Effects of basicity and CaF2 on the viscosity of CaF2–CaO–SiO2 slag for electroslag remelting process

Lao, Yigui; Gao, Yunming; Deng, Fangjie; Wang, Qiang; Li, Guangqiang

doi:10.1051/metal/2019066

Cited by 11 publications

(4 citation statements)

References 30 publications

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“…As shown in Figure b, it can be noticed that both increased Na 2 O content and increased temperature result in reduced viscosity. High temperature can weaken the bonds among particles and break the network structure in the slag . Because of its small size, Na + could loosen the network structure into a smaller one, and the charge of the [SiO 4 ] − groups could be fully balanced by Na + to form more stable structures .…”

Section: Resultsmentioning

confidence: 99%

“…High temperature can weaken the bonds among particles and break the network structure in the slag. 43 Because of its small size, Na + could loosen the network structure into a smaller one, and the charge of the [SiO 4 ] − groups could be fully balanced by Na + to form more stable structures. 44 The viscosity is 0.086 Pa s under the condition of 15 wt % Na 2 O and 1500 °C, indicating considerable fluidity.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Application of Pressure-less Sintering and Dynamic-Slag Treatment to Recover Diamond Wire Saw Silicon Powder

Chen

Wang

Huang

et al. 2020

ACS Sustainable Chem. Eng.

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Recycling silicon from environmentally hazardous diamond wire saw silicon powder waste (DWSSP) and effectively removing boron is still an elusive aim. Here, pressure-less sintering and dynamic-slag treatment were used to recover the powder waste. On the basis of thermodynamic simulation, the slag composition was designed. Dense structure of DWSSP ceramics could effectively reduce the oxidation loss. Dynamic-slag treatment can provide higher silicon recovery and better boron removal rate than can traditional one-step slag treatment. Slag-1 (Na 2 O-SiO 2 ) can remove boron while protecting molten silicon from oxidation. Interestingly, after Slag-2 (CaO−SiO 2 −Na 2 O) was added, relative displacement between the mixed slag and silicon can provide more favorable dynamic conditions. Using the dynamic-slag treatment, the boron removal efficiency reached 83.4%, and the silicon recovery rate reached 82.29%. Additionally, by introducing the solute penetration theory, the mechanism of boron removal during convective mass transfer process was discussed in detail. The simplicity of this combined approach provides a new possibility for recovery and purification of intractable fine powdery waste.

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Section: Resultsmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

Application of Pressure-less Sintering and Dynamic-Slag Treatment to Recover Diamond Wire Saw Silicon Powder

Chen

Wang

Huang

et al. 2020

ACS Sustainable Chem. Eng.

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show abstract

“…。しかしながら，実際のモールドフラックスは様々な成分を含む多成分系であり，最近では，三成分系以上の多成分系を対象とした測定が進められている [6][7][8] 。また，モールドフラックスには粘度や結晶化挙動の制御のため，多くの場合，酸化物成分(例：CaO，Na 2 O，K 2 O)だけでなく，フッ化物(例：CaF 2 ，NaF)も添加されることが多い [9][10][11][12][13][14] 。融体の粘度や構造に及ぼすフッ化物成分添加の影響解明は，高温冶金学の研究分野において工業的にも学術的にも重要な課題であり，多数の報告がなされている 15,16) 。融体中でのフッ化物イオンの役割を融体の陽イオン組成変化の影響から独立して理解するため，CaO と CaF 2 のモル比を変化させた際の粘度変化を議論している報告がいくつか存在する [17][18][19] 。最近では，モールドフラックスの粘度やレオロジー挙動を変化させる添加剤として窒化ケイ素(Si 3 N 4 ) が検討されており，窒化ケイ素を添加したオキシナイトライド融体の一部では非ニュートン流体としての挙動が報告されている [20][21][22] 。一方で，オキシナイトライド融体における非ニュートン性の発現機構は不明である。窒化ケイ素は，ガラス材料の特性改善のための添加剤としても用いられており 23) ，ガラス科学分野では陽イオンの組成比を一定とした際の陰イオン組成(酸化物イオンおよび窒化物イオンの構成比)がガラスの特性に及ぼす影響が調査されている 24) 。この組成設計のコンセプトは，酸化物イオン，フッ化物イオンおよび窒化物イオンのそれぞれが粘度に与える影響を明らかにするのに有用である。Hanfi ら 25 6. Parameters obtained by the Gaussian fit to the 29 Si MAS NMR spectra.…”

Section: 諸言unclassified

Viscosity of Na–Si–O–N–F Melts: Mixing Effect of Oxygen, Nitrogen and Fluorine

et al. 2022

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Fluorine and nitrogen are important elements of metallurgical slags and fluxes. Studies on their viscosity have often focused on the additive effect of fluoride and nitride compounds (e.g., CaF 2 and Si 3 N 4 ), whereas the influence of anionic composition (i.e., oxygen, fluorine and nitrogen concentrations) with a fixed cationic composition remains unclear. The present study reports the scarcely quantified viscosity variations due to changes in the anionic composition of a simple sodium silicate system by rotating crucible method under a controlled atmosphere. 29 Si magic-angle spinning nuclear magnetic resonance (MAS NMR) spectroscopy was used to characterize the structural changes against varying nitrogen and fluorine concentrations in the quenched glassy sample. The observed change in the local silicon structure was consistent with the expected variation from the conventional structural roles of nitrogen and fluorine in silicate glasses: nitrogen atoms tend to bond with silicon atoms, whereas fluorine atoms prefer to exist in surrounding sodium cations. Moreover, nitrogen tends to increase the viscosity, whereas fluorine strongly decreases the viscosity of the sodium silicate melts even with the enhancing effect of the latter on the polymerization of silicate anions. The viscosity of silicate melts has been commonly related to the overall polymerization degree of the liquid. However, the viscosity of fluorine-containing silicates cannot be explained by this conventional scenario. Fluorine ions tend to loosely bond with sodium cations. These sodium-fluorine complexes played a strong lubricant role in the network liquids.

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“…[9][10][11][12][13][14] The effect of the addition of fluoride, such as CaF 2 , on the viscosity and structure of melts has been a well-studied topic in the metallurgical research field due to its technical and scientific importance. 15,16) To understand the role of fluorine anions in the melts separately from the changes in cationic composition, few papers have discussed the variation in viscosity with the molar ratio of CaO to CaF 2 . [17][18][19] Recently, silicon nitride (Si 3 N 4 ) is also considered as an additive to the mold fluxes in order to vary the melt viscosity and their rheological behavior.…”

Section: Viscosity Of Na-si-o-n-f Melts: Mixing Effect Of Oxygen Nitmentioning

confidence: 99%

Viscosity of Na–Si–O–N–F Melts: Mixing Effect of Oxygen, Nitrogen, and Fluorine

et al. 2020

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Effects of basicity and CaF₂ on the viscosity of CaF₂–CaO–SiO₂ slag for electroslag remelting process

Cited by 11 publications

References 30 publications

Application of Pressure-less Sintering and Dynamic-Slag Treatment to Recover Diamond Wire Saw Silicon Powder

Application of Pressure-less Sintering and Dynamic-Slag Treatment to Recover Diamond Wire Saw Silicon Powder

Viscosity of Na–Si–O–N–F Melts: Mixing Effect of Oxygen, Nitrogen and Fluorine

Viscosity of Na–Si–O–N–F Melts: Mixing Effect of Oxygen, Nitrogen, and Fluorine

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