2015, 7(2): 80-83.
计算风工程中的网格技术对比研究
| 1. | 中国建筑科学研究院建研科技股份有限公司,北京 100013 |
| 2. | 北京市燃气集团研究院,北京 100011 |
Comparative Analysis on Grids Generation in Computational Wind Engineering
| 1. | CABR Technology Co., Ltd., China Academy of Building Research, Beijing 100013, China |
| 2. | Academy of Beijing Gas Group Co., Ltd., Beijing 100011, China |
引用本文:
康忠良, 方媛媛. 计算风工程中的网格技术对比研究[J]. 土木建筑工程信息技术,
2015, 7(2): 80-83.
Citation:
Kang Zhongliang, Fang Yuanyuan. Comparative Analysis on Grids Generation in Computational Wind Engineering[J]. Journal of Information Technologyin Civil Engineering and Architecture,
2015, 7(2): 80-83.
摘要:通过对比风工程数值模拟中可供选择的各种网格技术,深入分析了几种网格各自的特点。结构网格与非结构网格的优缺点基本是对立互补的,混合网格技术代表了当前和未来网格技术的主要发展趋势。自适应笛卡尔网格自动化程度高,对于各向同性流动问题极具优势。由于目前从事计算风工程的专业人员网格生成能力较差,自适应笛卡尔网格特别适合于风工程的低速复杂湍流问题的模拟。
Abstract: Several grid generation technologies are compared based on computational wind engineering. The advantages and disadvantages of structured grids and unstructured grids are opposite and mutually complementary, so mixed grids represent the current and future major development trend of grid generation. Adaptive Cartesian grids can be generated automatically, and show a great advantage for isotropic flow simulation. Adaptive Cartesian grids are particularly suitable for low speed complex turbulence flow simulation on wind engineering, for most professionals currently have a poor capacity for grid generation.
| [1] |
Sheng C, Taylor L, Whitfield D. Multiblockmultigrid solution of three dimensional incompressible turbulent flows about appended submarine configuration[R].AIAA-1995-0203. |
| [2] |
Flores J, Reznick S G, Holst T L. Transonic Navier-Stokes solution for a fighter-like configuration[R]. AIAA-1987-0032. |
| [3] |
Peace D G, Atanley S, Martin F. Development of a large Chimera grid system for space shuttle[R].AIAA-1993-0533. |
| [4] |
Frink N T, Shahyar Z Pirzadeh. Tetrahedral finite-volume solutions to the Navier-Stokes equations on complex configurations[R].NASA/TM-1998-208961. |
| [5] |
Baker T J. Mesh generation: art or science[J]. Prog.Aero. Sci., 2005, 41: 29-63.doi: 10.1016/j.paerosci.2005.02.002 |
| [6] |
Nakamichi J. Calculations of unsteady Navier-Stokes equations around an oscillating 3D wing using moving grid system[R]. AIAA-1987-1158. |
| [7] |
AftosmisM J, BergerM J, Melton JE. Robustand efficientcartesian mesh generation for component-based geometry[R]. AIAA-1997-0196. |
| [8] |
Lijewski L E. Comparison of transonic store separation trajectory predictions using the Pegasus/DXEAGLE and DEGGER Codes[R]. AIAA-1997-2202. |
| [9] |
FumiyaTogashi, Yasushi Ito, Kazuhiro Nakahashi. Extensions of overset unstructured grids to multiple bodies in contact[J]. Journal of Aircraft, 2006, 43(1): 52-57.doi: 10.2514/1.540 |
| [10] |
Griibe B, Carstens V. Computational of unsteady transonic flow in harmonically oscillating turbine cascades taking into account viscous effects[J]. ASME journal. Turbomachinery, 1998, 120(1): 104-111.doi: 10.1115/1.2841370 |
| [11] |
Hassan O, Probert E J, Morgan K. Unstructured mesh procedures for the simulation of three-dimensional transient compressible inviscid flows with moving boundary components[J]. Int. J. Numer. Mesh. Fluids, 1998, 27: 41-55.doi: 10.1002/(ISSN)1097-0363 |
| [12] |
张来平, 王振亚, 杨永健.复杂外形的动态混合网格生成方法[J].空气动力学学报, 2004, 22(2): 231-236. |
计量
- PDF下载量(17)
- 文章访问量(1090)
- HTML全文浏览量(1365)
