A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels

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Volume 3, Issue 2 (February 2006)

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ISSN: 1546-962X
Page Count: 13

A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels
Matsubara, Y
R&D Engineer, NTN Corporation,

Hamada, H
R&D Engineer, NTN Corporation,

Abstract

In rolling contact fatigue, hydrogen is believed to contribute to early flaking failures under some conditions. Hydrogen diffuses quickly in steels, even at room temperature, thus resulting in its dissipation into the surrounding atmosphere. This condition presents a uniquely difficult challenge for evaluating the intrinsic fatigue properties related to hydrogen embrittlement. In order to compensate for this, we employed ultrasonic fatigue testing at a loading frequency of 20 kHz, because a high loading frequency offsets the rapid hydrogen loss. In this report, the fatigue properties of hydrogen pre-charged JIS-SUJ2 (SAE52100 equivalent) were assessed. The amount of hydrogen was quantitatively measured by thermal desorption analysis. The diffusion coefficient of hydrogen was determined via electrochemical hydrogen permeation testing. These results indicate that the magnitude of fatigue strength reduction is directly proportional to the diffusible hydrogen content. Included with this report is our proposed method for evaluating fatigue strength related to hydrogen embrittlement.

Keywords:
fatigue strength, high strength steels, hydrogen embrittlement, ultrasonic fatigue, thermal desorption analysis of hydrogen, electrochemical hydrogen permeation method

Paper ID: JAI14048
DOI: 10.1520/JAI14048
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Author Title A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels Symposium Bearing Steel Technologies: Seventh International Symposium, 2005-05-19 Committee A01

		Home Journals STPs Manuals Topics Subscriptions/Pricing Digital Library / Journals / Journal of ASTM International (JAI) / Citation Page Volume 3, Issue 2 (February 2006) Click here to download this paper now for $25 PDF (392K) View License Agreement ISSN: 1546-962X Page Count: 13 A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels Matsubara, Y R&D Engineer, NTN Corporation, Hamada, H R&D Engineer, NTN Corporation, Abstract In rolling contact fatigue, hydrogen is believed to contribute to early flaking failures under some conditions. Hydrogen diffuses quickly in steels, even at room temperature, thus resulting in its dissipation into the surrounding atmosphere. This condition presents a uniquely difficult challenge for evaluating the intrinsic fatigue properties related to hydrogen embrittlement. In order to compensate for this, we employed ultrasonic fatigue testing at a loading frequency of 20 kHz, because a high loading frequency offsets the rapid hydrogen loss. In this report, the fatigue properties of hydrogen pre-charged JIS-SUJ2 (SAE52100 equivalent) were assessed. The amount of hydrogen was quantitatively measured by thermal desorption analysis. The diffusion coefficient of hydrogen was determined via electrochemical hydrogen permeation testing. These results indicate that the magnitude of fatigue strength reduction is directly proportional to the diffusible hydrogen content. Included with this report is our proposed method for evaluating fatigue strength related to hydrogen embrittlement. Keywords: fatigue strength, high strength steels, hydrogen embrittlement, ultrasonic fatigue, thermal desorption analysis of hydrogen, electrochemical hydrogen permeation method Paper ID: JAI14048 DOI: 10.1520/JAI14048 ASTM International is a member of CrossRef. Author Title A Novel Method to Evaluate the Influence of Hydrogen on Fatigue Properties of High Strength Steels Symposium Bearing Steel Technologies: Seventh International Symposium, 2005-05-19 Committee A01