The Four Stage Development of Starting Turbulent Buoyant Plumes

T. Tran, Kiran Bhaganagar
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Abstract

Turbulent heated and buoyant plumes have important applications in the atmosphere such as wildland fire plumes, volcanic plumes, and chemical plumes. The purpose of the study is to analyze the turbulence structures, and to understand the stages of the development of the starting turbulent plumes. For this purpose, data generated from an in-house Weather Research Forecast model coupled with Large-eddy simulation (WRF-bLES) with two-way feedback between the buoyant plume and the atmosphere developed has been used. The release of both dense gases (Co2, So2) and, buoyant gases (He, NH3, heated air) from a circular source at the bottom of the domain have been investigated. The simulations of the axisymmetric plume were performed at a high Reynolds number of 108. Vortex Identification methods were used to extract the Coherent structures and the large-scale features of the flow. The results have demonstrated that both the dense and the buoyant heated plumes with different initial characters exhibited universal characteristics and the development of the starting plumes occurred in four characteristic stages: Stage 1 is the plume acceleration stage, followed by stage 2 which corresponds to the formation of the head of the plume which grows spatially. Stage 3 is when the plume head is fully formed and the flow transitions to quasi-steady-state behavior. The final stage is the fully developed plume. The identification of the four-stage development of the plume in the neutral environment is the first step in studying the turbulent heated and buoyant plumes development in order to characterize realistic plumes and to quantify the extent of mixing at each of these stages. This work has important contributions to fundamental fluid dynamics of buoyant plumes with implications on forecasting the plume trajectory of smoke, wildland fire, and volcanic plumes.
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启动湍流浮力羽流的四阶段发展
湍流加热和浮力羽流在大气中有重要的应用,如野火羽流、火山羽流和化学羽流。研究的目的是分析湍流结构,了解起始湍流羽流的发展阶段。为此,使用了内部天气研究预报模型和大涡模拟(WRF-bLES)产生的数据,该模型在浮力羽流和大气之间形成双向反馈。从区域底部的循环源释放的致密气体(Co2, So2)和浮力气体(He, NH3,加热空气)已经被研究过。在高雷诺数为108的条件下对轴对称羽流进行了模拟。利用涡旋识别方法提取流场的相干结构和大尺度特征。结果表明,不同初始特征的致密型和浮力型加热羽流具有普遍的特征,初始羽流的发展经历了4个特征阶段:第1阶段为羽流加速阶段,第2阶段对应于羽流头部的形成和空间增长阶段。阶段3是羽头完全形成,流动过渡到准稳态行为。最后一个阶段是羽流完全发育。中性环境中羽流发展的四个阶段的识别是研究湍流加热和浮力羽流发展的第一步,目的是表征真实羽流的特征,并量化每个阶段的混合程度。这项工作对浮力羽流的基本流体动力学有重要贡献,对预测烟雾、野火和火山羽流的羽流轨迹具有重要意义。
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