On the mechanism of fatigue failure in the superlong life regime (<i>N</i>&gt;10<sup>7</sup> cycles). Part II: influence of hydrogen trapped by inclusions

Murakami, Yukitaka; Nomoto, Tetsushi; Ueda, Tamon

doi:10.1046/j.1460-2695.2000.00343.x

Cited by 143 publications

(134 citation statements)

References 3 publications

(1 reference statement)

Supporting

Mentioning

123

Contrasting

Unclassified

Order By: Relevance

“…The transition from a short to ultralong life appears usually as a horizontal step in the S-N curve, and the horizontal step usually corresponds to the conventional fatigue limit. [6][7][8][9][10][11][12][13] In the vicinity of a nonmetallic inclusion at the fracture origin, a dark area was often observed by optical microscopy (OM) inside a fisheye mark for specimens with a long fatigue life. Murakami et al named this area the ''optically dark area'' (ODA).…”

mentioning

confidence: 99%

“…Murakami et al named this area the ''optically dark area'' (ODA). [10][11][12] This feature appeared as a very rough area when observed by scanning electron microscopy (SEM); Shiozawa et al named it the ''granular bright facet'' (GBF). [14,15] Many workers tried to explain the formation mechanism of ODA and obtained some interesting results.…”

mentioning

confidence: 99%

“…[14,15] Many workers tried to explain the formation mechanism of ODA and obtained some interesting results. [10][11][12][14][15][16][17] Murakami et al considered that the formation of ODA might be related to hydrogen trapped by inclusion. [10][11][12] Hydrogen trapped by inclusion was observed by high-resolution tritium autoradiography, as shown in Figure 1, [18] and it seems that hydrogen trapped by inclusion should play an important role during the fatigue cracking process.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Yang

et al. 2009

Adv Eng Mater

View full text Add to dashboard Cite

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Yang

et al. 2009

Adv Eng Mater

View full text Add to dashboard Cite

“…(1)~ (17) ．これは高応力振幅・短寿命域における表面破壊から，低応力振幅・長寿命域における内部介在物を起点とした内部破壊に破壊機構が変化することによって生じ，通常 10 6 ～10 7 回程度で現れる疲労限度が消失する現象である．したがって，機械・構造物の安全性や信頼性を確保した疲労設計と保守・管理技術の確立のためには，10 7 回を越える超高サイクル域で生じる内部破壊の機構を解明することが重要な課題であり，これまでに多くの研究が行われてきた (18) ．超高サイクル域で生じる内部破壊の起点となった介在物周囲には凹凸の大きな粒状の領域，GBF（Granular Bright Facet）が観察され，塩澤らはこれまでに GBF 領域形成の機構として「微細炭化物の離散剥離説」を提案してきた (19), (20) ．また，この領域の形成が超高サイクル域の疲労破壊を支配することを指摘してきた．内部介在物周囲に形成される特異な領域およびその形成機構は塩澤らによるものの他，村上ら (21), (22) は ODA と命名して介在物周囲にトラップされた水素の影響と繰 * 原稿受付 2010 年 12 月 2 日 *1 学生員，富山大学大学院理工学教育部（〒930-8555 3190） *3 正員，フェロー，富山大学大学院理工学研究部 *4 正員，金沢工業大学基礎教育部（〒921-8501 石川県石川郡野々市町扇が丘 7-1） *5 (株)不二越マテリアル事業部（〒931-8511 3-1-1） E-mail: shiozawa@eng.u-toyama.ac.jp …”

Section: 高強度・高硬度鋼や表面改質処理を施した高強度鋼などの超高サイクル疲労において，二段折れ曲がりあるいは二重 S-n 曲線unclassified

Effect of Nitriding on Very High Cycle Fatigue Properties of Developed High Speed Steel

Hirano¹,

Shimatani²,

Shiozawa

et al. 2011

Trans.JSME, Ser.A

View full text Add to dashboard Cite

Evaluation of fatigue properties for new high speed steel nitrided was performed through a cantilever-type rotating bending fatigue test in air at room temperature in very high cycle fatigue (VHCF) regime. The high speed steel was made experimentally by control the chemical compositions to avoid formation of the GBF area near subsurface inclusion at crack origin, based on internal failure mechanism as 'dispersive decohesion of spherical carbide' model previously proposed by authors. Surface treatment was applied with both of radical nitriding and low-temperature nitriding. Fatigue strength was increased in the whole of applied stress amplitude levels by both nitridings. Fatigue failure mode was changed from a matrix cracking in surface of the untreated specimen to an internal-inclusion induced failure with GBF area of the nitrided specimens in VHCF regime, for the reason of surface layer having high hardness and high compressive residual stress. From the comparison with common high speed steel, JIS SKH51, failed by an internal-inclusion induced failure mode in VHCF regime, fatigue strength of nitrided specimens was increased about 35%. It was concluded that the GBF formation around a subsurface inclusion was restricted by decrease in distribution of small MC-carbide particles in the matrix and a large number of stress cycling were required for the formation of appropriate size for the GBF area to enable propagation as an ordinary crack.

show abstract

“…Consequently, crack formation was attributed to localized micro-plastic deformation. On the a Corresponding author: markus.fried@mtu.de other hand, Murakami et al [5] have described crack initiation starting from inclusions, growing to microcracks until critical stress concentrations induced crack propagation. A large portion of the total specimen life at low load levels is consumed by the crack initiation period.…”

Section: Introductionmentioning

confidence: 99%

Fatigue crack initiation in nickel-based superalloys studied by microstructure-based FE modeling and scanning electron microscopy

Fried

Krechel

Affeldt

et al. 2014

MATEC Web of Conferences

View full text Add to dashboard Cite

Abstract. In this work stage I crack initiation in polycrystalline nickel-based superalloys is investigated by analyzing anisotropic mechanical properties, local stress concentrations and plastic deformation on the microstructural length scale. The grain structure in the gauge section of fatigue specimens was characterized by EBSD. Based on the measured data, a microstructure-based FE model could be established to simulate the strain and stress distribution in the specimens during the first loading cycle of a fatigue test. The results were in fairly good agreement with experimentally measured local strains. Furthermore, the onset of plastic deformation was predicted by identifying shear stress maxima in the microstructure, presumably leading to activation of slip systems. Measurement of plastic deformation and observation of slip traces in the respective regions of the microstructure confirmed the predicted slip activity. The close relation between micro-plasticity, formation of slip traces and stage I crack initiation was demonstrated by SEM surface analyses of fatigued specimens and an in-situ fatigue test in a large chamber SEM.

show abstract

On the mechanism of fatigue failure in the superlong life regime (N>10⁷ cycles). Part II: influence of hydrogen trapped by inclusions

Cited by 143 publications

References 3 publications

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Effect of Nitriding on Very High Cycle Fatigue Properties of Developed High Speed Steel

Fatigue crack initiation in nickel-based superalloys studied by microstructure-based FE modeling and scanning electron microscopy

Contact Info

Product

Resources

About

On the mechanism of fatigue failure in the superlong life regime (N>107 cycles). Part II: influence of hydrogen trapped by inclusions

Cited by 143 publications

References 3 publications

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Effect of Hydrogen on Fatigue Strength of High‐Strength Steels in the VHCF Regime

Effect of Nitriding on Very High Cycle Fatigue Properties of Developed High Speed Steel

Fatigue crack initiation in nickel-based superalloys studied by microstructure-based FE modeling and scanning electron microscopy

Contact Info

Product

Resources

About

On the mechanism of fatigue failure in the superlong life regime (N>10⁷ cycles). Part II: influence of hydrogen trapped by inclusions