Melting and sintering characteristics of carbon-free mold fluxes

Abstract

This study systematically investigates the effects of basicity (CaO/SiO₂) and key constituents on the melting behaviour and sintering characteristics of carbon-free mold fluxes. As the CaO/SiO₂ ratio increases, both the melting temperature and time of mold fluxes increase, while the sintering rate and volumetric shrinkage decrease. With increasing Al₂O₃ content, the melting temperature and time first decrease and then increase with CaO/SiO₂ ratios below 1.0, and both parameters exhibit a continuous increase when the ratio is above 1.0. Moreover, the increase of Al₂O₃ content leads to a reduced sintering rate and volumetric shrinkage. Higher F⁻, TiO₂ and MnO contents result in reduced melting behaviour, along with increased sintering characteristics. With increasing MgO and BaO content, the melting temperature and time first decrease and then increase, whereas the sintering rate and volumetric shrinkage show an opposite trend. XRD analysis indicates that carbon-free mold fluxes with lower sintering rates exhibit more complex phase compositions. The optimal compositional range for carbon-free mold fluxes is determined to be having CaO/SiO₂ ratio of 1.0–1.1, Al₂O₃ content of 3–9 wt-%, F⁻ content of 3–6 wt-%, and TiO₂, MnO, MgO and BaO contents each at 6 wt-%, 6 wt-%, 3 wt-% and 3 wt-%, respectively.

Keywords

Carbon-free mold fluxes melting temperature melting time sintering rate volumetric shrinkage

Get full access to this article

View all access options for this article.

References

Xie

. Study on related basic theories of continuous casting mold fluxes and application in industry. Chongqing, China: Chongqing University, 2004.

Mills

Fox

, et al. Performance and properties of mould fluxes. Ironmak Steelmak 2005; 32: 26–34.

Mills

Hayashi

Wang

, et al. The structure and properties of silicate slags. Treatise Process Metall 2013; 1: 149–286.

Yan

Yang

, et al. Mechanism of controlling melting rate by carbon in mold powder for continuous casting. J Iron Steel Res 2011; 23: 28–31.

Kim

Lee

Effects of carbon particle size and content on the melting rate of mold powder. Proc 4th Eur Continuous Casting Conf 2002; 1: 371–377.

Long

Wang

Dou

. Investigation on carbonizing from mold flux into ultra-low-carbon steel during continuous casting. Metall Mater Trans B 2023; 54: 263–274.

Zeng

Chen

Zhao

, et al. Development and application of mould powder for continuous casting of ultra-low carbon steel at home and abroad. Iron Steel Vanad Titan 2000; 1: 40–44.

Wang

Jin

, et al. Analysis of continuous casting mold flux development situation for ultra low carbon steel combined with patent. Continuous Casting 2015; 40: 4.

Xixia Longcheng Metallurgical Materials Co. Ltd. A mold flux for continuous casting of ultra-low carbon steel. CN103817301A. 2014.

10.

Xie

Gan

. Amount and schedule of carbon addition in cc mold fluxes. J Iron Steel Res Int 1990; 2: 5–12.

11.

Terada

Kaneko

Ishikawa

, et al. Research of substitution for carbon: development of mold fluxes for ultra-low-carbon steel. Steelmaking Conf Proc 1991; 74: 635–638.

12.

You

Zhang

Liu

, et al. Effect of melting rate modifier on melting rate of mold powder for continuous casting. Refractories 2006; 40: 207–209, 220.

13.

Jiang

Ren

Liu

. Effects of BN on physical and chemical properties of the powder for IF steel. Continuous Cast 2006; 5: 40–42.

14.

Wan

. Weak electrolyte protective slag. CN201910961335.2. 2019.

15.

Yang

Zhu

. Evolution of compositions and properties of CaO–SiO₂ based mold flux for continuous casting high Mn steel. ISIJ Int 2016; 56: 2191–2198.

16.

Wen

Tang

. Viscosity and viscosity estimate model of fluoride-free and titanium-bearing mold fluxes. J Iron Steel Res Int 2010; 17: 6–10.

17.

Chen

Zhang

, et al. A critical review of the challenges of developing continuous casting mold fluxes for high-Ti steels. Int J Miner Metall Mater 2026; 33: 35–52.

18.

Shen

Liu

Chen

, et al. Unveiling the effect of MnO/SiO₂ ratios on the viscosity and structure of mold fluxes for high-Mn cryogenic steels. Ceram Int 2023; 49: 29308–29316.

19.

Chen

, et al. Properties and structure of a new non-reactive mold flux for high-al steel. J Iron Steel Res Int 2022; 29: 61–70.

20.

Piao

Zhu

Wang

, et al. Effects of BaO on the viscosity and structure of a new fluorine-free CaO-Al₂O₃-TiO₂-based mold flux for high titanium steel. Metall Mater Trans B 2020; 51: 2119–2130.

21.

Zhong

Wang

Zhou

, et al. Melting, viscosity and structure of lithium-free CaO-SiO₂ based melt: substituting Li₂O with Na₂O and B₂O₃. Ceram Int 2025; 51: 393–400.

22.

. Study on microstructure and macroproperty of mould fluxes with low-reactivity. Chongqing, China: Chongqing University, 2018.