Multiaxial fatigue analysis for the shaft of a 100 MW hydro-power generator

Authors

  • C. A. Mantilla CELSIA Calle 15 # 29B-30, Autopista Cali-Yumbo, Cali, COLOMBIA
  • J. A. Valdés School of Mechanical Engineering, Universidad del Valle Calle 13 # 100-00, Cali, COLOMBIA Phone: +5723212100 ext 7349; Fax: +5723334899
  • F. Casanova School of Mechanical Engineering, Universidad del Valle Calle 13 # 100-00, Cali, COLOMBIA Phone: +5723212100 ext 7349; Fax: +5723334899

DOI:

https://doi.org/10.15282/jmes.13.2.2019.12.0409

Keywords:

Fatigue life, damage, multiaxial stress, hydro-generator, stress measurement

Abstract

This paper presents a stress and fatigue life analysis for the shaft of a 100  hydro-generator. Normal and shear stresses were measured at the cylindrical section of the shaft at several power levels. A finite element model was developed to find points with stress concentration and the corresponding stress concentration factor. Analytical models taken from the literature were implemented to calculate stresses during phase-to-ground and phase-to-phase failure. Stresses were linked with the generation history of the machine taken each hour during one year to obtain the stress history. With the stress history, the Wang-Brown multiaxial fatigue model and the Miner’s rule were used to estimate the fatigue life.

Stresses on the shaft were found to be dependent on the generated power. Operation at partial load (between 30 and 60% of full load) was found to produce higher vibration in comparison with operation at power greater than 60% of full load. Changing the power level produced higher damage than the vibration produced during operation at a steady state condition. It was found that the shaft has a practically infinite life even when the damage produced during electrical failure was considered. 

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Published

2019-06-28

How to Cite

[1]
C. A. Mantilla, J. A. Valdés, and F. Casanova, “Multiaxial fatigue analysis for the shaft of a 100 MW hydro-power generator”, J. Mech. Eng. Sci., vol. 13, no. 2, pp. 4928–4945, Jun. 2019.

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