Journal of the Korean Society for Precision Engineering (한국정밀공학회지)

Korean Society for Precision Engineering (한국정밀공학회)
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Study of Axial and Torsional Fatigue Life Prediction Method for Low Pressure Turbine Rotor Steels

저압터빈용 로터강의 이축 피로수명예측법에 관한 연구

  • 현중섭 (한국전력공사 전력연구원 수화력발전연구소) ;
  • 송기욱 (한국전력공사 전력연구원 수화력발전연구소) ;
  • 이영신 (충남대학교 기계설계공학과)
  • Published : 2005.12.01
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Abstract

The rotating components such as turbine rotors in service are generally subjected to multiaxial cyclic loading conditions. The prediction of fatigue lift for turbine rotor components under complex multiaxial loading conditions is very important to prevent the fatigue failures in service. In this paper, axial and torsional low cycle fatigue tests were preformed for 3.5NiCrMo steels serviced low pressure turbine rotor of nuclear power plant. Several methods to predict biaxial fatigue life such as Tresca, von Mises and Brown & Miller's critical plane approach were evaluated to correlate the experimental results for serviced NiCrMoV steel. The fracture mode and fatigue characteristics of NiCrMoV steel were discussed based on the results of fatigue tests performed under the axial and torsional test conditions. In particular, the Brown and Miller's critical plane approach was found to best correlate the experimental data with predictions being within a factor of 2.

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References

  1. Ha, J.S., Kim, K.Y. ami Ahn, H.D., 'A Study on the Thermal-Mechanical Fatigue Life Prediction of 12Cr Steel,' Journal of KSPE, Vol. 11, No.4, pp. 114-125, 1994
  2. Kang, M.S., 'Low Cycle Fatigue Behavior of 12Cr Steel for Thermal Power Plant Steam Turbine,' Journal of KSPE, Vol. 19, No.8, pp. 71-76, 2002
  3. Berger, C., 'Present Status of Investigations on three Superclean 3.5%NiCrMoV Rotors,' Superclean Rotor Steels workshop Proceedings, pp. 31 - 48, 1989
  4. Anderson, A.F., Williams, R.A. and Wilkening, W.W., 'A Methodology for Predicting Torsional Fatigue Life of Turbine Generator Shafts Using Crack Initiation Plus Propagation,' EPRI Report EL-4333, 1985
  5. Brown, M.W. and Miller, K.J., 'A Theory for Fatigue Under Multiaxial Stress-Strain Conditions,' Proceedings of the Institution of Mechanical engineers, vol. 187, IMechE, pp. 745 - 755, 1973
  6. Garud, Y.S., 'A New Approach to the Evaluation of Fatigue Under Multiaxial Loadings,' Journal of Engineering Materials and Technology, ASME Transactions, Vol. 103, pp. 118 - 125, 1981 https://doi.org/10.1115/1.3224982
  7. Socie, D. 'Multiaxial Fatigue Damage Models,' Journal of Engineering Materials and Technology, Vol. 109, pp. 293 - 298,1987 https://doi.org/10.1115/1.3225980
  8. Peter, J. B. and Sreeramesh, K. 'Elevated Temperature Axial and Torsional Fatigue Behavior of Haynes 188,' Journal of Engineering Materials and Technology, Vol. 117, pp. 191 - 198, 1995 https://doi.org/10.1115/1.2804529