Manuscript ID : JSM-2004-1582 (R1)
Visit : 267
Page: 57 - 66
10.22034/jsm.2021.1898031.1582
20.1001.1.20083505.2022.14.1.4.4
Article Type:
Original Research
Fatigue Life Assessment for an Aluminum Alloy Piston Using Stress Gradient Approach Described in the FKM Method
Subject Areas :
Engineering
H Ashouri
1
1 - Department of Mechanical Engineering, Varamin-Pishva Branch, Islamic Azad University, Varamin, Iran
Received: 2021-09-06
Accepted : 2021-12-08
Published : 2022-03-30
Keywords:
References:
He T., Lu X., Zou D., Guo Y, Li W., Huang M., 2014, Thermo-mechanical fatigue life prediction for a marine diesel engine piston considering ring dynamics, Journal of Advances in Mechanical Engineering 6: 429637.
Reyes Belmonte M.A., Copeland C.D., Hopkins G., Schmieder A., Bredda S., Akehurst S., 2015, Improving heat rtransfer and reducing mass in a gasoline piston using additive manufacturing, SAE Technical Paper 2015(01): 0505.
Lu Y., Zhang X., Xiang P., Dong D., 2016, Analysis of thermal temperature fields and thermal stress under steady temperature field of diesel engine piston, Journal of Applied Thermal Engineering 113: 796-812.
Liu X.F., Wanga Y., Liuc W.H., 2017, Finite element analysis of thermo-mechanical conditions inside the piston of a diesel engine, Journal of Applied Thermal Engineering 119: 312-318.
Caldera M., Massone J.M., Martı´nez A., 2017, Failure analysis of a damaged direct injection diesel engine piston, Journal of Failure Analysis and Prevention 17: 979-988.
Najafi M., Dastani H., Abedini M., Pirani S., 2019, Stress analysis and fatigue life assessment of a piston in an upgraded engine, Journal of Failure Analysis and Prevention 19: 402-411.
Mancaruso E., Sequino L., Vaglieco B.M., 2019, Temperature measurements of the piston optical window in a research compression ignition engine to set-up a 1d model of heat transfer in transient conditions, SAE Technical Paper 2019(24): 0182.
Nouby M., Ghazaly K., Abd El-Gwwad A., 2019, Evaluation of gasoline engine piston with various coating materials using finite element method, International Journal of Automotive Engineering 9(2): 2942-2948.
Yao Z., Qian Z., 2018, Thermal analysis of nano ceramic coated piston used in natural gas engine, Journal of Alloys and Compounds 768: 441-450.
Dudarevaa N.Y, Enikeeva R.D., Ivanov V.Y., 2017, Thermal protection of internal combustion engines pistons, Journal of Procedia Engineering 206: 1382-1387.
Changming H., Sichuan X., 2016, Multi-Body dynamic simulation and fatigue analysis of the unique crank-train for a creative two-stroke opposed piston diesel engine, SAE Technical Paper 2016(01): 2332.
Golbakhshi H., Namjoo M., Dowlati M., Khoshnam F., 2016, Evaluating the coupled thermo-mechanical stresses for an aluminum alloy piston used in a gasoline engine XU7, The Journal of Engine Research 42: 33-41.
Shariyat M., Fathi Sola J., Jazayeri S.A., 2016, Experimentally validated combustion and piston fatigue life evaluation procedures for the bi-fuel engines, using an integral-type fatigue, Latin American Journal of Solids and Structures 13: 1030-1053.
Kakaee A.H., Gharloghi J., Foroughifar A., KhanlariA., 2015, Thermo-mechanical analysis of an SI engine piston using different boundary condition treatments, Journal of Centeral South University 22: 3817-3829.
Giacopini M., Sissa S., Rosi R., Fantoni S., 2015, Influence of different temperature distributions on the fatigue life of a motorcycle piston, Journal of Automobile Engineering 229(9): 1276-1288.
Sharma D., Abdulaziz A., Mohammad A., Marwan A.A, Siniawski M.T., 2014, Thermal and mechanical failure analysis of a two-stroke motocross engine piston, Journal of Failure Analysis and Prevention 14: 21-26.
Ayatollahi M.R, Mohammadi F., Chamani H., 2013, Notch effects on high cycle fatigue life of engine components, 7th International Conference on Internal Combustion Engines, Iran.
Carpenter M., Jha P., Ray S., Nienhuis M.D., 2019, Fatigue tests of un-notched and notched specimens and life prediction using a variable critical distance method, SAE Technical Paper 2019(01): 0801.
Mirmohammadi A., Kalhor A., 2017, Studying turbocharging effects on engine performance and emissions by various compression ratios, American Journal of Energy and Power Engineering 4(6): 84-88.
Durat M., Kapsiz M., Nart E., Ficici F., Parlak A., 2012, The effects of coating materials in spark ignition engine design, Journal of Materials and Design 36: 540-545.
Stephens , Fatemi A., Fuchs H., 2001, Metal Fatigue in Engineering, John Wiley.
Lee Y.L, Pan J., Hathaway R.B., Barkey M.E., 2005, Fatigue Testing and Analysis: Theory and Practice, Elsevier Butterworth-Heinemann.
McKelvey S.A, Lee Y.L, Barkey M.E., 2012, Stress-based uniaxial fatigue analysis using methods described in FKM-guideline, Journal of Failure Analysis and Prevention 12: 445-484.
Lee Y.L, Barkey M., Kang H.T., 2012, Metal Fatigue Analysis Handbook: Practical Problem-Solving Techniques for Computer-Aided Engineering, Elsevier.
Haibach E., 2003, FKM-Guideline: Analytical Strength Assessment of Components in Mechanical Engineering, VDMA Verlag.
Ansys (V.18), 2018, User’s Manual.
Silva, F.S., 2006, Fatigue on engine pistons – a compendium of case studies, Journal of Engineering Failure Analysis, 13: 480-492.