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Comparison of the Crystallization Behavior of Silica Between Mg- and Al-Phosphate Used in Tension Coatings of Grain-Oriented Electrical Steel

  • Hyung-Ki Park
  • Min-Soo Han
  • Chang-Hwan Chang
  • Jong-Tae Park
  • Chang-Soo Park
  • Hyung-Don JooEmail author
Article
  • 2 Downloads

Abstract

The effect of the phosphate component on the thermal stability of tension coatings was investigated with a focus on the crystallization behavior of amorphous silica in the tension coating. After stress-relief annealing, core loss of samples coated with a Mg-phosphate was improved, while that coated with an Al-phosphate was deteriorated. The domain wall spacing of the samples coated with Mg- and Al-phosphates was respectively increased and decreased after stress relief annealing. This means that the stress relief annealing did not much diminish the tensile stress for Mg-phosphate coating but much diminished the tensile stress for Al-phosphate coating. Based on FTIR and XRD results, we found that the crystallization temperature of silica with Al-phosphate was lower than that of silica with Mg-phosphate. The crystallization of silica was accompanied by an abrupt volume change, which formed cracks in the tension coating and deteriorated the tensile stress.

Keywords

Grain-oriented electrical steel Tension coating Silica Crystallization Phosphate 

Notes

Acknowledgements

The authors gratefully acknowledge POSCO Technical Research Laboratories for financially and technically supporting this research.

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Copyright information

© The Korean Institute of Metals and Materials 2019

Authors and Affiliations

  • Hyung-Ki Park
    • 1
  • Min-Soo Han
    • 2
  • Chang-Hwan Chang
    • 3
  • Jong-Tae Park
    • 2
  • Chang-Soo Park
    • 2
  • Hyung-Don Joo
    • 2
    Email author
  1. 1.Gangwon Regional DivisionKorea Institute of Industrial TechnologyGangneungRepublic of Korea
  2. 2.POSCO Technical Research LaboratoriesPOSCOPohangRepublic of Korea
  3. 3.Analysis & Assessment GroupResearch Institute of Industrial Science & TechnologyPohangRepublic of Korea

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