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Effect of Galvanizing Furnace Temperature on Material Property and Galvanized Surface of Hot Rolled Galvanized Steel

  • Jong Chan Jeong (Quality technology department automotive steel quality control section, POSCO Gwangyang works) ;
  • Jae Joong Kim (Automotive Steel Research Lab, POSCO Technical Research Laboratories) ;
  • Seong Ho Han (Automotive Steel Research Lab, POSCO Technical Research Laboratories)
  • Received : 2024.02.08
  • Accepted : 2024.05.30
  • Published : 2024.08.30

Abstract

Recently, hot rolled galvanized steel is widely used in automotive parts. As the paradigm of the automotive market has changed from fossil fuel vehicle to electric vehicle, the automotive industry needs more high-strength steels to reduce weights of automobiles. However, because high-strength steel contains high solute carbon, it is expected to have a risk of stretcher-strain on the surface due to dislocation trapping by solute [C] and [N]. Generally, galvanized steel is supposed to pass through a furnace around the temperature of Zinc pot to increase material temperature. Otherwise, the inhibition layer could not be formed. However, solute carbon and nitrogen are volatile enough to move around the furnace temperature. Moreover, the ratio of ferrite phase and precipitated Fe3C can be variable, resulting in yield point elongation related to the stretcher strain. Furthermore, the quality of the galvanized surface can be affected by a high temperature of the furnace. Although a relatively hot rolled galvanizing line furnace has a lower temperature than an annealing line furnace, it can affect various quality aspects. In other words, this paper aims to determine how these phenomena appear concerning furnace temperature.

Keywords

References

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