Technological Support for Evaluation of Hydrogen Compatibility of Materials in Laboratory Conditions

Anton S. Tsvetkov; N.O. Shaposhnikov; Valery A. Yakhimovich; Maksim K. Kurakin; Andrey A. Lapechenkov

doi:10.4028/p-dxest6

Paper Titles

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Analysis of Causes of Corrosion Damage to Internal Surface of Stainless Steel Heat Exchanger Tubes
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Criteria for Revaluating the Propensity of Metals to Corrosion Cracking during Accelerated Testing in an Environment with Hydrogen Sulfide and Carbon Dioxide
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Technological Support for Evaluation of Hydrogen Compatibility of Materials in Laboratory Conditions
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Physical Modeling of Steel Resistance to Hydrogen Embrittlement
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Analysis of the Effect of Zea Mays Husk Particulate Reinforcement on 1170 Aluminium Corrosion in a Simulated Industrial Environment
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 943Technological Support for Evaluation of Hydrogen...

Technological Support for Evaluation of Hydrogen Compatibility of Materials in Laboratory Conditions

Abstract:

Materials selection for hydrogen service is needed to support the deployment of hydrogen as a fuel as well as the development of codes and standards for stationary hydrogen use, hydrogen vehicles, refueling stations, and hydrogen transportation. Hydrogen energy infrastructure is currently in the process of development and in preparation for mass transportation of hydrogen gas and methane-hydrogen media involves significant use of the existing network of gas pipelines and formation of a network of hydrogen pipelines. Materials property measurement is needed on deformation, fracture and fatigue in hydrogen-containing media. Determination of steel properties such as strength, crack and fatigue resistance are priority to ensure safe design of pipelines transporting hydrogen gas or methane-hydrogen mixture. At the same time, there is a problem in technological support for evaluation of hydrogen compatibility of materials in laboratory conditions for evaluation of hydrogen embrittlement, depending on hydrogen concentration, methods and modes of loading, temperature, pressure and actual properties of materials.

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Periodical:

Key Engineering Materials (Volume 943)

Pages:

85-89

DOI:

https://doi.org/10.4028/p-dxest6

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Online since:

March 2023

Authors:

Anton S. Tsvetkov*, N.O. Shaposhnikov, Valery A. Yakhimovich, Maksim K. Kurakin, Andrey A. Lapechenkov

Keywords:

Autoclave, Hydrogen Embrittlement, Hydrogen Gas, Steel

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References

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