ADIABATIC SHEAR BAND IN WHITE-ETCHING LAYER

Acta Metall Sin

1997, Vol. 33

Issue (11): 1161-1164 DOI:

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ADIABATIC SHEAR BAND IN WHITE-ETCHING LAYER

ZHANG Baofa;SHEN Wanci;LIU Yingjie; WANG Yuanfei;TANG Xiangyun (Tsinghua University;Beijing 100084)

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ZHANG Baofa;SHEN Wanci;LIU Yingjie; WANG Yuanfei;TANG Xiangyun (Tsinghua University;Beijing 100084). ADIABATIC SHEAR BAND IN WHITE-ETCHING LAYER. Acta Metall Sin, 1997, 33(11): 1161-1164.

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Abstract Adiabatic shear band was observed in surface white-etching layer in impact wear test.The band possesses very fine crystalline grains,and is harder than white-etching layer.The adiabatic shear bnad in white-etching layer is liable to fracture or cracking in impact wear.It's supposed that dynamic recrystallization occures in the band in white-etching layer whereas dynamic recovery takes place in the white-etching layer.

Key words: white-etching layer adiabatic shear band impact wear dynamic recovery dynamic recrystallization fracture

Received: 18 November 1997

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https://www.ams.org.cn/EN/ OR https://www.ams.org.cn/EN/Y1997/V33/I11/1161

1ScottD,SmithAI,TaitJ,TremainGR.Wear,1975;33:293
2ZenerC,HollomonJH.JApplPhys,1944;15:22
3BackmanME.FinneganSA.In:PohdeRW,ButcherBM,HollandJR,KarnesCHeds,MetalluryicalEffectsatHighStrainRates,NewYork:Plenum,1973:531
4张保法,刘英杰,沈万慈,王远飞,唐祥云.科学通报,1996;41:374
5ZhangBF,LiuYJ,ShenWC,WangYF,TangXY,WangXD.Wear,1996;198:287
6GriffithsBJ.JTribol,1987;109:525
7BaiYL.ResMech,1990;31:133
8WittmanCL,MeyersMA,PakHR.MetallTrans,1990;21A:707

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