An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties

Motte, Robin; De Waele, Wim

An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties

Robin Motte (UGent) and Wim De Waele (UGent)

(2024) METALS. 14(1).

Author

Robin Motte (UGent) and Wim De Waele (UGent)

Organization

Department of Electromechanical, Systems and Metal Engineering

Project

Structural integrity of remanufactured components made by Wire+Arc Additive Manufacturing

Abstract

Due to the time-consuming and costly nature of high-cycle fatigue experiments, correlations between fatigue strength and mechanical properties obtained through more simple and fast experiments can be interesting from an economic perspective. This review article aims to provide an overview of such relations established in the open literature from the 1980s to 2023 for conventionally manufactured steel grades. The majority of these models relate fatigue strength at a given fatigue life (often termed “fatigue limit” or “endurance limit”) to ultimate tensile strength, yield strength (both static and cyclic), hardness, elongation, reduction in area, and Charpy impact energy. Relations taking flaws such as nonmetallic inclusions into account are also discussed. Additionally, models predicting S–N curves are provided. The various estimations are presented in tables, together with the materials and test conditions for which they were established.

Keywords

General Materials Science, Metals and Alloys, high-cycle fatigue, S-N curve, estimations, yield strength, ultimate tensile strength, hardness, toughness, flaws, steel, S-N CURVE, GIGACYCLE FATIGUE, TENSILE-STRENGTH, LIFE, FAILURE, LIMIT, PREDICTION, HARDNESS, STRESS, MODEL

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01HKVNNQ9JVG2EX7CTVZ055HSG

MLA: Motte, Robin, and Wim De Waele. “An Overview of Estimations for the High-Cycle Fatigue Strength of Conventionally Manufactured Steels Based on Other Mechanical Properties.” METALS, vol. 14, no. 1, 2024, doi:10.3390/met14010085.
APA: Motte, R., & De Waele, W. (2024). An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties. METALS, 14(1). https://doi.org/10.3390/met14010085
Chicago author-date: Motte, Robin, and Wim De Waele. 2024. “An Overview of Estimations for the High-Cycle Fatigue Strength of Conventionally Manufactured Steels Based on Other Mechanical Properties.” METALS 14 (1). https://doi.org/10.3390/met14010085.
Chicago author-date (all authors): Motte, Robin, and Wim De Waele. 2024. “An Overview of Estimations for the High-Cycle Fatigue Strength of Conventionally Manufactured Steels Based on Other Mechanical Properties.” METALS 14 (1). doi:10.3390/met14010085.
Vancouver: 1.
Motte R, De Waele W. An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties. METALS. 2024;14(1).
IEEE: [1]
R. Motte and W. De Waele, “An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties,” METALS, vol. 14, no. 1, 2024.

@article{01HKVNNQ9JVG2EX7CTVZ055HSG,
  abstract     = {{Due to the time-consuming and costly nature of high-cycle fatigue experiments, correlations between fatigue strength and mechanical properties obtained through more simple and fast experiments can be interesting from an economic perspective. This review article aims to provide an overview of such relations established in the open literature from the 1980s to 2023 for conventionally manufactured steel grades. The majority of these models relate fatigue strength at a given fatigue life (often termed “fatigue limit” or “endurance limit”) to ultimate tensile strength, yield strength (both static and cyclic), hardness, elongation, reduction in area, and Charpy impact energy. Relations taking flaws such as nonmetallic inclusions into account are also discussed. Additionally, models predicting S–N curves are provided. The various estimations are presented in tables, together with the materials and test conditions for which they were established.}},
  articleno    = {{85}},
  author       = {{Motte, Robin and De Waele, Wim}},
  issn         = {{2075-4701}},
  journal      = {{METALS}},
  keywords     = {{General Materials Science,Metals and Alloys,high-cycle fatigue,S-N curve,estimations,yield strength,ultimate tensile strength,hardness,toughness,flaws,steel,S-N CURVE,GIGACYCLE FATIGUE,TENSILE-STRENGTH,LIFE,FAILURE,LIMIT,PREDICTION,HARDNESS,STRESS,MODEL}},
  language     = {{eng}},
  number       = {{1}},
  pages        = {{53}},
  title        = {{An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties}},
  url          = {{http://doi.org/10.3390/met14010085}},
  volume       = {{14}},
  year         = {{2024}},
}

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An overview of estimations for the high-cycle fatigue strength of conventionally manufactured steels based on other mechanical properties

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