Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance
Feshar, M., MAHGOUB, F., Abdel-Gaber, A. (2023). Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance. EKB Journal Management System, 1(2), 64-70. doi: 10.21608/ajst.2024.333736
Magdy T Feshar; Fatma MAHGOUB; Ashraf Abdel-Gaber. "Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance". EKB Journal Management System, 1, 2, 2023, 64-70. doi: 10.21608/ajst.2024.333736
Feshar, M., MAHGOUB, F., Abdel-Gaber, A. (2023). 'Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance', EKB Journal Management System, 1(2), pp. 64-70. doi: 10.21608/ajst.2024.333736
Feshar, M., MAHGOUB, F., Abdel-Gaber, A. Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance. EKB Journal Management System, 2023; 1(2): 64-70. doi: 10.21608/ajst.2024.333736

Optimization of the Steel Casting Process Parameters to Control the Longitudinal Facial Crack (LFC) Defect Appearance

Alexandria Journal of Science and Technology
Volume 1, Issue 2, December 2023, Page 64-70  XML PDF (1.03 MB)
Document Type: Original Article
DOI: 10.21608/ajst.2024.333736
View on SCiNiTO View on SCiNiTO
Authors
Magdy T Feshar email orcid 1; Fatma MAHGOUBorcid 1; Ashraf Abdel-Gaber2
1Institute of Graduate Studies and Research, Materials Science Department, Alexandria University, 21526 Alexandria, Egypt
2Faculty of Science, Alexandria University, Alexandria, Egypt.
Abstract
The target of this research was to identify the occurrence of the longitudinal facial crack (LFC) defect during the casting of a low-carbon, low-manganese flat steel product. Despite the severity of this defect which may be minor, it turned out unacceptable in the final product due to the remarkable production losses associated with reproducing the product. Electrochemical testing was executed on samples of the LFC defect, which were compared to a control sample. Additionally, Selected LFC samples were also analyzed using scanning electron microscopy and energy-dispersive X-ray spectroscopy at various process parameters such as carbon equivalent, isostatic flow control, non-metallic inclusion, mold flux to determine the root cause of the LFC defect. The findings of this investigation revealed that optimizing specific process parameters in both the thin slab caster and the melt shop effectively controlled the appearance of LFC defects. By manipulating these parameters, it was possible to mitigate the occurrence of LFC defects and prevent the associated economic losses, which result from having to reproduce the product. The likelihood of LFC defects can be drastically reduced by identifying and solving the underlying root causes of the defect, such as adjusting carbon equivalent, isostatic flow control material, managing non-metallic inclusions, and improving mold flux. These results underline how crucial it is to properly optimize the process variables in order to guarantee the manufacture of premium low-carbon, low-manganese flat steel products.
Keywords
LFC; SEM; Electrochemical Techniques; Heat Flux; Mold Flux
Statistics
Article View: 58
PDF Download: 49