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Home > Archive>Volume 52, Issue 10, 2023 >3600-3607. DOI:10.12442/j.issn.1002-185X.20220773
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Tensile creep properties and damage mechanisms of W-4Re-0.27HfC alloy at 1500~1700 ℃
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1.NPU-SAS Joint Research Center,School of Materials Science and Engineering,Northwestern Polytechnical University,Xi’an;2.ATTL Advanced Materials Co,Ltd;3.School of Materials Science and Engineering,The University of Sheffield,Sheffield,UK,S QF

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    Abstract:

    In this paper, the tensile creep behavior in vacuum of W-4Re-0.27HfC alloy prepared by powder metallurgy was studied. The creep temperature was 1500~1700℃ and the creep stress was 40~60MPa. SEM, EBSD and TEM observations were used to observe the microstructure, characterize the evolution of grain size and dislocation during the creep process. The results show that the steady creep rate of W-4Re-0.27HfC alloy ranges from1′10-7~5′10-6, which is two orders of magnitude lower than that of pure tungsten (W). The creep resistance of W-4Re-0.27HfC alloy is higher than that of pure W due to the dislocation pinned by HfC particles and the lattice distortion caused by Re replacing W atoms. The creep mechanisms of W-4Re-0.27HfC is mainly dislocation slip, accompanied by grain boundary slip at 1500℃. Dislocation climb becomes the main creep mechanism with increasing temperature. The dislocations were blocked by the HfC particles, which leads to the debonding of the HfC/ matrix interface. Moreover, the desquamation of HfC particles forms pores, which results in the great degradation in the creep properties of the alloy.

    Reference
    [1]朱玲旭, 燕青芝, 郎少庭, 等. 钨基面向等离子体材料的研究进展[J].中国有色金属学报, 2012, 22(12):3522-3528.
    [2] Jaffee R I,Sims C T,Hardwood J J. The effect of Rhenium on the fabrication and ductility of molybdenum and Tungsten[C]. Plansee-Seminar Proceedings,Reutte,Austria: Plansee Group, 1958: 380-410.
    [3]杨世民, 范景莲. 铈、镧、钇、铼、钾对钨材料的强化机制探讨[J].硬质合金,2015,32(01):19-23.
    [4]Gao H,Zee R. A Semi-mechanistic creep model for tungsten and molybdenum based solid solution alloys[J].Scripta Metallurgica Et Materialia,1995,32(10):1665-1670.
    [5]Klopp,Witzke. Mechanical properties of a tungsten 23.4rhenium 0.27hafnium carbon alloy[J].Journal of the Less Common Metals, 1971,24(4):427-443.
    [6]Vandervoort,R.R. Creep behavior of W-5Re[J].Metallurgical Transactions,1970,1(4):857-864.
    [7]K.Y,Wang.S,Miao et al. Thermal stability and mechanical properties of HfC dispersion strengthened W alloys as plasma facing components in fusion devices[J].Journal of Nuclear Materials, 2017,492(08):260-268.
    [8]Li Y,Li L,Li J et al. Microstructural evolution and hot deformation behavior of W-3Re-5HfC alloy[J].International Journal of Refractory Metals and Hard Materials,2021(2):105535.
    [9]H.M. Yun. Effect of composition and microstructure on the creep and stress-rupture behaviour of tungsten alloy wires at 1366-1500K[J].Materials Science and Engineering:A,1993, 165(1):65-74.
    [10]Ren C,Fang Z Z,Koopman M et al. Methods for improving ductility of tungsten-A review[J].International Journal of Refractory Metals and Hard Materials, 2018, 75(9):170-183.
    [11]Butler,Paramore,Ligda et al. Mechanisms of deformation and ductility in tungsten – A review[J].International Journal of Refractory Metals and Hard Materials,Volume,2018,75(9): 248-261.
    [12]吴凯鹏. 基于铼掺杂的纳米多晶钨晶界影响区强化机制[D].西南交通大学, 2020.
    [13]Golan O,Arbel A,Eliezer D et al. The applicability of Norton''s creep power law and its modified version to a single-crystal superalloy type CMSX-2[J].Materials Science & Engineering A, 1996,216(1-2):125-130.
    [14]Gordon,Vandermeer. The mechanisms of boundary migration in recrystallization[J].Trans.Metall.Soc.AIME,1962,224(1):917-928.
    [15]Lee D,Umer M A,Ryu H J et al. Elevated temperature ablation resistance of HfC particle-reinforced tungsten composites[J]. International Journal of Refractory Metals and Hard Materials, 2014(43):89–93.
    [16]孟杨,任群,鞠新华.利用局域取向差衡量变形金属中的位错密度[J].材料热处理学报, 2014(11):7
    [17]Hahn,Meyers. Grain-size dependent mechanical behavior of nanocrystalline metals[J].Materials Science & Engineering A,2015,646(14):101-134.
    [18]G.King,H.Sell. The effect of thoria on the elevated temperature tensile properties of recrystallized high purity tungsten,Trans[J]. Metall.Soc.AIME,1965,82(5):132-162.
    [19]Luo A,Shin K S,Jacobson D L.Hafnium carbide strengthening in a tungsten-rhenium matrix at ultrahigh temperatures[J].Acta Metallurgica Et Materialia,1992,40(9):2225-2232.
    [20]Park J J. Creep strength of a tungsten–rhenium–hafnium carbide alloy from 2200 to 2400K[J].Materials Science and Engineering A,1999,265(1):174-178.
    [21]Klopp W D,Witzke W R. Mechanical properties of a tungsten 23.4rhenium 0.27hafnium-carbon alloy[J].Journal of the Less Common Metals,1971,24(4):427-443.
    [22]B.Harris,E.Ellison. Creep and tensile properties of heavily drawn tungsten wire,Trans[J].Vacuum,1967,17(7):428.
    [23]Wang,Du G,Chen N et al. Ideal strengths and thermodynamic properties of W and W Re alloys from first-principles calculation[J]. Fusion Engineering and Design,2020,155(6):111579.
    [24] Magri M,Lemoine G,Adam L et al. A coupled model of diffusional creep of polycrystalline solids based on climb of dislocations at grain boundaries[J].Journal of the Mechanics and Physics of Solids,2020,135(1):103786.1-103786.20
    [25]Mingqui Liu,John Cowley. Hafnium carbide growth behavior and its relationship to the dispersion hardening in tungsten at high temperature[J].Materials Science and Engineering:A,1993,160(2):159-167
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[Wang Chenrui, Dong Di, Ying Wenqing, Zhang Chao, Wang Chengyang, Li Mei, Sun Shangyue, Zhang Chengyu. Tensile creep properties and damage mechanisms of W-4Re-0.27HfC alloy at 1500~1700 ℃[J]. Rare Metal Materials and Engineering,2023,52(10):3600~3607.]
DOI:10.12442/j. issn.1002-185X.20220773

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History
  • Received:September 29,2022
  • Revised:October 09,2023
  • Adopted:November 24,2022
  • Online: October 27,2023
  • Published: October 24,2023

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