THERMAL SCIENCE

International Scientific Journal

Thermal Science - Online First

Huizeying Zhang

,

Mingxin Gao

,

Lincong Xu

,

Yang Wang

online first only

Design and simulation of supersonic profiling nozzle for U78CRV rail heat treatment

ABSTRACT
In order to address with the defects of poor cooling capacity and cooling uniformity of the rail air-quenching technology, the supersonic profiling nozzle (SP nozzle) was designed to improve the cooling capacity through supersonic jet and improve the cooling uniformity through the profiling structure of the rail head. Numerical simulation method combined with experimental were used to study the heat transfer characteristics of SP nozzle on rail. The results showed that air-cooled quenching at a pressure of 0.4 MPa increased the cooling capacity of the SP nozzle by 23.96%, 15.35% and 31.69%, and the cooling uniformity by 36.82%, 46.98% and 22.19% over the existing circular normal nozzle, circular supersonic nozzle and normal profiling nozzle, respectively. A segmented cooling process curve of "slow first and then fast" was designed, and the cooling time of the segmented cooling SP nozzle was shortened by 49s compared with the CR nozzle. Compared to the SP nozzle cooled at a constant rate, the cooling time is shortened by 35 seconds. Regulate the inlet pressure of the SP nozzle to cool the rail at a cooling rate close to but not exceeding the critical cooling rate of pearlite transformation before the rail temperature is lower than the end temperature of pearlite transformation (about 500 ℃),and then increase the inlet pressure as much as possible, which is beneficial to improve the production efficiency on the premise of ensuring the performance of the heat-treated rail.
KEYWORDS
rail, heat treatment, supersonic profilingnozzle, heat exchange characteristics
PAPER SUBMITTED: 2024-11-11
PAPER REVISED: 2025-01-07
PAPER ACCEPTED: 2025-01-13
PUBLISHED ONLINE: 2025-04-05
DOI REFERENCE: https://doi.org/10.2298/TSCI241111066Z
REFERENCES
  1. Hu, J., et al., Cause analysis of partial shelling on rail tread of high-speed railway, Heat Treatment of Metals, 44.S1(2019), pp. 186-189
  2. Wang, X., Research on the service life of rails and extension measures of the Da qin Railway, China Railway, 06(2011), pp. 43-46
  3. Ding, H., et al., Effect of preheating/post-isothermal treatment temperature on microstructures and properties of cladding on U75V rail prepared by plasma cladding method, Surface and Coatings Technology, 399(2020), pp. 126122
  4. Gao, M., et al., Effect of Alloying Elements on Pearlite Critical Cooling Rate of U75V Rail-steel, Transactions of the Indian Institute of Metals, 76.3(2022), pp 665-673
  5. Li, B., et al., Dynamic CCT curve of U75V steel for high-speed railway, Journal of Iron and Steel Research, 26.11(2014), pp. 20-24
  6. Li, C., Online heat treatment of U75V rail, Heat Treatment of Metals, 43.01(2018), pp. 152-156
  7. Zhang, W., Study on bending deformation and residual stress of U75V heavy rail air-cooled quenching. D. thesis, Liaoning University of Science and Technology, Anshan, China, 2022
  8. Gao, M., et al., Investigation the transient heat transfer to a supersonic air jet impinging on a high-temperature plate based on a discrimination-experiment method, PLOS ONE, 17.3(2022), pp. 1-27
  9. Song, L., Study on flow field and temperature field of U75V heavy rail supersonic air-cooled quenching. D. thesis, Liaoning University of Science and Technology, Anshan, China, 2021
  10. Li, X., et al., Simulation of Temperature-field During Rail Air-cooling Quenching Process, Journal of Wuhan University of Technology, 34.7(2012), pp. 146-148
  11. Li, D., et al., Improvement of the Heat Treatment Process of U72Mn Steel Rail-Head, Heat Treatment of Metals, 29.12(2004), pp. 65-68
  12. Shan, Z., Design and study of 60kg/m heavy rail air-cooled quenching profiling nozzle. D. thesis, Liaoning University of Science and Technology, Anshan, China, 2022
  13. Kang, H., Experimental study on key technologies of U75V heavy rail on-line heat treatment process. D. thesis, Northeastern University, Shenyang, China, 2012
  14. Karimi, A. et al., Selective dehydration of high-pressure natural gas using supersonic nozzles, Chemical Engineering & Processing Process Intensification, 48.1(2009), pp. 560-568
  15. Xie, J., et al., Simulation Analysis of Supersonic Nozzle Discharge Coefficient, Chinese Hydraulics & Pneumatics, 46.12(2022), pp. 123-128
  16. Wu, J., Numerical simulation of U75V normalizing cooling process based on Fluent. D. thesis, Beijing Jiao Tong University, Beijing, China, 2021
  17. S, S., et al., Application of a Reynolds-Stress Turbulence Model to the Compressible Shear Layer, ICASE Report 90-18NASA CR, 1990, pp. 182002
  18. John, D., Fundamentals of Computational Fluid Dynamics and Its Applications, China Machine Press., Beijing, China, 2007
  19. Yang, J., et al., Numerical study of transient conjugate heat transfer of the cryo-supersonic air-quenching based on a Mach-weighted pressure-based method, International Journal of Heat and Mass Transfer, 134(2019), pp. 586-599
  20. Kang, H., et al., Relationship between Rockwell hardness and pearlite lamellar spacing of hardened layer under different cooling rates for U75V 60kg/m heavy rail, Materials Science & Engineering Technology, 52.4(2021), pp.460-467
  21. Guo, D., et al., Laminar plasma jet surface hardening of the U75V rail steel: Insight into the hardening mechanism and control scheme-ScienceDirect, Surface and Coatings Technology, 394(2020), pp. 125857
PDF VERSION [DOWNLOAD]
Design and simulation of supersonic profiling nozzle for U78CRV rail heat treatment