Influences of Alloying Elements on Continuous Cooling Phase Transformation and Microstructures of Extremely Fine Pearlite

Influences of Alloying Elements on Continuous Cooling Phase Transformation and Microstructures of Extremely Fine Pearlite

In the present research, the cooling phase transformation characteristics and microstructures of a Co- and Al-containing high-carbon steel were investigated under slow cooling rates (0.02–2.0 °C/s). In addition, by means of a Thermecmastor thermal simulator, the phase transformation temperatures wer...

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Veröffentlicht in:Metals (Basel ) 2019-01, Vol.9 (1), p.70
Hauptverfasser: Feng, Lulu, Hu, Feng, Zhou, Wen, Ke, Rui, Zhang, Guohong, Wu, Kaiming, Qiao, Wenwei
Format: Artikel
Sprache:eng
Schlagworte:
Alloying elements
Bainitic transformations
bridge cable steel
Carbon steel
Cooling
Cooling curves
Cooling rate
Diamond pyramid hardness
extremely fine pearlite
Free energy
hardness
High carbon steels
Magnetic fields
microstructure
Pearlite
Phase transitions
Scanning electron microscopy
Simulation
slow cooling
Software
Temperature
Tensile strength
Thermal simulation
Thermal simulators
Thermal transformations
Transformation temperature
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Zusammenfassung:In the present research, the cooling phase transformation characteristics and microstructures of a Co- and Al-containing high-carbon steel were investigated under slow cooling rates (0.02–2.0 °C/s). In addition, by means of a Thermecmastor thermal simulator, the phase transformation temperatures were measured, and the corresponding continuous cooling transformation (CCT) curves were plotted. It was found that an extremely fine, fully pearlitic structure with an interlamellar spacing of 45 nm, and a hardness of 425 HV1 (Vickers hardness under 1 kg load) were obtained at a cooling rate of 0.1 °C/s. The addition of Co and Al accelerated the pearlitic reaction and reduced the interlamellar spacing by increasing the free energy of phase transformation, thus a fully pearlitic structure was obtained at slow cooling rates.
ISSN:2075-4701
2075-4701
DOI:10.3390/met9010070