Scientific Research and Essays

  • Abbreviation: Sci. Res. Essays
  • Language: English
  • ISSN: 1992-2248
  • DOI: 10.5897/SRE
  • Start Year: 2006
  • Published Articles: 2768

Full Length Research Paper

Reliability of vibratory indications during the follow-up of bearing spalling

Omar DJEBILI
  • Omar DJEBILI
  • Laboratory of Energetics, Mechanics and Engineering, University of Boumerdes, Algeria.
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Oussama BERBRI
  • Oussama BERBRI
  • Laboratory of Energetics, Mechanics and Engineering, University of Boumerdes, Algeria.
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  •  Received: 19 April 2021
  •  Accepted: 13 July 2021
  •  Published: 31 August 2021

References

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Alfredson RJ, Mathew J (1985b). Time domain methods for monitoring the condition of rolling element bearings. Transactions of the Institution of Engineers, Australia. Mechanical engineering ME 86(2):102-107.

  
 

Allison B, Pandkar A (2018). Critical factors for determining a first estimate of fatigue limit of bearing steels under rolling contact fatigue. International Journal of Fatigue 117:396-406.
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Bastami AR, Vahid S (2021). A comprehensive evaluation of the effect of defect size in rolling element bearings on the statistical features of the vibration signal. Mechanical Systems and Signal Processing 151:107334.
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Dudragne G (2000). Rolling element bearings: Operational limits and damage mechanisms. Mecanique et Industries 1(6):593-602. (In French).
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El Laithy M, Wang L, Harvey TJ, Vierneusel B, Correns M, Blass T (2019). Further understanding of rolling contact fatigue in rolling element bearings - A review. Tribology International 140:105849.
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Fernandes PJL (1997). Contact fatigue in rolling-element bearings. Engineering Failure Analysis 4(2):155-160.
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Gupta PK, Zaretsky EV (2018). New stress-based fatigue life models for ball and roller bearings. Tribology Transactions 61(2):304-324.
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Lei Y, Li N, Guo L, Li N, Yan T, Lin J (2018). Machinery health prognostics: A systematic review from data acquisition to RUL prediction. Mechanical Systems and Signal Processing 104:799-834.
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Manoj V, Manohar Shenoy K, Gopinath K (2008). Developmental studies on rolling contact fatigue test rig. Wear 264(7 8):708-718.
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Rycerz P, Olver A, Kadiric A (2017). Propagation of surface initiated rolling contact fatigue cracks in bearing steel. International Journal of Fatigue 97:29-38.
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Tallian TE (1999). Failure atlas for Hertz contact machine elements. ASME Press, New York P 496.

  

 

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