A novel experimental set-up for generating microbubbles for the removal of inclusions from water and liquid metals

CIM Journal Pub Date : 2023-10-12 DOI:10.1080/19236026.2023.2255094

R. Tiwari, D. Gonzalez-Morales, M. M. Isac, R. I. L. Guthrie

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Abstract

To enhance steel cleanliness, extensive research has been conducted on bubble flotation techniques for inclusion removal. However, effective removal of nonmetallic inclusions smaller than 50 μm remains a challenge during standard liquid metal processing operations. These tiny inclusions have insufficient rising speeds to enable them to float out to the slag layer on their own. Several studies have demonstrated that the use of 500-μm bubbles would be necessary to facilitate the flotation of sub-50-μm inclusion particles from liquid steel within a tundish. Our approach to generating microbubbles in liquid metals uses liquid shearing flows. This method splits forming bubbles into smaller sizes by applying intense shear stresses. As a result, significantly larger surface areas are created, enhancing the interaction between the microbubbles and the inclusions. To test the effectiveness of this approach, a novel setup comprising submerged nozzles within a liquid metal was designed, manufactured, and operated. This setup allowed for experimentation with different rotational speeds and effluent gas flow rates, thereby determining the bubble sizes produced. Microbubbles within the desired size range (400–600 µm) were successfully generated in a Cerrolow 136 eutectic alloy.

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一种新的实验装置，用于产生微气泡，以去除水和液态金属中的夹杂物

为了提高钢的清洁度，人们对气泡浮选去除夹杂物技术进行了广泛的研究。然而，在标准的液态金属加工操作中，有效去除小于50 μm的非金属夹杂物仍然是一个挑战。这些微小的夹杂物没有足够的上升速度使它们能够自己浮到渣层上。一些研究表明，使用500 μm的气泡对于促进中间包内钢液中低于50 μm的夹杂颗粒的浮选是必要的。我们在液态金属中产生微气泡的方法是使用液态剪切流。这种方法通过施加强烈的剪切应力将形成的气泡分裂成更小的尺寸。结果，产生了更大的表面积，增强了微泡和夹杂物之间的相互作用。为了测试这种方法的有效性，研究人员设计、制造并运行了一种新型装置，该装置由液态金属中的浸入式喷嘴组成。该装置允许以不同的转速和流出气体流速进行实验，从而确定产生的气泡大小。在Cerrolow 136共晶合金中成功地产生了所需尺寸范围(400-600µm)的微泡。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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CIM Journal

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