基于隐式嵌套重叠网格技术的阻力预测

doi:10.7527/S1000-6893.2013.0024

流体力学与飞行力学

本期目录 | 过刊浏览 | 高级检索

前一篇 | 后一篇

基于隐式嵌套重叠网格技术的阻力预测

徐嘉, 刘秋洪, 蔡晋生, 屈崑

西北工业大学航空学院, 陕西西安 710072

收稿日期:2012-07-31 修回日期:2012-09-10 出版日期:2013-02-25 发布日期:2012-10-18
通讯作者: 蔡晋生 E-mail:jcai@nwpu.edu.cn
作者简介:徐嘉,男,博士研究生。主要研究方向:理论与计算流体力学。E-mail:xj_gogox@sina.com;刘秋洪,男,副教授。主要研究方向:理论与计算流体力学,噪声研究控制。E-mail:qhliu@nwpu.edu.cn;蔡晋生,男,教授,博士生导师。主要研究方向:理论与计算流体力学,飞行器流动控制。Tel:029-88495381,E-mail:jcai@nwpu.edu.cn;屈崑,男,副教授。主要研究方向:理论与计算流体力学,高超声速飞行器设计,并行计算。E-mail:246313@qq.com
基金资助:
国家自然科学基金(10972183)

Drag Prediction Based on Overset Grids with Implict Hole Cutting Technique

XU Jia, LIU Qiuhong, CAI Jinsheng, QU Kun

School of Aeronautics, Northwestern Ploytchnical University, Xi’an 710072, China

Received:2012-07-31 Revised:2012-09-10 Online:2013-02-25 Published:2012-10-18
Contact: 10.7527/S1000-6893.2013.0024 E-mail:jcai@nwpu.edu.cn
Supported by:
National Natural Science Foundation of China (10972183)

摘要/Abstract

摘要：

采用一种多层多块隐式嵌套重叠网格技术,对美国国家航空航天局通用化研究模型(NASA-CRM)翼身平尾(WBT)组合体进行了数值模拟与分析。多层多块隐式嵌套重叠网格技术是结合多层多块嵌套重叠网格处理策略和隐式切割方法,在建立重叠网格之间的流场信息传递关系时,基于网格单元切割准则选择"最优"重叠单元而无需人工设定插值边界。对美国AIAA委员会召开的第4届阻力预测研讨会(DPW-4)提供的CRM WBT组合体生成4种不同密度的结构化多层多块嵌套重叠网格,并采用计算流体力学(CFD)方法进行数值计算和阻力预测,计算结果与CFL3D和OVERFLOW的结果进行了对比。数值模拟结果表明:计算得到的压力分布和极曲线与CFL3D和OVERFLOW的结果几乎相同,说明了隐式嵌套重叠网格技术的有效性,同时也验证了流场求解方法与程序的可靠性。当迎角增大到3°左右时,在机身与机翼、尾翼连接处出现明显的分离涡,影响CRM WBT组合体的气动特性。在阻力预测方面,增加网格密度能够提高阻力预测的精度。采用不同的湍流模型会导致升、阻力系数的计算结果存在一定的差异,因此,湍流模型的选择也是阻力预测需要考虑的因素。

关键词: 数值模拟, 阻力系数, 重叠网格, 多层多块嵌套策略, 隐式切割方法, 翼身平尾组合体

Abstract:

A multi-layer multi-block overset grid technique is presented to accurately simulate the viscous flows around the wing-body-tail (WBT) configuration of a common NASA research model (CRM). Based on the hierarchical overset grid strategy and the implicit hole cutting algorithm, this technique selects the "best" cells located in the overlapped regions by the criterion of cell size, rather than bydetermining whether a computed cell is lying inside (hole cell) or outside (not a hole cell) of a specified region. Four types of grids are built for a CRM WBT configuration proposed in the fourth drag prediction workshop (DPW-4), and viscous flows around the configuration are analyzed by an in-house computational fluid dynamic (CFD) solver. The numerical results show that all the aerodynamic forces matched well with those of CFL3D and OVERFLOW, which demonstrates the accuracy and efficiency of the in-house CFD solver. When the angle of attack is larger than 3°, separation bubbles at the wing and tail trailing edge have some influence on the aerodynamic performance of the CRM WBT configuration. The overset grid density is used to study drag prediction, and computational drag is more accurate with larger sizes of grids. Because the two turbulence models present different predictions of the effect of lift-drag performance, selection of turbulence models is also worth considering on drag prediction.

Key words: numerical simulation, drag coefficient, overset grids, hierarchical grid system, implicit hole cutting, wing-body-tail configuration

中图分类号:

V211.4

徐嘉, 刘秋洪, 蔡晋生, 屈崑. 基于隐式嵌套重叠网格技术的阻力预测[J]. 航空学报, 2013, 34(2): 208-217.

XU Jia, LIU Qiuhong, CAI Jinsheng, QU Kun. Drag Prediction Based on Overset Grids with Implict Hole Cutting Technique[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2013, 34(2): 208-217.

参考文献

[1] van Dam C P. Recent experience with different methods of drag prediction. Progress in Aerospace Sciences, 1999, 35(8): 751-798.

[2] Levy D W, Zickuhr T, Vassberg J, et al. Summary of data from the first AIAA CFD drag prediction workshop. AIAA-2002-841, 2002.

[3] Lain K R, Vassberg J C, Wahls R A, et al. Summary of data from the second AIAA CFD drag prediction workshop. AIAA-2004-555, 2004.

[4] Vassberg J C, Brodersen O P, Wahls R A, et al. Summary of the fourth AIAA CFD drag prediction workshop. AIAA-2010-4547, 2010.

[5] Thompson J F, Weatherill N P. Aspects of numerical grid generation: current and art. AIAA-1993-3539, 1993.

[6] Prewitt N C, Belk D M, Shyy W. Parallel computing of overset grids for aerodynamic problems with moving grids. Progress in Aerospace Sciences, 2000, 36(6): 117-172.

[7] Yan C. The method and application for computational fluid dynamics. Beijing: Beihang University Press, 2006:200-201. (in Chinese) 阎超. 计算流体力学方法及应用. 北京: 北京航空航天大学出版社, 2006: 200-201.

[8] Lee Y L, Baeder J D. Implicit hole cutting—a new approach to overset grid connectivity. AIAA-2003-4128, 2003.

[9] Liao W, Cai J, Tsai H M. A multigrid overset grid flow solver with implicit hole cutting method. Computer Methods in Appllied Mechanics Engineering, 2007, 196(9):1701-1715.

[10] Landmann B, Montagnac M. A highly automated parallel Chimera method for overset grids based on the implicit hole cutting technique. International Journal for Numerical Methods in Fluids, 2011, 66(6): 778-804.

[11] Tian S L. The algorithm study on unstructured overset grid. Nanjing: College of Aerospace Engineering, Nanjing University of Aeronautics and Astronautics, 2008. (in Chinese) 田书玲. 基于非结构网格方法的重叠网格算法研究.南京: 南京航空航天大学航空宇航学院, 2008.

[12] Yasuhiro W, Meng S L. A flux splitting scheme with high-resolution and robustness for discontinuities. NASA Technical Memorandum 106452, Washington, D.C: Microfiche, 1994.

[13] Vos J B, Leyland P, van Kemenade, et al. NSMB handbook version 5.0. IMHEF-DGM-EPFL, 2003.

[14] Menter F R. Zonal two-equation k-ω turbulence model for aerodynamic flows. AIAA-1993-2906, 1993.

[15] Edwards J R, Chandra S. Comparison of eddy viscosity-transport turbulence models for three-dimensional, shock-separated flowfields. AIAA Jounal, 1996, 34(4): 756- 763.

[16] Pan Y F. An auto-disposal technology of overlap grid methed and its application on CFD. Changsha: College of Aerospace and Materials Engineering, National University of Defense Technology, 2005. (in Chinese) 庞宇飞. 重叠网格自动处理技术及其应用. 长沙: 国防科学技术大学航天与材料工程学院, 2005.

[17] 4th CFD drag prediction workshop. URL: http://aaac.larc.nass.gov/tsab/cfdlarc/aiaa-dpw/, email: dpw@cessna.textron.com, June 2009.

E-mail：hkxb@buaa.edu.cn

关于我们

期刊社服务

专业学科

封面文章

友情链接

主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

基于隐式嵌套重叠网格技术的阻力预测

Drag Prediction Based on Overset Grids with Implict Hole Cutting Technique

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	夏侯唐凡, 陈江涛, 邵志栋, 吴晓军, 刘宇. 随机和认知不确定性框架下的CFD模型确认度量综述[J]. 航空学报, 2022, 43(8): 25716-025716.
[2]	杨建凯, 顾冬冬, 葛庆, 檀晨晨, 文雨. 铝合金激光增材制造支撑布局及精确成形机制[J]. 航空学报, 2022, 43(4): 525331-525331.
[3]	姜有旭, 李杰, 杨钊. 某层流机翼验证机风洞试验数据修正方法[J]. 航空学报, 2022, 43(11): 526814-526814.
[4]	段俊亦, 童福林, 李新亮, 刘洪伟. 压缩-膨胀湍流边界层平均摩阻分解[J]. 航空学报, 2022, 43(1): 625915-625915.
[5]	刘朋欣, 袁先旭, 孙东, 傅亚陆, 李辰. 高温化学非平衡湍流边界层直接数值模拟[J]. 航空学报, 2022, 43(1): 124877-124877.
[6]	沈鹏飞, 刘朋欣, 孙东, 袁先旭. 马赫6柱-裙构型激波/湍流边界层干扰摩阻统计特性[J]. 航空学报, 2022, 43(1): 626005-626005.
[7]	刘朋欣, 袁先旭, 梁飞, 李辰, 孙东. 高温化学非平衡湍流边界层脉动量象限分析[J]. 航空学报, 2021, 42(S1): 726338-726338.
[8]	鲍俊, 王瑜, 牛潜, 朱锡冬, 程建杰. 喷雾液滴撞击液膜影响参数及流动机理分析[J]. 航空学报, 2021, 42(S1): 726360-726360.
[9]	陈崇沛, 梁剑寒, 关清帝, 高天运. 守恒型可压缩一维湍流方法及其在超声速标量混合层中的应用[J]. 航空学报, 2021, 42(S1): 726364-726364.
[10]	李青, 涂国华, 余钊圣, 林昭武, 李婷婷, 袁先旭. 惯性颗粒在非均匀加速流中的输运问题[J]. 航空学报, 2021, 42(S1): 726390-726390.
[11]	李成成, 李芳, 杨斌, 王莹. 等离子体激励抑制喷管分离流动数值模拟[J]. 航空学报, 2021, 42(7): 124547-124547.
[12]	郭永恒, 江雄, 肖中云, 王子维, 卢风顺. 一种自动化并行重叠网格隐式装配方法[J]. 航空学报, 2021, 42(6): 124369-124369.
[13]	刘宗兴, 刘军, 李维娜. 爆炸冲击载荷下典型机身结构动响应及破坏[J]. 航空学报, 2021, 42(2): 224252-224252.
[14]	孙东, 刘朋欣, 沈鹏飞, 童福林, 郭启龙. 马赫数6柱-裙激波/边界层干扰直接模拟[J]. 航空学报, 2021, 42(12): 124681-124681.
[15]	王方, 王煜栋, 姜胜利, 陈军, 唐军, 徐华胜, 李象远, 邢竞文, 高东硕, 金捷. AECSC-JASMIN湍流燃烧仿真软件研发和检验[J]. 航空学报, 2021, 42(12): 625003-625003.