Evolution of non-metallic inclusions during heat treatment

Self Cite

Understanding the thermodynamics and kinetics of solid‐state reactions on the characteristic transformations of nonmetallic inclusions in the linepipe steel during isothermal heating is of great importance for achieving good steel quality. Herein, heat treatment experiments are used, which are carried out at 1473 K (1200 °C) between 1 and 10 h in an Ar atmosphere, to investigate the resulting changes in the inclusion characteristics of linepipe steel. The chemical compositions, morphology, and size distribution of the inclusions are characterized. Results indicate that Mn and S in the linepipe steel react with CaS inclusions/phases to form (Ca, Mn)S inclusions/phases during heating at 1473 K (1200 °C), while MnS inclusions are gradually decomposed. Based on the FactSage Macro process, a kinetic model is established to calculate the regional equilibrium at the interface between the inclusion and steel at every time step and predict the extent of the inclusion transformation during isothermal heating. The experimental measurements and predicted results are in reasonable agreement. The diffusion‐limited kinetic model verifies that the effects of heating time and inclusion size on inclusion transformation are as predicted for Mn and S diffusion control by observation.

“…Integrated with the apparent area, the average chemical composition of the inclusions with different sizes could be calculated by Equation (5). [ 28 ]

j_{avg} = \frac{\sum_{k = 1}^{n} j_{k} \times {Area}_{k}}{\sum_{k = 1}^{n} {Area}_{k}}

where n represents the inclusion number in a specified size range;

{Area}_{k}

and

j_{k}

are the exposed apparent area and the chemical composition of a single inclusion ( k ), respectively; and

j_{avg}

represents the average chemical composition of the inclusions in the specified size range. As shown in Figure 3, the apparent radii of the inclusions mainly ranged from 0 to 5 μm.…”

Section: Resultsmentioning

confidence: 99%

“…Integrated with the apparent area, the average chemical composition of the inclusions with different sizes could be calculated by Equation ( 5). [28] j avg ¼…”

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Thermodynamic and Kinetic Analyses of Inclusion Transformations in Linepipe Steel during Isothermal Heating at 1473 K (1200 °C)

Liu

Webler

2022

Self Cite

“…This trend is quite similar to that in the present study. In contrast, Liu et al [ 35 ] found that the inclusions of MgO–Al 2 O 3 –CaO–CaS system would change into MgO–Al 2 O 3 –(Ca, Mn)S inclusions during heat treatment. The CaO in the inclusions would react with the S and Al in steel to generate CaS and Al 2 O 3 .…”

Section: Discussionmentioning

confidence: 96%

“…Similar experiments were also carried out by Ren et al, [ 32–34 ] and they proposed that the evolution of MnO–SiO 2 system inclusions was closely related to heating temperature, inclusion size, and holding time as well as the contents of Cr and Si in steel. Liu et al [ 35 ] observed the inclusions in calcium‐treated Al‐killed steel after heat treatment and found that the inclusions of CaS and MgO–Al 2 O 3 –CaO–CaS in steel would transform into (Ca, Mn)S and MgO–Al 2 O 3 –(Ca, Mn)S inclusions, respectively. In addition, the average size of inclusions increased as well.…”

Section: Introductionmentioning

confidence: 99%

Evolution of Nonmetallic Inclusions in Ti‐Bearing Al‐Killed Steel during Heat Treatment at 1200 °C

Yang

Deng

Zhu

2023

To understand the evolution behaviors of the inclusions in Ti‐bearing Al‐killed steel, steel samples taken from a 20CrMnTi casting billet are heated at 1200 °C for different times, and the changes in composition, size, and numbers of the inclusions are investigated. Some modeling experiments are also designed to reveal the interaction between solid steel and inclusions using premelted slags. It is found that oxysulfide, sulfide, and nitride inclusions are detected in the casting billet before heating. During heating, small changes are observed in the types of inclusions, while the size of these inclusions increases with time. The Mn and S in steel transfer to the sulfide phase of these inclusions and further generate a (Ca, Mn)S solution. The Ti in steel replaces some of the Al element in the oxide part of the inclusions, resulting in the increase of TiOx content and the drop of Al2O3 content in the inclusions. When the TiOx content is sufficient, a thin layer of TiN is predicated at the edges of the oxide part. The reaction between the TiOx in inclusions and the N in steel plays a role in this evolution.

Inclusions Evolution of Ca‐Treated Steel During High‐Heat Input Welding

Qi,

Pang,

et al. 2024

This article has investigated a 60 mm Ca‐treated Q550 steel used for high‐heat input welding. The results have shown that the Ca‐type inclusions account for 70% of the inclusions in the steel which are mainly CaAlMg type, Ca–Al type, and a small amount of CaS type while the non‐Ca‐type inclusions are mainly FeCO. After undergoing the welding thermal cycle, the number of Ca‐containing inclusions above 2 μm in size is decreased while the number of non‐Ca‐containing inclusions below 1 μm (mainly FeO) is increased significantly. However, the total area of inclusions is decreased. It has been found out that the CaAlSO‐type inclusions undergo “diffusion” of O element to the surroundings during the thermal cycle, forming a ring‐shaped oxygen‐rich zone and carbon‐rich zone which promotes the nucleation of acicular ferrite. In contrast, the CaAlMgSO‐type inclusions undergo “decomposition” during the thermal cycle which forms a group of inclusions with different sizes and types, promoting nucleation of multioriented acicular ferrite.