Low cycle fatigue prediction for cylinder head considering notch stress-strain correction proposed by Neuber
Subject Areas : Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering
Hojjat Ashouri
1
(Department of Mechanical Engineering, Varamin-Pishva Branch, Islamic Azad University, Varamin, Iran)
Keywords:
Abstract :
[1] Zhang, H., Cui, Y., Liang, G., Li, L., Zhang, G., Qiao, X. (2021). Fatigue life prediction analysis of high‑intensity marine diesel engine cylinder head based on fast thermal fluid solid coupling method. Journal of the Brazilian Society of Mechanical Sciences and Engineering, https://doi.org/10.1007/s40430-021-03049-7.
[2] Liu, Y., Annabattula, P., Mirmiran, S., Zhang, L., Chen, J., Gaikwad, S., Singh,K., (2020). Assessing Thermo-mechanical Fatigue of a Cast Aluminum Alloy Cylinder Head of an Internal Combustion Engine. SAE Technical Paper No.2020-011077.
[3] Seifert, T., Hazime, R., Chang, C-C., Hu, C. (2019). Constitutive Modeling and Thermo-mechanical Fatigue Life Predictions of A356-T6 Aluminum Cylinder Heads Considering Ageing Effects. SAE Technical Paper No.2019-01-0534.
[4] Lai, W-J., E-P, C. (2018). Development of a Thermal Fatigue Test Bench for Cylinder Head Materials. SAE Technical Paper No.2018-01-1410.
[5] Wang, Y., Xu, Z., Chen, M. (2020). Thermo-Mechanical Fatigue and Life Prediction of Turbocharged Engine Cylinder Head. SAE Technical Paper No.2020-01-1163.
[6] Chen, M., Wang, Y., Wu, W., Cui, Q., Wang, K., Wang, L. (2016). Thermal-Mechanical Fatigue Prediction of Aluminum Cylinder Head with Integrated Exhaust Manifold of a Turbo Charged Gasoline Engine. SAE Technical Paper No.2016-01-1085.
[7] Ghasemi, A. (2012). Cylinder Head High/Low Cycle Fatigue CAE Analysis. SAE International Paper No.2012-01-1999.
[8] Zeng, X., Luo, X., Jing, G., Zou, P., Lin, Y., Wei, T., Yuan, X., Ge, H. (2020). Engine Cylinder Head Thermal-Mechanical Fatigue Evaluation Technology and Platform Application. SAE International Journal of Engines, 13(1), 101-120.
[9] Gordon, A.P., Williams, E.P., Schulist, M., APPLICABLITY OF NEUBER’S RULE TO THERMOMECHANICAL FATIGUE, Proceedings of the ASME Turbo Expo 2008, Germany.
[10] Kujawski, D., Teo, J. LK. (2017). A Generalization of Neuber’s Rule for Numerical Applications, Journal of Structural Integrity Procedia, 5,883-888.
[11] Ashouri, H. (2015). Finite element analysis of thermo-mechanical stresses in diesel engines cylinder heads using a two-layer viscoplasticity model, International Journal of Automotive Engineering, 5(4), 2054-2064.
[12] Ashouri, H. (2016). Thermo-mechanical analysis of fatigue cracks of diesel engines cylinder heads using a two-layer two-layer viscoplasticity model with considering viscosity effects, International Journal of Automotive Engineering, 6(2), 2163-2175.
[13] Ashouri, H. (2017). Thermal barrier coating effect on stress and temperature distribution of diesel engines cylinder heads using a two layer viscoelasticity model with considering viscosity, International Journal of Automotive Engineering, 7(2), 2380-2392.
[14] Beranger, M., Fiark, J-M., Ammar, K., Ccailetaud, G. (2018). A new fatigue model including thermal ageing for low copper aluminum-silicon alloys, Procedia Engineering, 213, 720-729.
[15] Satyanarayana, K., Hanumantha Rao, T-V. (2018). Response optimization of four stroke variable compression ratio diesel engine cylinder head with stress analysis, Materials Today: Proceedings, 5, 19497-19506.
[16] Jinga, G-X., Zhang, M-X., Qub, S., Pangb, J-C., Fub, C-M., Donga, C., Lib, S-X., Xua, C-G., Zhangb, Z-F. (2018). Investigation into diesel engine cylinder head failure, Journal of Engineering Failure Analysis, 90, 36–46.
[17] Fontea, M., Reis, L., Infanteb, V., (2019). Freitas, M. Failure analysis of cylinder head studs of a four stroke marine diesel engine, Journal of Engineering Failure Analysis, 101, 298–308.
[18] Pingale, A., Chang,C-Chi., Perander, J. (2021). Data Driven Model to Predict Cylinder Head Fatigue Failure, SAE Technical Paper No. 2021-01-0801.
[19] Ashouri, H. (2022). Thermo-mechanical analysis of magnesium alloy diesel engines cylinder heads using a two-layer viscoplasticity model, Automotive Science and Engineering, 12(3), 3892-3904.
[20] Keshavarz, M., Keshavarz, A. (2021). Dynamic optimization of load step transient response of a turbocharged spark ignition engine focusing on valves timing. Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineering, 13 (4),53-65.
[21] Ren, P-R., Song, W., Zhong, G., Huang, W-Q., Zuo, Z-X., Zhao, C-Z., Yan, K-J. (2021). High-cycle fatigue failure analysis of cast Al-Si alloy engine
cylinder head, Journal of Engineering Failure Analysis, 127, 1-15.
[22] Zhang, H., Xie, G., Liang, G., Li, L., Zhang, G., Lei, J. (2022). Application of Scaled Specimens in Evaluating Thermal Fatigue Performance of Cylinder Head, https://doi.org/10.1007/s40799-022-00597-y.
[23] Mahajan, P., Bodake, R., Thakur, A. (2021). Optimization of Scallop Design for Cylinder Head of a Multi-Cylinder Diesel Engine for Reduction of Combustion Deck Temperatures and Simultaneously Enhancing Combustion Deck Fatigue Margin. SAE Technical Paper No.2021-01-1233.
[24] Neuber, H. (1961). Theory of stress concentration for shear-strained prismatical bodies with arbitrary non-linear stress-strain law, ASME Journal of Applied Mechanics, 28, 544–550.
[25] Chaboche, J.L. (2008). A review of some plasticity and viscoplasticity constitutive theories, International Journal of Plasticity, 24, 1642–1693.
[26] Dowling, N. E. (1998). Mechanical Behavior of Materials, Prentice Hall.
[27] Stephens, R., Fatemi, A., Fuchs. H. (2001). Metal fatigue in engineering, 2nd edition, John Wiley.
[28] Metzeger, M., Leidenfrost, M., Werner, E., Riedel, H., Seifert, T. (2014). Lifetime Prediction of EN-GJV 450 Cast Iron Cylinder Heads under Combined Thermo-mechanical and High Fatigue Loading, SAE International Paper No.2014-01-9047.
[29] Xuyang, G., Cheng, Y., Zhang, Z. (2013). Thermo-mechanical fatigue life prediction of heavy duty diesel engine cylinder head, ASME International Mechanical Engineering Congress and Exposition, California, U.S.A.
[30] Takahashi, Sasaki, K. (2010). Low cycle fatigue of aluminum alloy cylinder head in consideration of changing metrology microstructure, Journal of Procedia engineering, 2, pp.67-776.
[31] Angeloni, M. (2011). Fatigue life evaluation of A356 aluminum alloy used for engine cylinder head, Ph.D. Thesis, University of Sau Palu, Brazil.
[32] Ashouri, H. (2022). Fatigue life assessment for an aluminum alloy piston using stress gradient approach described in the FKM method, Journal of Solid Mechanics, 14(1), 57-66.
[33] Li, J., Wang, P., Cui, X., Li, K., Yi, R. ( 2013). Gray Cast Iron Cylinder Head Thermal Mechanical Fatigue Analysis, Proceedings of the FISITA 2012 World Automotive Congress Lecture Notes in Electrical Engineering, 189, 243-257.
