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http://dx.doi.org/10.15701/kcgs.2020.26.5.1

Stable Anisotropic Freezing Modeling Technique Using the Interaction between IISPH Fluids and Ice Particles  

Kim, Jong-Hyun (Kangnam University)
Abstract
In this paper, we propose a new method to stable simulation the directional ice shape by coupling of freezing solver and viscous water flow. The proposed ice modeling framework considers viscous fluid flow in the direction of ice growth, which is important in freezing simulation. The water simulation solution uses the method of applying a new viscous technique to the IISPH(Implicit incompressible SPH) simulation, and the ice direction and the glaze effect use the proposed anisotropic freezing solution. The condition in which water particles change state to ice particles is calculated as a function of humidity and new energy with water flow. Humidity approximates a virtual water film on the surface of the object, and fluid flow is incorporated into our anisotropic freezing solution to guide the growth direction of ice. As a result, the results of the glaze and directional freezing simulations are shown stably according to the flow direction of viscous water.
Keywords
Freeze simulation; Icicle shape; Implicit incompressible SPH; Glaze of ice; Anisotropic growth direction of ice;
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