Abstract

Microstructural evolution and formation mechanism of reaction layer for 22MnB5 steel hot-dipped in Al–10Si (in wt %) alloy was investigated. The microstructural identification of the reaction layer was characterized via transmission electron microscopy and electron backscatter diffraction. In addition, the formation mechanisms of the phases were discussed with vertical section (isopleth) of the (Al–Si–Fe) ternary system. The solidified Al–Si coating layer consisted of three phases of Al, Si, and τ5 (Al8Fe2Si). The reaction layer on the Al–Si coating layer side is a fine τ5 phase (Al8Fe2Si) of 5 μm thickness. The layer on the steel side consisted of an η phase (Fe2Al5) of thickness of 500 nm or less. τ1 (Al2Fe3Si3, triclinic) phase of 200-nm-thickness was formed in the η phase, and κ phase (Fe3AlC) of 40–50 nm thickness was formed between η phase and steel. The τ5 phase was formed by isothermal solidification at 690 °C in the liquid Al–10 wt % Si when 3.73–29.0 wt % of Fe was dissolved from the boron steel into the Al–Si liquid bath. It was considered that the η phase was formed by the diffusion reaction of Al, Si, and Fe between τ5 and ferrite steel. κ (Fe3AlC) phase was formed by the reaction of the carbon, which is barely employed in η and τ phases, and diffused Al.

Highlights

  • Aluminized steels have a higher oxidation resistance than that of Zn-coated steels, and hot-dip aluminizing processes for coating steels with Al and Al alloys are widely used [1,2,3,4]

  • Commercial thermodynamic calculation software package (Thermo-Calc, version 6.0) on the basis of the Al database Thermo-Calc Al database version 6.0 (TCAL6) was used to calculate the vertical section of the (Al–Si–Fe) ternary system kept constant at 10 wt % Si and examine the formation mechanism of each phase

  • The microstructures of the reaction layer and phases formed on boron steel hot dipped in Al–10 wt % Si was investigated using a transmission electron microscopy (TEM) preparing with focused ion beam (FIB)

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Summary

Introduction

Aluminized steels have a higher oxidation resistance than that of Zn-coated steels, and hot-dip aluminizing processes for coating steels with Al and Al alloys are widely used [1,2,3,4]. Al–Si, the types of phases formed from the liquid side on the steel side are reported to be different. They are: (1) three phases consisting of the τ5 phase (Al7 Fe2 Si), θ phase (FeAl3 ), and η phase (Fe2 Al5 ) [11]; (2) three phases consisting of the τ5 phase (Al7 Fe2 Si), η phase (Fe2 Al5 ), and τ1 phase (Al2 Fe3 Si3 or Fe3 (AlSi)5 ) [12,13]; and (3) four phases consisting of the τ5 phase (Al8 Fe2 Si), θ phase (Fe4 Al13 ), η phase (Fe2 Al5 ), and τ1 phase (Fe3 Al2 Si) [14,15]. The composition of the θ phase can be represented by

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