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Effect of orifice configuration on the volumetric mass transfer coefficient during ladle purging

Published online by Cambridge University Press:  02 February 2012

Fang Jiang ,
Yun-Xia Song  and
Guo-Guang Cheng
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Abstract

Physical model experiments were performed to clarify the influence of orifice configuration on the volumetric mass transfer coefficient during ladle purging. Bubble behavior was recorded by a high speed video camera in the present study. And carbon dioxide desorption from an aqueous NaOH solution was used to measure the volumetric mass transfer coefficient. It is found that bubbles for multi-hole orifice are generally smaller than those for 1-hole orifice. However, when the hole distance in the multi-hole orifice is too short to avoid bubble coalescence, large bubbles will be formed. It is shown that there is a decreasing tendency of the volumetric mass transfer coefficient when the hole diameter increases. The volumetric mass transfer coefficient firstly increases with increasing the hole distance and hole number. Thereafter, it remains approximately constant with further increase in the hole distance and hole number.

Keywords

Ladle purgingorifice configurationbubble behaviorvolumetric mass transfer coefficientVidange de pocheconfiguration du système de vidangecomportement des bullescoefficient de transfert de masse
Type
Research Article
Information
Metallurgical Research & Technology , Volume 108 , Issue 7-8 , 2011 , pp. 465 - 472
Copyright
© EDP Sciences 2012

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References

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