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عنوان URL للمقالة


رقم المقالة : JSME-2210-1226 (R2) زيارة : 224 الصفحة: 53 - 62

20.1001.1.27834441.2022.14.4.6.2

نوع المخطوط: ابحاث

Numerical simulation of piston with different materials for justification of its strength

الموضوعات : فصلنامه شبیه سازی و تحلیل تکنولوژی های نوین در مهندسی مکانیک

Bharosh Kumar Yadav 1 , Babin Dangal 2 , Shiva Shanker Pandey 3 , Mehdi Jahangiri 4

1 - Department of Mechanical Engineering, Institute of Engineering (IOE), Tribhuvan University (TU), Purwanchal Campus, Dharan-08, Nepal
2 - Department of Mechanical Engineering, Purwanchal Campus, Institute Of Engineering, Tribhuvan University, Dharan-08, Nepal.
3 - Department of Mechanical Engineering, Purwanchal Campus, Institute Of Engineering, Tribhuvan University, Dharan-08, Nepal.
4 - Energy Research Center, Shahrekord Branch, Islamic Azad University, Shahrekord, Iran.

تاريخ الإرسال : 21 الإثنين , ربيع الأول, 1444 تاريخ التأكيد : 07 السبت , جمادى الثانية, 1444 تاريخ الإصدار : 07 الخميس , جمادى الأولى, 1444

الکلمات المفتاحية: ANSYS, Piston, SOLIDWORKS, Structural and thermal analysis,

ملخص المقالة :

This project deals with the determination of best material among the three selected ones. Initially, based on systematic literature review, three materials, i.e. aluminium 4032, grey cast iron and titanium 6Al-6V, were selected, and their properties were determined. Then, design specifications form YAMAHA FZV3 was taken, and required design parameters and necessary dimensions of the piston were calculated. After this, the piston's Design was performed using SOLIDWORKS 2016, followed by structural and thermal analysis using ANSYS 16.0. Finally, the results were compared and it was noticed that among three materials the highest deformation was seen for aluminum which was 31.77% more than titanium alloy while the maximum difference in stress was for grey cast iron with 39.7% more than titanium alloy. Also, the heat flux for titanium alloy was least. This indicated that titanium 6Ai-4V gave better for durability and structural and theoretical performance. Hence, it was concluded to be the best material among the selected ones for the piston used.

المصادر:

 

  • Dai, Z., Wang, C., Zhang, D., Tian, W., Qiu, S., & Su, G. H. (2021). Design and analysis of a free-piston stirling engine for space nuclear power reactor. Nuclear Engineering and Technology53(2), 637-646.
    •
  • Barbieri, S. G., Giacopini, M., Mangeruga, V., & Mantovani, S. (2017). A design strategy based on topology optimization techniques for an additive manufactured high performance engine piston. Procedia Manufacturing11, 641-649.
    •
  • Arsha, A. G., Jayakumar, E., Rajan, T. P. D., Antony, V., & Pai, B. C. (2015). Design and fabrication of functionally graded in-situ aluminium composites for automotive pistons. Materials & Design88, 1201-1209.
    •
  • Gopal, G., Kumar, L. S., Reddy, K. V. B., Rao, M. U. M., & Srinivasulu, G. (2017). Analysis of Piston, Connecting rod and Crank shaft assembly. Materials Today: Proceedings4(8), 7810-7819.
    •
  • Liu, X. F., Wang, Y., & Liu, W. H. (2017). Finite element analysis of thermo-mechanical conditions inside the piston of a diesel engine. Applied Thermal Engineering119, 312-318.
    •
  • Floweday, G., Petrov, S., Tait, R. B., & Press, J. (2011). Thermo-mechanical fatigue damage and failure of modern high performance diesel pistons. Engineering Failure Analysis18(7), 1664-1674.
    •
  • Bawankar, C. S., & Gupta, R. (2016). Effects of piston bowl geometry on combustion and emission characteristics on diesel engine: a cfd case study. International Journal of Research in Engineering and Technology5, 81-93.
    •
  • Jaichandar, S., & Annamalai, K. (2012). Effects of open combustion chamber geometries on the performance of pongamia biodiesel in a DI diesel engine. Fuel98, 272-279.
    •
  • AZO Materials. Titanium Alloys - Ti6Al4V Grade 5. Available from: https://www.azom.com/properties.aspx?ArticleID=1547 (04 August 2021)
    •
  • AZO Materials. Aluminium/Aluminum 4032 Alloy (UNS A94032). 2012, SEP 13; Available from: https://www.azom.com/article.aspx?ArticleID=6622 (04 August 2021)
    •
  • Guesser, L. W., & Guedes, L. C. (1997). Recent developments in cast iron applied to the automotive industry. In IX Symposium on Automotive Engineering(Vol. 8).
    •
  • Sonar, D. K., & Chattopadhyay, M. (2015). Theoretical analysis of stress and design of piston head using CATIA & ANSYS. International Journal of Engineering Science Invention4(6), 52-61.
    •
  • Khurmi, R. S., & Gupta, J. K. (2005). A textbook of machine design. S. Chand publishing.
    •
  • Specifications of Yamaha, 2019, December 15; Available from: https://www.bikedekho.com/yamaha/fz-s-fi-version-3/specifications (04 August 2021)
    •
  • ANSYS, T.S., ANSYS Theory Reference. Eleventh ed. 1999, Canonsburg, PA: ANSYS, Inc. http://lmee.univ-evry.fr/~hello/ENS/CS93/ANSYS/ANSYS%20Mechanical%20APDL%20Theory%20Reference.pdf
    •
  • Keribar, R., & Morel, T. (1987). Thermal shock calculations in IC engines. SAE transactions, 130-148.
    •
  • Lu, Y., Zhang, X., Xiang, P., & Dong, D. (2017). Analysis of thermal temperature fields and thermal stress under steady temperature field of diesel engine piston. Applied thermal engineering113, 796-812.
    •

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