International Scientific Journal


In order to study the influence of welding flash on heat transfer performance of steel piston cooling gallery, the pistons with different structures are studied. In this paper, the finite element simulation calculation of the steel piston with the welding flash and the non-flash structure on the same model and the annular cavity section is carried out separately, and the amount of carbon deposited in the top of the steel piston and cooling gallery after 1000 hours test is measured. The comparative analysis finds that the existence of welding flash hinders the heat transfer of cooling gallery, resulting in an increase in the temperature of the inner surface of cooling gallery, which in turn increases the temperature of entire piston head. Carbon deposits in the top surface and cooling gallery of the steel piston, which affects the cooling effect.
PAPER REVISED: 2022-04-20
PAPER ACCEPTED: 2022-04-29
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THERMAL SCIENCE YEAR 2022, VOLUME 26, ISSUE Issue 6, PAGES [4993 - 5000]
  1. Lv, J., Wang, P., Bai, M., Li, G., & Zeng, K. . "Experimental visualization of gas-liquid two-phase flow during reciprocating motion," Applied Thermal Engineering, vol.79,p. 63-73, 2015
  2. Peng, W., Jizu, L., Minli, B., Yuyan, W., Chengzhi, H., & Liang, Z. . "Numerical simulation on the flow and heat transfer process of nanofluids inside a piston cooling gallery," Numerical Heat Transfer,vol. 65,no. 4,p. 378-400,2014
  3. Torregrosa, A. J., Broatch, A., Olmeda, P., & J Mart, N. . "A contribution to film coefficient estimation in piston cooling galleries," Experimental Thermal & Fluid Science, vol.34, no.2, p.142-151, 2010
  4. Kortas, J. . "From aluminium pistons to steel pistons in trucks and ships," Mtz Worldwide,vol. 66,no. 11, p.23-25, 2005
  5. Du, S., Xiaobing, H., Man, G., & Zhang, Y. . " Friction welding parameters of forged steel piston and joint microstructure," Welding & Joining, vol. 4, p.13-16, 2014
  6. Du H W. "Monosteel Is Expected to be Widely Applied in China Market," Commercial Vehicle, vol. 4, p.70-72, 2016
  7. Koszalka, G., Suchecki, A., & Pielecha, J. . " Analysis of design parameters of pistons and piston rings of a combustion engine," MATEC Web of Conferences,(Poland), 2017, vol. 118, pp.00013
  8. Liu, J. X., Wang, Y., & Zhang, W. Z. . "The Effects of the Cooling Gallery Position on the Piston Temperature Field and Thermal Stress," Applied Mechanics & Materials, vol. 37-38, p.1462-1465, 2010
  9. Wang, P., Han, K., Yoon, S., Yu, Y., & Liu, M. . "The gas-liquid two-phase flow in reciprocating enclosure with piston cooling gallery application," International Journal of Thermal Sciences, vol.p.129, 73-82, 2018
  10. Kong, R., Kim, S., Bajorek, S., Tien, K., & Hoxie, C. . "Effects of Pipe Size on Horizontal Two-Phase Flow: Flow Regimes, Pressure Drop, Two-Phase Flow Parameters, and Drift-Flux Analysis," Experimental Thermal & Fluid Science , S0894177718302966, 2018
  11. Fu, W. S., Lian, S. H., & Hao, L. Y. . "An investigation of heat transfer of a reciprocating piston," International Journal of Heat & Mass Transfer, vol.49, 23-24, p.4360-4371, 2006
  12. Pan, J., Nigro, R., & Matsuo, E. . "3-D Modeling of Heat Transfer in Diesel Engine Piston Cooling Galleries," Sae World Congress & Exhibition, (United States), 2005, pp.1644
  13. Wang, P., Liang, R., Yu, Y., Zhang, J., Lv, J., & Bai, M. . "The flow and heat transfer characteristics of engine oil inside the piston cooling gallery," APPLIED THERMAL ENGINEERING,vol. 115, p.620-629, 2017
  14. Wang, P., Lv, J., Bai, M., Li, G., & Zeng, K. . "The reciprocating motion characteristics of nanofluid inside the piston cooling gallery," Powder Technology, vol.274, p.402-417, 2015
  15. A, X. D., A, J. L., B, J. W., B, Z. W., & A, L. S. . "Numerical Investigation on the Oscillating Flow and Uneven Heat Transfer Processes of the Cooling Oil inside a Piston Gallery," Applied Thermal Engineering, vol.126, p. 139-150, 2017
  16. Zhaowen W., Dong Z., Gang L., Pei Z., Mingtao X., Cheng Xiaobei.Enhanced mechanism of multi-chamber oscillation cooling of large marine diesel engine piston
  17. Zhiming W., Pingjian M.. Study on circumferential heat transfer characteristics of piston annular oil cavity oscillation cooling
  18. Xiwen D., Hao C., Qianfan X., Jilin L., Dewen J., Xiaojia Y.. Flexible section-profile design of a cooling gallery inside a diesel engine piston
  19. Zhiyuan X.. Simulation experimental study on the enhancement of reciprocating oscillation shock heat transfer by the modification of the microstructure of the internal combustion engine piston cooling oil cavity wall
  20. Lv Z., Xinqi Q., Peiyou X., Rui L.. Simulation study on oscillation cooling characteristics of gasoline engine piston inner cooling oil cavity
  21. Lijun D., Jian Z., Guannan H.. Influence of cooling gallery structure on the flow patterns of two-phase flow and heat transfer characteristics
  22. Jilin L., Pan Y., Xiwen D., Yuhua B., Dewen J.. Numerical investigation on the effects of spatial angle on oscillating flow and heat transfer characteristics of piston cooling galleries
  23. Deng, L., Liu, Y., Xiong, P., & Wang, Z.. "Effect of Oil Cooling Gallery on Piston Secondary Motion in a Highly Intensified Internal Combustion Engine,"(in Chinese), Automotive Engineering. vol.39, no. 3, p.269-274, 2017

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