Immersed boundary method for unsteady kinetic model equations |
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| Authors: | Cem Pekardan Sruti Chigullapalli Lin Sun Alina Alexeenko |
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| Affiliation: | 1. School of Aeronautics and Astronautics, Purdue University, West Lafayette, USA;2. NNSA PRISM: Center for Prediction of Reliability, Integrity and Survivability of Microsystems, Rosen Center for Advanced Computing, West Lafayette, USA |
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| Abstract: | Predicting unsteady flows and aerodynamic forces for large displacement motion of microstructures requires transient solution of Boltzmann equation with moving boundaries. For the inclusion of moving complex boundaries for these problems, three immersed boundary method flux formulations (interpolation, relaxation, and interrelaxation) are presented. These formulations are implemented in a 2‐D finite volume method solver for ellipsoidal‐statistical (ES)‐Bhatnagar‐Gross‐Krook (BGK) equations using unstructured meshes. For the verification, a transient analytical solution for free molecular 1‐D flow is derived, and results are compared with the immersed boundary (IB)‐ES‐BGK methods. In 2‐D, methods are verified with the conformal, non‐moving finite volume method, and it is shown that the interrelaxation flux formulation gives an error less than the interpolation and relaxation methods for a given mesh size. Furthermore, formulations applied to a thermally induced flow for a heated beam near a cold substrate show that interrelaxation formulation gives more accurate solution in terms of heat flux. As a 2‐D unsteady application, IB/ES‐BGK methods are used to determine flow properties and damping forces for impulsive motion of microbeam due to high inertial forces. IB/ES‐BGK methods are compared with Navier–Stokes solution at low Knudsen numbers, and it is shown that velocity slip in the transitional rarefied regime reduces the unsteady damping force. Copyright © 2015 John Wiley & Sons, Ltd. |
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| Keywords: | immersed boundary method Boltzmann kinetic model equation microflows gas damping rarefied gas dynamics |
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