旋转搅拌流中液滴夹带及膜破碎特性的实验研究

Ruiqi Kang, Z. Xiong, Zhuguo Li, Shuo Ouyang, J. Liu
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引用次数: 0

摘要

旋叶分离器的分离性能,包括压降和分离效率,与两相流型和液膜破碎行为密切相关。在旋流叶片分离机中,液滴发生碰撞,膜破碎。受螺旋叶片结构和中心轮毂的影响,螺旋叶片出口区域容易形成搅拌流。由于搅拌流液膜厚度复杂多变,在正常工况下,从侧面或顶部直观观察夹带液滴的产生和发展过程是极其困难的。关于旋转流场下液滴夹带现象的数据很少,导致旋转流场下液滴的夹带机理不清楚。本文研究了小液体流量下旋流叶片下游液滴的夹带情况。研制了旋转流场可视化实验装置。搅拌流是在接近零液流的条件下形成的。通过观察少量液滴在旋转流场中的运动,提取出搅拌流中液滴的运动特征。通过视觉摄影获得了旋转搅拌流和液滴夹带过程。得到了旋转流场作用下的液膜韧带和滤袋破碎特性,以及夹带液滴的粒径特性。
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Experimental Study on Droplets Entrainment and Film Breakup Characteristics Under in Rotating Churn Flow
The separation performance of swirl-vane separators, including pressure drop and separation efficiency, is closely related to the two-phase flow pattern and the liquid film breakup behavior. In the swirling-swirl-vane separators, the droplets collision and film breakup happen. Influenced by the spiral blade structure and the central hub, the swirl-vane outlet region is prone to the formation of churn flow. Due to the complex and variant thickness of the liquid film in churn flow, it is extremely difficult to visually observe the generation and development process of the droplet entrainment from the side or the top under normal working conditions. Data on the phenomenon of droplet entrainment under the rotating flow field are rare, resulting in the entrainment mechanism of droplets under the rotating flow field is unclear. In this paper, investigations on the entrainment of droplets downstream of the swirl-vane has been carried out for a small liquid flow rate. A rotary flow field visualization experimental device has been developed. The churn flow is formed under the condition of near-zero liquid flow. The motion characteristics of the droplets in the churn flow are extracted by observing the movement of a small number of droplets in a rotating flow field. The rotational churn flow and droplet entrainment process are obtained through visual photography. The liquid film ligament and bag breakup characteristics under the rotating flow field are obtained, as well as the particle size characteristics of the entrainment droplets.
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