Flow Controllability of Hydrogen Diffusion Driven by Local Stress Field for Steel under Cyclic Loading Condition

Toshihito Ohmi; A.Toshimitsu Yokobori Jr.; Kenichi Takei

doi:10.4028/www.scientific.net/DDF.326-328.626

Paper Titles

Comparison of Two Models for Simulation of Binary Alloy Solidification
p.599

Application of Simplified Inverse Solution to Estimate the Thermo-Physical Parameters of Granular Porous Materials Bonded by Different Resins
p.605

Problem of Acceptability of Internal Porosity in Semi-Finished Cast Product as New Trend "Tolerance of Damage" Present in Modern Design Office
p.612

The Effect of Hydrogen on Pitting Corrosion of Superaustenitic and Austenitic-Ferritic Stainless Steels
p.620

Flow Controllability of Hydrogen Diffusion Driven by Local Stress Field for Steel under Cyclic Loading Condition
p.626

Analysis of Stress Induced Voiding Using by Finite Element Analysis Coupled with Finite Difference Analysis
p.632

Exergetic Analyses of a Particular Absorption Cooling System
p.641

Effect of Synthesis Duration on the Physicochemical Properties of Siliceous Mesoporous Molecular Sieve (Si-MMS)
p.647

Effect of Frequency on Hydrocarbon (HC) Detection Using 3D Finite Integral Modeling
p.654

HomeDefect and Diffusion ForumDefect and Diffusion Forum Vols. 326-328Flow Controllability of Hydrogen Diffusion Driven...

Flow Controllability of Hydrogen Diffusion Driven by Local Stress Field for Steel under Cyclic Loading Condition

Abstract:

The hydrogen diffuses and accumulates at the stress concentration area like a crack tip and it causes hydrogen embrittlement. To clarify the mechanism of hydrogen embrittlement, it is important to obtain the hydrogen concentration behavior. However, experimental detection is not feasible due to the high diffusivity of hydrogen and numerical analyses have been preceded. In this paper, by using a finite element and finite difference coupled method at which the diffusion analysis is performed by FDM coupled with the stress analysis by FEM, the analyses of hydrogen diffusion were conducted under cyclic loading conditions.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Defect and Diffusion Forum (Volumes 326-328)

Pages:

626-631

DOI:

https://doi.org/10.4028/www.scientific.net/DDF.326-328.626

Citation:

Cite this paper

Online since:

April 2012

Authors:

Toshihito Ohmi, A.Toshimitsu Yokobori Jr., Kenichi Takei

Keywords:

Fatigue, FEM-FDM Coupling Method, Hydrogen Distribution, Hydrogen Embrittlement, Hydrogen Flux, Numerical Analysis

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] J.G. Morlet, H.H. Johnson and A.R. Troiano: J. Iron Steel Inst. Vol. 189 (1958), p.37.

Google Scholar

[2] R.A. Oriani: NACE Houston Vol. 32 (1969), p.32.

Google Scholar

[3] A.T. Yokobori, Jr., T. Nemoto, K. Satoh and T. Yamada: Engng. Fract. Mech. Vol. 5 (1996) p.47.

Google Scholar

[4] A.T. Yokobori, Jr., Y. Chinda, T. Nemoto, K. Satoh and T. Yamada: Corrosion Science Vol. 44 (2002), p.407.

Google Scholar

[5] A.T. Yokobori, Jr., T. Uesugi, M. Sendoh and M. Shibata: Strength Fracture and Complexity An International Journal Vol. 1 (2003), p.187.

Google Scholar

[6] P. Sofronis and R.M. McMeeking: J. Mech. Phys. Solids Vol. 37 (1989), p.317.

Google Scholar

[7] A.H.M. Krom, R.W.J. Koers and A. Bakker: J. Mech. Phys. Solids Vol. 47 (1999), p.971.

Google Scholar

[8] H.P. Leeuwen: Engng. Fracture Mechanics Vol. 6 (1974), p.141.

Google Scholar

[9] H.P. Leeuwen: Corrosion –NACE Vol. 31 (1975), p.42.

Google Scholar

[10] P.G. Shewmon: Diffusion in solids, Academic Press, New York (1963) p.122.

Google Scholar

[11] Y.C. Fung: Foundations of Solid Mechanics, Prentice-Hall Inc., New Jersey, (1965) p.365.

Google Scholar

[12] Y. Yamada: Plasticity and Viscoelasticity, Baifukan, (1972), p.180 (in Japanese).

Google Scholar

[13] Y. Yamada, N. Yoshimura and T. Sakurai: Int. J. Mech. Sci. Vol. 10 (1968), p.343.

Google Scholar