Intensification of Bubble Disintegration and Dispersion by Mechanical Stirring in Gas Injection Refining
スポンサーリンク
概要
- 論文の詳細を見る
Water model experiments were performed for establishing highly efficient gas injection refining processes. Mechanical stirring was applied to disintegrate the injected bubbles and to disperse them widely in the bath. The bubble disintegration and dispersion were investigated by changing rotation mode (direction of rotation), rotation speed, blade size of the impeller and gas flow rate. Forward rotation of the impeller induced a stable tangential flow and could not disperse bubbles in the bath due to formation of a vortex around the impeller shaft. The tangential flow could be suppressed by forward–interrupt rotation, which could reduce the vortex formation to some degree. However, forward–interrupt rotation could not disperse the bubbles widely in the bath. Forward–reverse rotation could prevent the vortex formation completely and create a strong shear stress field, which intensified the bubble disintegration and dispersion in the bath. Higher impeller rotation speed and larger blade length in forward–reverse rotation could enhance the bubble disintegration and make the dispersed bubbles smaller. The bubble dispersion zone became wider with larger blade length. The bubble size tended to be larger at higher gas flow rates. However, its dependence on the gas flow rate became smaller at higher impeller rotation speed.
- 社団法人 日本鉄鋼協会の論文
- 2009-01-15
著者
-
SANO Masamichi
Nagoya University
-
Wang Qiang
Northeastern Univ.
-
Wang Qiang
Northeastern University Shenyang
-
He Jicheng
Northeastern University Shenyang
-
Liu Yan
Northeastern University Shenyang
-
ZHANG TingAn
Northeastern University, Shenyang
-
Zhang Tingan
Northeastern University Shenyang
-
He JiCheng
Northeastern University
-
Zhang TingAn
Northeastern University
-
Liu Yan
Northeastern University
関連論文
- Erratum: Intensification of Bubble Disintegration and Dispersion by Mechanical Stirring in Gas Injection Refining[ISIJ. Int. 49(1): 17-23 (2009)]
- The Effect of Magnesium Gas Injecting Conditions on the Rate of Hot Metal Desulfurization
- Electromagnetic Field Distribution in Two-section Slitless Mold for Soft-contact Electromagnetic Continuous Casting
- Effects of Uniform and Gradient High Magnetic Fields on Gravity Segregation in Aluminum Alloys
- Influences of Flow Intensity, Cooling Rate and Nucleation Density at Ingot Surface on Deflective Growth of Dendrites for Al-based Alloy
- Prediction of Solidification Microstructure and Columnar-to-equiaxed Transition of Al-Si Alloy by Two-dimensional Cellular Automaton with "Decentred Square" Growth Algorithm
- Intensification of Bubble Disintegration and Dispersion by Mechanical Stirring in Gas Injection Refining
- In-Situ Fabrication of Bi/BiMn-BiMn-Mn Graded Materials by High Magnetic Field Gradients
- Solidified Structure Control of Metallic Materials by Static High Magnetic Fields
- Prediction of Solidification Paths for Fe-C-Cr Alloys by a Multiphase Segregation Model Coupled to Thermodynamic Equilibrium Calculations
- Restrictions of Physical Properties on Solidification Microstructures of Al-based Binary Alloys by Cellular Automaton
- Analysis of an Automatic Steel-teeming Method Using Electromagnetic Induction Heating in Slide Gate System
- Microstructure of Martensite/Bainite Dual-phase Grey Cast Iron and Its Strengthening Mechanism
- Effect of Heat Treatment on Microstructure and Mechanical Properties of Ti-alloyed Hypereutectic High Chromium Cast Iron
- Effect of Cooling Rate and Ti Addition on the Microstructure and Mechanical Properties in As-cast Condition of Hypereutectic High Chromium Cast Irons
- Prediction of Carbide Precipitation Using Partial Equilibrium Approximation in Fe–C–V–W–Cr–Mo High Speed Steels
- Effect of Heat Treatment on Microstructure and Mechanical Properties of Ti-alloyed Hypereutectic High Chromium Cast Iron