高阶矩湍流模型研究进展及挑战

王圣业; 符翔; 杨小亮; 郑皓榜; 邓小刚

doi:10.6052/1000-0992-20-029

高阶矩湍流模型研究进展及挑战

doi: 10.6052/1000-0992-20-029

王圣业¹,
符翔¹,
杨小亮¹,
郑皓榜¹,
邓小刚^1,2,*, ,

¹ 国防科技大学空天科学学院, 长沙 410073
² 军事科学院, 北京 100190

基金项目:

国家自然科学基金 (12002379)、湖南省自然科学基金 (2020JJ5648)、国防科技大学科研计划 (ZK20-43) 和国家专项工程 (GJXM92579) 资助项目.

详细信息

作者简介:
*E-mail: xgdeng2000@vip.sina.com
王圣业, 国防科技大学副教授, 主要从事计算流体力学方法研究与大型CAE软件平台开发工作. 2013年于北京航空航天大学获学士学位, 2018年于国防科技大学获博士学位, 师从邓小刚院士. 现为某国家重大工程副主任设计师、中国力学学会会员, 主持国家自然科学基金青年基金项目、湖南省自然科学基金青年基金项目、国防科技大学科研计划项目3项. 以第一通讯作者身份在国内外学术期刊上发表SCI论文9篇, EI论文3篇.

通讯作者:
邓小刚

中图分类号: O357.5
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出版历程
- 收稿日期: 2020-11-16
- 刊出日期: 2021-03-25

Progresses and challenges of high-order-moment turbulence closure

¹ College of Aerospace Science and Engineering, National University of Defense Technology, Changsha 410073, China
² Academy of Military Sciences, Beijing 100190, China

More Information

Corresponding author: DENG Xiaogang

摘要

摘要: 高阶矩模型是湍流模式理论研究中的难点和前沿. 自周培源先生首次建立一般湍流的雷诺应力输运方程起, 为了更精确的预测复杂流动, 人们从未间断过对高阶矩模型的研究. 尤其进入新世纪以来, 随着计算机硬件水平的飞跃和高精度数值算法的突破, 湍流模拟方法正由RANS向LES转变. 而无论对于RANS框架、LES框架还是两者混合, 高阶矩模式都是其中先进封闭模式的代表. 基于此, 本文对高阶矩模型的发展情况进行了总结, 重点包括高阶矩模型中各项的建模方式、尺度提供方程的演化历程和数值求解技术的关键需求. 然后, 通过几类典型湍流问题展示了其相对于传统涡黏模型的优势, 并且给出了部分CFD软件对高阶矩模型的集成情况. 最后对高阶矩湍流模型未来面临的挑战和发展的方向进行了展望.
- 湍流模型 /
- 计算流体力学 /
- 雷诺应力模型 /
- 雷诺平均模拟 /
- 大涡数值模拟
Abstract: High-order-moment model is one of the focuses and frontier topics in the research of turbulence closure theory. Since Mr. Chou first established the Reynolds-stress transport equation in general turbulence, scholars have never stopped to study the high-order-moment model in order to predict the complex flow more accurately. Especially in the new century, thanks to the rapid development of computer hardware and the breakthrough of high-order numerical methods, turbulence simulation is in the course of turning from RANS into LES. In either RANS framework, LES framework, or the hybrid one, high-order-moment models are representative of advanced closure models. According to this, the paper gives a general review of the high-order-moment models. The focus includes the modeling approach of each source item, the evolution process of scale providing equations, and the research demand of numerical solution technology. Through several typical turbulence problems, their advantages over the traditional eddy-viscosity models are shown. Moreover, the integration of high-order-moment models in some CFD software is given. Finally, the future challenges and development direction of the high-order-moment turbulence model are prospected.
- turbulence model /
- computational fluid dynamics /
- Reynolds-stress model /
- RANS /
- LES

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