非金属介在物起点の疲労き裂による疲労限度の消滅と人工微小欠陥から発生した疲労き裂の停留  [in Japanese] Elimination of Conventional Fatigue Limit due to Fatigue Crack Originated at Nonmetallic Inclusion, and Non-propagation of Fatigue Crack Originated at Artificial Small Hole  [in Japanese]

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Abstract

The mechanism of fatigue failure in the ultra-high cycle regime was studied using a martensitic stainless steel. The effect of internal hydrogen trapped by nonmetallic inclusions on high cycle fatigue behaviour has been discussed by Murakami et al. In order to investigate more in detail the mechanism of the elimination of the conventional fatigue limit and the influence of hydrogen trapped by inclusion, specimens with various artificial small defects were prepared. The fatigue failure of a specimen which contained an artificial hole occurred at N<SUB>f</SUB> ≅10<SUP>8</SUP> from a nonmetallic inclusion which is smaller in size than the artificial small surface hole. In the case of the specimen containing two artificial holes connected with a fatigue crack, non-propagation crack was observed at the edge of the artificial hole, and the fatigue limit was in good agreement with the value predicted by the √<I>area</I> parameter model. In the case of the specimen whose fatigue crack originating at an inclusion, the crack continued propagation, and finally the specimen failed. Considering that nonmetallic inclusions trap hydrogen, it is presumed that the elimination of the conventional fatigue limit due to fatigue crack originated at nonmetallic inclusion is caused by synergetic effect of cyclic stress and hydrogen trapped by inclusions.

Journal

  • TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A

    TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series A 72(720), 1123-1130, 2006-08-25

    The Japan Society of Mechanical Engineers

References:  32

Cited by:  3

Codes

  • NII Article ID (NAID)
    110004763330
  • NII NACSIS-CAT ID (NCID)
    AN0018742X
  • Text Lang
    JPN
  • Article Type
    Journal Article
  • ISSN
    03875008
  • NDL Article ID
    8076401
  • NDL Source Classification
    ZM16(科学技術--科学技術一般--工業材料・材料試験)
  • NDL Call No.
    Z14-737
  • Data Source
    CJP  CJPref  NDL  NII-ELS  J-STAGE 
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