Geometry-Aware Volume-of-Fluid Method
We present a new framework to simulate moving interfaces in viscous incompressible two phase flows. The goal is to achieve both conservation of the fluid volume and a detailed reconstruction of the fluid surface. To these ends, we incorporate sub‐grid refinement of the level set with the volume‐of‐f...
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| Vydáno v: | Computer graphics forum Ročník 32; číslo 2pt3; s. 379 - 388 |
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| Médium: | Journal Article |
| Jazyk: | angličtina |
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Oxford, UK
Blackwell Publishing Ltd
01.05.2013
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| ISSN: | 0167-7055, 1467-8659 |
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| Abstract | We present a new framework to simulate moving interfaces in viscous incompressible two phase flows. The goal is to achieve both conservation of the fluid volume and a detailed reconstruction of the fluid surface. To these ends, we incorporate sub‐grid refinement of the level set with the volume‐of‐fluid method. In the context of this refined level set grid we propose the algorithms needed for the coupling of the level set and the volume‐of‐fluid, which include techniques for computing volume, redistancing the level set, and handling surface tension. We report the experimental results produced with the proposed method via simulations of the two phase fluid phenomena such as air‐cushioning and deforming large bubbles. |
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| AbstractList | We present a new framework to simulate moving interfaces in viscous incompressible two phase flows. The goal is to achieve both conservation of the fluid volume and a detailed reconstruction of the fluid surface. To these ends, we incorporate sub‐grid refinement of the level set with the volume‐of‐fluid method. In the context of this refined level set grid we propose the algorithms needed for the coupling of the level set and the volume‐of‐fluid, which include techniques for computing volume, redistancing the level set, and handling surface tension. We report the experimental results produced with the proposed method via simulations of the two phase fluid phenomena such as air‐cushioning and deforming large bubbles. We present a new framework to simulate moving interfaces in viscous incompressible two phase flows. The goal is to achieve both conservation of the fluid volume and a detailed reconstruction of the fluid surface. To these ends, we incorporate sub-grid refinement of the level set with the volume-of-fluid method. In the context of this refined level set grid we propose the algorithms needed for the coupling of the level set and the volume-of-fluid, which include techniques for computing volume, redistancing the level set, and handling surface tension. We report the experimental results produced with the proposed method via simulations of the two phase fluid phenomena such as air-cushioning and deforming large bubbles. [PUBLICATION ABSTRACT] |
| Author | Cho, Junghyun Ko, Hyeong-Seok |
| Author_xml | – sequence: 1 givenname: Junghyun surname: Cho fullname: Cho, Junghyun organization: Seoul National University, Korea – sequence: 2 givenname: Hyeong-Seok surname: Ko fullname: Ko, Hyeong-Seok organization: Seoul National University, Korea |
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| References_xml | – reference: Monaghan J. J.: Smoothed particle hydrodynamics. Ann. Rev. Astron. Astrophys. 30 (1992), 543-74. 2. – reference: Stam J.: Stable fluids. Computer Graphics (Proc. ACM SIGGRAPH '99) 33, Annual Conference Series (1999), 121-128. 2. – reference: Brochu T., Batty C., Bridson R.: Matching fluid simulation elements to surface geometry and topology. ACM Trans. Graph. 29 (July 2010), 47:1-47:9. 3. – reference: Kim D., Song O.-y., Ko H.-S.: Stretching and wiggling liquids. ACM Trans. Graph. 28, 5 (2009), 1-7. 2. – reference: Brackbill J. U., Kothe D. B., Zemach C.: A continuum method for modeling surface tension. J. Comp. Phys. 100 (1992), 335-354. 6. – reference: Sussman M.: A method for overcoming the surface tension time step constraint in multiphase flows ii. Int. J. Numer. Meth. Fluids 68 (2011), 1343-1361. 8. – reference: Mullen P., McKenzie A., Tong Y., Desbrun M.: A variational approach to Eulerian geometry processing. ACM Trans. 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| Title | Geometry-Aware Volume-of-Fluid Method |
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