TIAN G F,JIANG J,et al.Mechanistic behaviour and modelling of creep in powder metallurgy FGH96 nickel superalloy[J].Materials Science and Engineering:A,2016,676:441-449.
【32】OH J H,CHOI I C,KIM Y J,et al.Variations in overall- and phase-hardness of a new Ni-based superalloy during isothermal aging[J].Materials Science and Engineering:A,2011,528(19/20):6121-6127.
【33】BUCKSON R A,OJO O A.Cyclic deformation characteristics and fatigue crack growth behaviour of a newly developed aerospace superalloy Haynes 282[J].Materials Science and Engineering:A,2012,555:63-70.
【34】KIM D,JIANG R,EVANGELOU A,et al.Effects of γ' size and carbide distribution on fatigue crack growth mechanisms at 650℃ in an advanced Ni-based superalloy[J].International Journal of Fatigue,2021,145:106086.
【35】侯坤磊. K4750镍基高温合金变形机制和η相析出行为研究[D]. 合肥:中国科学技术大学, 2022. HOU K L, The deformation mechanism and η precipitation behavior of K4750 Ni-based superalloy[D]. Hefei:University of Science and Technology of China, 2022.
【36】PANG H T,REED P A S.Effects of microstructure on room temperature fatigue crack initiation and short crack propagation in Udimet 720Li Ni-base superalloy[J].International Journal of Fatigue,2008,30(10/11):2009-2020.
【37】PANWAR S,SUNDARARAGHAVAN V.Dislocation theory-based cohesive model for microstructurally short fatigue crack growth[J].Materials Science and Engineering:A,2017,708:395-404.
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