Cold Crucible Induction Melting for the Fabrication of Fe–<i>x</i>TiC In Situ Metal Matrix Composites: Alloying Efficiency and Microstructural Analysis

Perminov, Anton; Günther, Peer Eric; Ilatovskaia, Mariia O.; Wei, Xingwen; Volkova, Olena

doi:10.1002/adem.202300627

Cited by 3 publications

(1 citation statement)

References 24 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Observa-se a fase FCC-A1-AUTO#2, apresentando em torno de 20% em fração molar próxima a temperatura de fusão do substrato (1423 K). Segundo a designação de Strukturbericht, tal fase apresenta uma estrutura do tipo Cúbica de Face Centrada (CFC) e pertencente ao grupo espacial Fm 3 m [106]. Essas características correspondem aos carbonetos do tipo MC (M = metal de transição) como o carboneto de titânio.…”

Section: Sistema 058fe-024c-009si-009tiunclassified

Produção e caracterização de camadas MMC resistentes ao desgaste em ferros fundidos nodulares pela técnica >i<TIG surface alloying>/i< in-situ

Triani

View full text Add to dashboard Cite

show abstract

Section: Sistema 058fe-024c-009si-009tiunclassified

Produção e caracterização de camadas MMC resistentes ao desgaste em ferros fundidos nodulares pela técnica >i<TIG surface alloying>/i< in-situ

Triani

View full text Add to dashboard Cite

show abstract

Remelting of In Situ Fe‐xTiC Metal Matrix Composites by the Sessile Drop Method: Characteristic Temperatures and Microstructural Analysis

Perminov,

Ilatovskaia,

Wei

et al. 2024

steel research int.

View full text Add to dashboard Cite

The remelting of Fe‐xTiC metal matrix composites (MMCs) is studied using the sessile drop method. This is to determine the conditions needed for the complete dissolution of TiC precipitates in the Fe‐based melt. Samples with different amounts of TiC (2, 3.5, and 5 wt%) are analyzed in a hot‐stage microscope (HSM), capturing the softening and melting temperatures. A Cr‐alloyed steel is selected as a matrix. Consequently, the presence of TiC elevates the melting initiation temperature above the melting point of pure iron (e.g., 1659 ± 10 °C for Fe‐5TiC). Furthermore, samples with higher TiC amounts exhibit higher melting initiation temperatures. This trend is confirmed by differential scanning calorimetry measurements, conducted on the representative Fe‐xTiC samples. Microstructural examinations of the solidified (HSM) samples identify two distinct TiC precipitate morphologies: primary blocky/cubic and secondary eutectic plate like. For instance, the Fe‐5TiC sample contains numerous blocky/cubic precipitates (7.5 ± 3.1 μm) clustered at the upper cross‐ section, while secondary plate‐like precipitates (20.4 ± 11.8 μm) are uniformly distributed in eutectic assemblies with the matrix. This study provides meaningful insights for optimizing the production of as‐cast and as‐atomized Fe‐TiC MMCs, particularly in selecting reinforcement levels and homogenization temperatures for complete TiC dissolution.

show abstract

Thermodynamic Investigation on K2TiF6 and C Powder to Prepared in-situ TiCp in Molten Al-Si-Fe Alloy

Tang,

Xiao,

Gao

et al. 2024

Silicon

View full text Add to dashboard Cite

Cold Crucible Induction Melting for the Fabrication of Fe–xTiC In Situ Metal Matrix Composites: Alloying Efficiency and Microstructural Analysis

Cited by 3 publications

References 24 publications

Produção e caracterização de camadas MMC resistentes ao desgaste em ferros fundidos nodulares pela técnica >i<TIG surface alloying>/i< in-situ

Produção e caracterização de camadas MMC resistentes ao desgaste em ferros fundidos nodulares pela técnica >i<TIG surface alloying>/i< in-situ

Remelting of In Situ Fe‐xTiC Metal Matrix Composites by the Sessile Drop Method: Characteristic Temperatures and Microstructural Analysis

Thermodynamic Investigation on K2TiF6 and C Powder to Prepared in-situ TiCp in Molten Al-Si-Fe Alloy

Contact Info

Product

Resources

About