引用本文: | 钟诚文,陈健锋,张瑞,等.双原子分子气体的定常隐式全流域多尺度算法.[J].国防科技大学学报,2023,45(4):94-108.[点击复制] |
ZHONG Chengwen,CHEN Jianfeng,ZHANG Rui,et al.Multi-scale implicit scheme for steady flows of diatomic molecular gases in all flow regimes[J].Journal of National University of Defense Technology,2023,45(4):94-108[点击复制] |
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双原子分子气体的定常隐式全流域多尺度算法 |
钟诚文1,2,3,陈健锋1,张瑞1,卓丛山1,2,3,刘沙1,2,3 |
(1. 西北工业大学 航空学院, 陕西 西安 710072;2. 西北工业大学 极端力学研究院, 陕西 西安 710072;3. 西北工业大学 翼型、叶栅空气动力学国家级重点实验室, 陕西 西安 710072)
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摘要: |
巨大的计算资源需求极大地阻碍了统一气体动理学格式的应用。采用宏观预估技术,基于Boltzmann-Rykov模型方程发展全流域适用的保守恒定常隐式算法,协同求解宏观方程和微观方程以加速收敛。在单元界面,通过模型方程特征差分解构造简单高效的多尺度数值通量,并结合非均匀非结构速度空间和速度空间自适应技术进一步降低计算需求、提升计算效率。超声速和高超声速平板绕流和圆球绕流的数值结果验证了算法的准确性与高效性。结果表明,算法能够准确求解二维和三维双原子气体多尺度流动问题,且相比于显式离散统一气体动理学格式可加速一个量级。 |
关键词: 多尺度算法 隐式算法 稀薄气体 双原子气体 |
DOI:10.11887/j.cn.202304009 |
投稿日期:2023-03-16 |
基金项目:国家自然科学基金资助项目(12172301,11902266,12072283,11902264);国家“111计划”资助项目(B17037) |
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Multi-scale implicit scheme for steady flows of diatomic molecular gases in all flow regimes |
ZHONG Chengwen1,2,3, CHEN Jianfeng1, ZHANG Rui1, ZHUO Congshan1,2,3, LIU Sha1,2,3 |
(1. School of Aeronautics, Northwestern Polytechnical University, Xi′an 710072, China;2. Institute of Extreme Mechanics, Northwestern Polytechnical University, Xi′an 710072, China;3. National Key Laboratory of Science and Technology on Aerodynamic Design and Research, Northwestern Polytechnical University, Xi′an 710072, China)
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Abstract: |
The application of unified gas kinetic scheme is greatly hindered by the huge requirements of computing resources. Based on Boltzmann-Rykov model equation, a conservative implicit scheme for steady flows in all flow regimes was developed by adopting macroscopic prediction technique, and the macroscopic equation and microscopic equation were solved collaboratively to accelerate the convergence. At the cell interface, a simplified and efficient multi-scale numerical flux was directly constructed from the characteristic difference solution of kinetic model equation. The adoption of non-uniform, unstructured velocity space and velocity space adaptive technology further reduce the requirement of computation and improve computational efficiency. The applications of unstructured discrete velocity space and adaptive discrete velocity space reduced the number of velocity mesh significantly and made the present method be rather efficient. The accuracy and effectiveness of the proposed method were confirmed by the simulations of rarefied supersonic and hypersonic flows over a flat plate, supersonic and hypersonic flows over a sphere. Numerical results indicate that the proposed method can accurately solve two-dimensional and three-dimensional diatomic gas multi-scale flow problems, and it is about one orders of magnitude faster than the explicit discrete unified gas kinetic scheme method. |
Keywords: multi-scale scheme implicit scheme rarefied gas diatomic gas |
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