Influence of Phosphorus on Solidification Structure in Continuously Cast 0.1 mass% Carbon Steel.

Yoshida, Naotsugu; Umezawa, Osamu; Nagai, Kotobu

doi:10.2355/isijinternational.43.348

Cited by 59 publications

(65 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Figure 12 shows the prediction of the growth rate of the interface between the austenite and ferrite in holding at given temperatures for the 0.4 and 0.8 % Mn compositions. 16) The present prediction says that although the difference is not large, a lower growth rate is expected for the 0.8 % Mn than for the 0.4 % Mn. When we assume that the transformation starts after the compression below 1 093 K and finishes above 973 K, the ferrite size may reach a value between 2 and 5 mm in 3 s. The lower the transformation temperature range, the more the growth.…”

Section: Influence Of Mn Segregation On Nucleation Andmentioning

confidence: 80%

“…A continuous cast slab made in a laboratory-scale was prepared for the present study. The details of the casting are reported in the literature by Yoshida et al 16) and also mentioned in Table 3 with other preparations for GRP samples. The average spacing of the primary dendrite arms was 318 mm and the average spacing of the secondary dendrite arms was 137 mm.…”

Section: Sample Preparationmentioning

confidence: 99%

“…The average spacing of the primary dendrite arms was 318 mm and the average spacing of the secondary dendrite arms was 137 mm. 16) Using this slab, each specimen with or without the elimination of micro-segregation was prepared. The former was cut directly from a quarter thickness of the slab for the Type 3 microstructure, and the latter was rolled to a plate by 70 % in nominal reduction ratio and reheated for 86.4 ks at 1 623 K to eliminate the Mn micro-segregation for the Type ISIJ International, Vol.…”

Section: Sample Preparationmentioning

confidence: 99%

See 2 more Smart Citations

Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs

2003

Self Cite

View full text Add to dashboard Cite

Using a 100 mm thick continuously cast slab with a chemical composition of 0.10C-0.16Si-0.58Mn-0.01P-0.003S (mass%), we have clarified the effect of the manganese segregation on the transformed ferrite structure when the slab was reheated to make austenite grains equi-axed and smaller and followed by the Grain Refinement Process (GRP) of heavy compression and subsequent controlled cooling. Samples from which the Mn segregation was eliminated were also prepared for comparison. The resultant microstructure was examined for compressive strains between 0.7 and 2.1.When the austenite grain size is 160 or 120 mm prior to GRP, the ferrite grain size of the samples with the Mn segregation is smaller at the given strain than that of the samples from which the Mn segregation was eliminated. The Mn band formed by the heavy compression is thought to act as a barrier in the form of a relatively stable austenite against the ferrite growth.Moreover, we found a unique equation to predict the transformed ferrite grain size in the samples with the Mn segregation. Namely, the ferrite grain size can be accounted for according to a parameter, ES (effective spacing): a mean spacing that considers both the pancake austenite grain boundary and the Mn band. We also suggest that the smaller Mn band spacing may make the ferrite structure finer even when the austenite grain size is large.KEY WORDS: cast slab; low carbon steel; heavy deformation; TMCP; HDR; HCR; phase transformation; grain boundary; ferrite grain; austenite grain; grain size; Mn segregation. Type 2 is the homogenized form of Type 1 without forging. The micro-segregation disappears by heating for several hours at an elevated temperature. The austenite grain size is large. This type is not always utilized practically but is important from a scientific viewpoint.For Types 1 and 2 microstructures, the recrystallization process has been developed and essentially combined with GRP to obtain fine austenite grains. The addition of Nb and Ti has been adopted for this purpose especially for Type 1. [7][8][9][10][11] Type 3 is the reheated form of Type 1 that is cooled once in the fully ferritic temperature regime. The micro-segregation remains but the austenite structure becomes equi-axed and smaller. The austenite grain size is between 20 and 300 mm.Type 4 is somehow classical. First the solidified structure is destroyed by some deformation at an elevated temperature, then it is homogenized and normalized. Figure 2 illustrates the difference between Types 3 and 4 microstructures prior to GRP. Micro-segregation does not exist, and the austenite grain size is mostly as small as that of Type 3. Torizuka et al. reported that the size of ferrite grains transformed from the heavily deformed austenite depends on the thickness of the compressed austenite grain for a Si-Mn steel with a Type 4 microstructure. 12,13) For Types 3 and 4 microstructures, a fine austenite grain size can be easily obtained by austenitizing or reheating the steel for a relatively short period in a lower austenitic ...

show abstract

Section: Influence Of Mn Segregation On Nucleation Andmentioning

confidence: 80%

Section: Sample Preparationmentioning

confidence: 99%

Section: Sample Preparationmentioning

confidence: 99%

See 1 more Smart Citation

Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs

2003

Self Cite

View full text Add to dashboard Cite

show abstract

“…15,16) Moreover, it was reported that P addition led to the refinement of as-cast g grain structure in 0.1 mass% C steel. [8][9][10] It was discussed that the increase in P concentration significantly lowers T g and P segregation developed during casting process provides the pinning effect. In our previous study, we investigated the effects of Al addition on the as-cast g grain structure in 0.2 mass% C steel.…”

Section: Introductionmentioning

confidence: 99%

“…[8][9][10][11][12][13][14] The addition of d-ferrite stabilizing elements such as Nb, V and Mo extends the dϩg region in the phase diagram toward lower temperatures, which leads to refinement of as-cast g grain structure due to pinning effect of the d phase on the g grains. 15,16) Moreover, it was reported that P addition led to the refinement of as-cast g grain structure in 0.1 mass% C steel.…”

Section: Introductionmentioning

confidence: 99%

Effects of Al and P Additions on As-cast Austenite Grain Structure in 0.2 mass% Carbon Steel

et al. 2010

View full text Add to dashboard Cite

show abstract

Precipitation of Copper Sulfide and its effect on the Microstructure and Properties of Steel

Liu¹,

Kuwabara²,

Li³

et al. 2011

steel research int.

View full text Add to dashboard Cite

The precipitation behavior of copper sulfides in strip cast and isothermal heat treated low carbon steel were investigated by SEM and TEM. The copper sulfides were classified as duplex inclusion of oxide and sulfide (OS), plate-like copper sulfide (PS), shell-like copper sulfide (SS), and nano-scale copper sulfide (NS). Based on the experimental results, the formation mechanisms of these copper sulfides, as well as the effects of cooling rate and constituentes of steel on the competitive precipitation between copper sulfide and manganese sulfide were discussed. The effects of coppers sulfides on the mechanical properties as well as the formation of acicular ferrite in steel were also introduced.

show abstract

Influence of Phosphorus on Solidification Structure in Continuously Cast 0.1 mass% Carbon Steel.

Cited by 59 publications

References 22 publications

Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs

Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs

Effects of Al and P Additions on As-cast Austenite Grain Structure in 0.2 mass% Carbon Steel

Precipitation of Copper Sulfide and its effect on the Microstructure and Properties of Steel

Contact Info

Product

Resources

About