A New Evaluation Method of Hydrogen Embrittlement Fracture for High Strength Steel by Local Approach

Takagi, Shusaku; Terasaki, Satoshi; Tsuzaki, Kaneaki; Inoue, Tatsuo; Minami, Fumiyoshi

doi:10.2355/isijinternational.45.263

Cited by 29 publications

(10 citation statements)

References 19 publications

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“…The maximum peak 1 hydrogen content which does not cause hydrogen embrittlement failure is defined as 'critical hydrogen content for hydrogen embrittlement' [Hc]. 3,9) The critical hydrogen content correlates with the tensile strength irrespective of the heating rate to the tempering temperature. The It should be noted that time to fracture also correlates with the tensile strength irrespective of the heating rate to the tempering temperature.…”

Section: Slow Strain Rate Testmentioning

confidence: 99%

Effect of Uniform Distribution of Fine Cementite on Hydrogen Embrittlement of Low Carbon Martensitic Steel Plates

Nagao

Hayashi²,

Oi³

et al. 2012

ISIJ International

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The effect of uniform distribution of fine cementite on resistance of ultra-high strength steels to hydrogen embrittlement was studied. The materials used were directly-quenched and tempered 1 000-1 300 MPa class low carbon steel plates for welded structures with lath martensite structure. Cementite morphology was different at different heating rates to tempering temperatures. Finer cementite was distributed in rapidly-heated steels (20°C/s) than in slowly-heated steels (0.3°C/s). The rapidly-heated steels showed higher resistance to hydrogen embrittlement than the slowly-heated steels for a slow strain rate test (SSRT), whereas they showed almost the same resistance to hydrogen embrittlement for a constant load test (CLT). The specimens fractured in a plastic region for the SSRT, on the other hand, the CLT was conducted in an elastic region. The difference in hydrogen embrittlement resistance between plastic and elastic loading methods was concluded to result from a change in the hydrogen trap state at cementite in association with plasticity. Hydrogen is more strongly trapped at and/or around the strained interfaces between the matrix and cementite after plastic deformation. A close observation of fracture surfaces, hydrogen thermal desorption analysis and hydrogen microprint technique revealed that the high resistance of the rapidly-heated and tempered steels to hydrogen embrittlement for the SSRT is due to a shift of the fracture mode from quasicleavage fracture to ductile fracture. This shift was caused by the suppression of the quasi-cleavage fracture due to less hydrogen at lath boundaries accompanied by the uniform distribution of fine cementite.

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Section: Slow Strain Rate Testmentioning

confidence: 99%

Effect of Uniform Distribution of Fine Cementite on Hydrogen Embrittlement of Low Carbon Martensitic Steel Plates

Nagao

Hayashi²,

Oi³

et al. 2012

ISIJ International

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“…Mechanical properties of the steel used. [16][17][18][19][20] иииииииииииииииииииииииииииииииииииииии( 2 )…”

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Evaluation of Hydrogen Embrittlement for High Strength Steel Sheets

Toji¹,

Takagi²,

Yoshino³

et al. 2009

Tetsu-to-Hagane

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Synopsis :The risk of delayed fracture should be evaluated when applying ultra high strength steel sheets to automotive parts. Steel sheets for automobiles are usually formed into various parts by cold working. Therefore, plastic strain introduced by the cold working must be considered as a factor affecting the hydrogen embrittlement in addition to the applied stress and the content of diffusible hydrogen entered into steels, which are considered as factors affecting the hydrogen embrittlement of high strength steel bolts. In this study, the influence of plastic strain, as well as stress and diffusible hydrogen content, on hydrogen embrittlement of steel sheets was quantitatively studied by using an 1180 MPa grade cold rolled steel sheet. Plastic strain was introduced by U-shape bending. Stress was applied by tightening the bent specimen with a bolt. Then, hydrogen was introduced by immersing in hydrochloric acid. The time to fracture and the content of diffusible hydrogen entered into steel were investigated. The fracture was promoted by severe deformation, and it seemed to be caused by the presence of micro cracks and/or micro voids. The hydrogen cracking conditions region of the steel sheet was mapped in the three-dimensional space with the axes of applied strain, applied stress and diffusible hydrogen content. It was considered that the evaluation of the risk of delayed fracture of automotive parts made of the steel sheet under service environment was possible by a comparison of the hydrogen cracking conditions and the service conditions of the parts on the 3D space.

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“…With focusing on this local approach, a development of a new estimation method of hydrogen-induced unstable fracture in brittle manner has been advanced taking the deterioration of materials due to hydrogen into consideration. 4) This new approach is successful for predicting the occurrence of delayed fracture for components with various stress concentration factors and hydrogen contents, whereas the method for determining the material parameters with respect to hydrogen-induced deterioration of materials has not been necessarily established.…”

Section: Introductionmentioning

confidence: 99%

“…1,2) Moreover, the methods taking not only the local stress but also the local diffusible hydrogen content in the components into consideration have also been proposed. 3,4) However, for the more accurate evaluation of the time dependent hydrogen-induced fracture with statistical scatter and for transferable evaluation of that dependent on the shape and size of the components and loading condition, a new evaluation model is required to be proposed.…”

Section: Introductionmentioning

confidence: 99%

Weibull Model for Hydrogen-induced Fracture of High Strength Steel

Ohata

Omura²,

Minami

2012

ISIJ Int.

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This study proposes a new evaluation model of hydrogen-induced unstable fracture of high strength steel and/or its welds. In this model, a new driving force for hydrogen-induced fracture, Hydrogen-Weibull stress, is proposed on the basis of the original Beremin model, where cohesive energy reduction due to diffusible hydrogen is implemented into the local unstable fracture model. The Hydrogen-Weibull stress, which is enlarged not only by the local stress but also by diffusible hydrogen content, can be independent of geometrical parameters of components as well as diffusible hydrogen content. The validity of this Hydrogen-Weibull stress is demonstrated by constant load test conducted with different load level and with various initial hydrogen contents.KEY WORDS: hydrogen embrittlement; hydrogen-induced unstable fracture; delayed fracture; high strength steel; hydrogen content; weibull stress.

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A New Evaluation Method of Hydrogen Embrittlement Fracture for High Strength Steel by Local Approach

Cited by 29 publications

References 19 publications

Effect of Uniform Distribution of Fine Cementite on Hydrogen Embrittlement of Low Carbon Martensitic Steel Plates

Effect of Uniform Distribution of Fine Cementite on Hydrogen Embrittlement of Low Carbon Martensitic Steel Plates

Evaluation of Hydrogen Embrittlement for High Strength Steel Sheets

Weibull Model for Hydrogen-induced Fracture of High Strength Steel

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