Alexander Straub, Sebastian Boblest, G. Karch, F. Sadlo, T. Ertl
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Droplet-Local Line Integration for Multiphase Flow
Line integration of stream-, streak-, and pathlines is widely used and popular for visualizing single-phase flow. In multiphase flow, i.e., where the fluid consists, e.g., of a liquid and a gaseous phase, these techniques could also provide valuable insights into the internal flow of droplets and ligaments and thus into their dynamics. However, since such structures tend to act as entities, high translational and rotational velocities often obfuscate their detail. As a remedy, we present a method for deriving a droplet-local velocity field, using a decomposition of the original velocity field removing translational and rotational velocity parts, and adapt path- and streaklines. Ge-nerally, the resulting integral lines are thus shorter and less tangled, which simplifies their analysis. We demonstrate and discuss the uti-lity of our approach on droplets in two-phase flow data and visualize the removed velocity parts employing glyphs for context.
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