Proceedings Article10.2514/6.2008-927
A Multi-Code Python-Based Infrastructure for Overset CFD with Adaptive Cartesian Grids
Andrew M. Wissink,Jayanarayanan Sitaraman,Venkateswaran Sankaran,Dimitri J. Mavriplis,Thomas H. Pulliam +4 more
- 07 Jan 2008
94
TL;DR: A computational infrastructure that supports Chimera-based interfacing of different CFD solvers a body-fitted unstructured grid solvers with a blockstructured adaptive cartesian grid solver to perform time-dependent adaptive movingbody CFD calculations of external aerodynamics is described.
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Abstract: This paper describes a computational infrastructure that supports Chimera-based interfacing of different CFD solvers a body-fitted unstructured grid solver with a blockstructured adaptive cartesian grid solver to perform time-dependent adaptive movingbody CFD calculations of external aerodynamics. The goal of this infrastructure is to facilitate the use of different solvers in different parts of the computational domain body fitted unstructured to capture viscous near-wall effects, and cartesian adaptive mesh refinement to capture effects away from the wall. The computational infrastructure, written using Python, orchestrates execution of the different solvers and coordinates data exchanges between them, controlling the overall time integration scheme. Details about the infrastructure used to integrate the codes, the parallel implementation, and results from demonstration calculations are presented.
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Citations
CFD Vision 2030 Study: A Path to Revolutionary Computational Aerosciences
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Overset grid technology development at NASA Ames Research Center
TL;DR: This article traces the development of overset grid technologies at NASA Ames Research Center, including: data format and visualization software; and algorithms and software tools for surface grid generation, volume grid Generation, domain connectivity, forces and moments calculation, and flow solution computation.
114
Application of the Helios Computational Platform to Rotorcraft Flowfields
Jayanarayanan Sitaraman,Andrew M. Wissink,Venketeswaran Sankaran,Buvana Jayaraman,Anubhav Datta,Zhi Yang,Dimitri J. Mavriplis,Hossein Saberi,Mark Potsdam,David O'Brien,Rui Cheng,Nathan S. Hariharan,Roger C. Strawn +12 more
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TL;DR: The first version of the Helios platform as mentioned in this paper is based on an overset framework that employs unstructured mixed-element meshes in the near-body domain combined with high-order Cartesian meshes in o-body.
98
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