Advanced search
Publication Cover
Materials Science and Technology Volume 39, 2023 - Issue 15
Journal homepage
92
Views
0
CrossRef citations to date
0
Altmetric
Research Article

Effect of variable amplitude on fatigue life of 17CrNi steel beyond 107 cycles

Abdelhak Nehilaa Space Technology Research Division, Centre for Satellite Technology and Development, Algerian Space Agency, Oran, AlgeriaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-6202-4281View further author information
ORCID Icon &
Wei Lib School of Mechanical Engineering, Beijing Institute of Technology, Beijing, People’s Republic of ChinaView further author information
Pages 2158-2167 | Received 06 Dec 2022, Accepted 19 Mar 2023, Published online: 31 Mar 2023

References

  • Zhang J, Li S, Yang Z, et al. Influence of inclusion size on fatigue behavior of high strength steels in the gigacycle fatigue regime. Int J Fatigue. 2007;29:765–771.
  • Sakai T, Oguma N, Morikawa A. Microscopic and nanoscopic observations of metallurgical structures around inclusions at interior crack initiation site for a bearing steel in very high-cycle fatigue fatigue. Fract Eng Mater Struct. 2015;38:1305–1314.
  • Paris P, Marines-Garcia I, Hertzberg R, Donald J. The relationship of effective stress intensity, elastic modulus and Burgers-vector on fatigue crack growth as associated with ‘fish eye’ gigacycle fatigue phenomena. Proceedings of the international conference on very high cycle fatigue III; 2004; Kyoto, Japan.
  • Hong Y, Lei Z, Sun C, et al. Propensities of crack interior initiation and early growth for very-high-cycle fatigue of high strength steels. Int J Fatigue. 2014;58:144–151.
  • Su H, Liu X, Sun C, et al. Nanograin layer formation at crack initiation region for very-high-cycle fatigue of a Ti-6Al-4 V alloy. Fatigue Fract Eng Mater Struct. 2017;40:979–999.
  • Nakasone Y, Hara H. FEM simulation of growth of fish-eye cracks in the very high cycle fatigue of a high strength steel SUJ2. In: Proceedings of the international conference on very high cycle fatigue III; 2004; Kyoto, Japan.
  • Wagner D, Ranc N, and Bathias C. Study of fatigue crack growth in gigacycle fatigue domain by thermal analysis during the tests. Proceedings of very high cycle fatigue IV, 2007; Warrendale, USA.
  • Murakami Y. Analysis of stress intensity factors of modes I, II and III for inclined cracks of arbitrary shape. Eng Fract Mech. 1985;22:101–114.
  • Sun C, Lei Z, Xie J, et al. Effects of inclusion size and stress ratio on fatigue strength for high-strength steels with fish-eye mode failure. Int J Fatigue. 2013;48:19–27.
  • Lai J, Lund T, Rydén K, et al. The fatigue limit of bearing steels-part I: A pragmatic approach to predict very high cycle fatigue strength. Int J Fatigue. 2012;37:155–168.
  • Sun C, Xie J, Zhao A, et al. A cumulative damage model for fatigue life estimation of high-strength steels in high-cycle and very-high-cycle fatigue regimes. Fatigue Fract Eng Mater Struct. 2012;35:638–647.
  • Mayer H, Haydn W, Schuller R, et al. Very high cycle fatigue properties of bainitic high carbon-chromium steel under variable amplitude loading. Int J Fatigue. 2009;31:1300–1308.
  • Issler S, Bacher-Höchst M, Haydn W. Fatigue design for components under variable amplitude loading in the very high cycle fatigue area. In: 2nd international conference on material and component performance under variable amplitude loading. Berlin: DVM; 2009. p. 935–943.
  • Nakajima M, Kamiya N, Itoga H, et al. Experimental estimation of crack initiation lives and fatigue limit in subsurface fracture of high carbon chromium steel. Int J Fatigue. 2006;28:1540–1546.
  • Lu L, Shiozawa K. Effect of two-step load variation on giga-cycle fatigue and internal crack growth behaviour of high carbon-chromium bearing steel. In: Sakai T, Ochi Y, editors. Proc of VHCF3. Japan: Society of Material Science; 2004. p. 185–192.
  • Mayer H, Fitzka M, Schuller R. Ultrasonic fatigue testing of 2024-T351 aluminum alloy at different load ratios under constant and variable amplitude. In: Berger C, Christ H-J, editors. Proc of VHCF5. Berlin: DVM; 2011. p. 355–360.
  • Navaei AE, Aghazadeh MJ. Fatigue damage accumulation in cold-drawn patented steel wire under variable loading. Mater Design. 2010;31:2018–2024.
  • Marco SM, Starkey WL. A concept of fatigue damage. Trans ASME. 1954;76:627–632.
  • Freudenthal AM, Heller RA. On stress interaction in fatigue and cumulative damage rule. J Aerospace Sci. 1959;26:431–442.
  • Ziha K. Fatigue yield. Int J Fatigue. 2009;31:1211–1214.
  • Liu Y, Mahadevan S. Stochastic fatigue damage modeling under variable amplitude loading. Int J Fatigue. 2007;29:1149–1161.
  • Line K, Mcdaniels R, Pulikollu R, Tryon R. Crack nucleation prediction through surface roughness measurement phase I. VEXTEC Corporation; 2008. (Final Report).
  • Nehila A, Li W, Zhao H. Interior failure mechanism and life prediction of surface-treated 17CrNi steel under high and very high cycle fatigue. Fatigue Fract Eng Mater Struct. 2018;41:1–12.
  • Deng H, Li W, Zhao H. Multiple fatigue failure behaviors and long-life prediction approach of carburized Cr-Ni steel with variable stress ratio. Materials. 2017;10:1084–1105.
  • Liu P, Li W, Nehila A, et al. High cycle fatigue property of carburized 20Cr gear steel under axial loading. Metals (Basel). 2016;6:246–260.
  • Mayer H, Haydn W, Schuller R, et al. Very high cycle fatigue properties of bainitic high carbon-chromium steel under variable amplitude conditions. Int J Fatigue. 2009;31:1300–1308.
  • Nehila A, Li W, Gao N, et al. Very high cycle fatigue of surface carburized CrNi steel at variable stress ratio: failure analysis and life prediction. Int J Fatigue. 2018;111:112–123.
  • Miner MA. Cumulative damage in fatigue. J Appl Mech. 1945;12:159–164.
  • Gao H, Huang H-Z, Zhu S-P, et al. A modified nonlinear damage accumulation model for fatigue life prediction considering load interaction effects. Sci World J. 2014;2014:164378.
  • Manson SS, Halford GR. Practical implementation of the double linear damage rule and damage curve approach for treating cumulative fatigue damage. Int J Fract. 1981;17:169–192.
  • Corten HT. Fracture mechanics of composites. Amsterdam: Elsevier Inc; 1972.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.