Identification of Cracking Issues and Process Improvements through Plant Monitoring and Numerical Modelling of Secondary Cooling during Continuous Casting of HSLA Steels

Identification of Cracking Issues and Process Improvements through Plant Monitoring and Numerical Modelling of Secondary Cooling during Continuous Casting of HSLA Steels

A holistic approach to diagnose the occurrence of cracking on HSLA steel slabs and propose countermeasures to prevent them is presented. The approach consisted on plant monitoring, including direct temperature measurements in the strand with pyrometers. Extensive characterization was performed via t...

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Bibliographic Details
Published in:ISIJ International Vol. 61; no. 3; pp. 834 - 843
Main Authors: Huitron, Rosa Maria Pineda, Lopez, Pavel Ernesto Ramirez, Vuorinen, Esa, Jalali, Pooria Nazem, Kärkkäinen, Maija
Format: Journal Article
Language:English
Published: The Iron and Steel Institute of Japan 15-03-2021
Subjects:
3-d numerical models
Continuous casting
Cooling
cooling curves
crack susceptibility
Cracks
Direct temperature measurement
Ductility
Engineering Materials
Ferrite
High-strength low-alloy steel
HSLA steels
Materialteknik
Microscopy technique
Microstructure characterization
Numerical models
Operation parameters
Optimization strategy
plant monitoring
Steel castings
Temperature measurement
Temperature variation
Tundish temperature
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Summary:A holistic approach to diagnose the occurrence of cracking on HSLA steel slabs and propose countermeasures to prevent them is presented. The approach consisted on plant monitoring, including direct temperature measurements in the strand with pyrometers. Extensive characterization was performed via thermo-mechanical tests and microscopy techniques which revealed combination of Widmanstätten ferrite, acicular ferrite and secondary phases that promote embrittlement during casting with a minimum ductility between 700°C–800°C (± 50°C) which is responsible for cracking in this steel. Finally, 1D and 3D numerical models were developed to test possible cooling strategies which proved that reductions in water flowrate can have a positive effect in slab quality by avoiding the low ductility zone. Corrective actions included decreasing cooling to increase the overall temperature of the strand before the straightener to increase the overall temperature. Yet, some slabs still observed the presence of cracks which points at secondary factors such as high tundish temperatures >1530°C producing cracking. Other secondary factors include strong temperature variations up to ± 250°C during measurements which would send the strand corners into the low ductility range producing cracking despite having a hot slab centre. Although these optimization strategies are particular to each caster and steel grade, a similar approach could be applied to address secondary cooling issues during continuous casting. The models presented are an ideal toolkit to analyse the influence of product size and operation parameters in combination with plant monitoring and extensive microstructure characterization to improve the quality and productivity of the process.
ISSN:0915-1559
1347-5460
1347-5460
DOI:10.2355/isijinternational.ISIJINT-2020-442