多场耦合系统动力学仿真方法研究进展

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doi:10.6052/1000-0992-22-043

1.
南京理工大学发射动力学研究所, 南京 210094
2.
南京理工大学能源与动力工程学院, 南京 210094

基金项目:国家自然科学基金 (11972193, 92266201) 资助项目

详细信息

作者简介:
王国平, 南京理工大学教授, 博士生导师, 发表论文160余篇, 主持国家和省部级项目10多项, 获首届国防卓越青年基金、中国青年科技奖、国家高层次人才计划、国家百千万人才工程、教育部新世纪优秀人才支持计划和江苏省“333工程”中青年领军人才等

通讯作者:
taoling@njust.edu.cn

中图分类号:O302
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- 被引次数:0
出版历程
- 收稿日期:2022-09-28
- 录用日期:2022-10-21
- 网络出版日期:2022-10-22
- 刊出日期:2023-06-25

Review of dynamics simulation methods for multi-field coupling systems

1.
Institute of Launch Dynamics, Nanjing University of Science and Technology, Nanjing 210094, China,
2.
School of Energy and Power Engineering, Nanjing University of Science and Technology, Nanjing 210094, China

More Information

Corresponding author:taoling@njust.edu.cn

摘要

摘要:现代工程系统往往是以复杂结构/机械系统为主体, 融合热、流、电磁等若干子系统的多场耦合系统. 此类系统动力学建模复杂、计算难度大, 给系统动态特性高效精确评估与设计优化带来前所未有的挑战, 有关其高效精确动力学仿真方法的研究愈发受到关注. 本文详细回顾了复杂工程系统多场耦合动力学仿真方法研究成果和进展, 包括: 多场耦合动力学建模与数值求解基本策略、网格变形处理方法、耦合数据交换技术、数值计算效率等问题, 在此基础上详细讨论了单一和混合不确定性条件下多场耦合系统不确定性分析及可靠性评估方法, 以期为相关研究提供有益的借鉴和参考.
- 多场耦合/
- 动网格/
- 分区求解/
- 不确定性/
- 可靠性/
- 耦合数据传递
Abstract:Modern engineering system is usually a multi-field coupling system with complex structure/mechanical system as the main body, which integrates thermal, electromagnetic, fluid and other subsystems. The dynamics modeling of these systems are complex and their numerical calculate are also difficult, which bring unprecedented challenges to the efficient and accurate evaluation and design optimization of the system dynamic characteristics. In this paper, the research progress of multi-field coupling dynamics simulation methods for complex engineering systems are reviewed in detail, including the basic strategies of multi-field coupling dynamics modeling and numerical solution, mesh deformation processing method, coupling data exchange technology, numerical calculation efficiency, etc. On this basis, for uncertain multi-field coupling engineering systems, their uncertainty analysis and reliability evaluation methods under single and hybrid uncertainties are discussed in detail. This review paper is expected to provide some useful references for related researchers.
- multi-field coupling/
- dynamic grid/
- partition solution/
- uncertainty/
- reliability/
- coupling data exchange

HTML全文

图 1多物理场典型耦合关系和耦合变量示意图 (Rong et al. 2019,王思莹等 2014,Hron & Turek 2006,Degroote et al. 2009,宋少云 2007,Dietz et al. 2001,Fernández 2011,Erbts et al. 2015,Degroote & Vierendeels 2011)

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图 2典型流场−结构场耦合问题分区解法示意图

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图 3典型充液多刚体系统动力学问题分区解法示意图 (Rumold 2001)

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图 4径向基函数和Delaunay背景图相结合的网格变形方法 (蒋波 2017)

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图 5双翼型轨迹模拟过程网格变形/重构示意图. (a)背景网格与运动物体子网格, (b)初始位置网格, (c)网格变形, (d)大变形的网格重构 (徐琳和宋万强 2019)

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图 6基于多体系统传递矩阵法和Van der Pol的海洋热塑性增强管流固耦合仿真. (a) 立管模型示意图, (b) 剪切流情况下立管轴向涡激振动振幅分布 (芮雪等 2020)

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图 7基于多体系统传递矩阵法的多管火箭燃气射流−多体动力学单向耦合仿真. (a) 多管火箭发射系统动力学模型, (b) 不同时刻迎气面压强, (c) 定向管口y方向位移、角速度 (李书田 2020)

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图 8弹炮耦合武器系统多速率协同仿真. (a) 弹丸−火炮多体系统耦合模型, (b) 多速率积分方法, (c) 后座位移和炮口位移时间历程 (Rong et al. 2013)

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图 9不确定性刚−柔−热耦合梁系统动力学响应非侵入式自适应稀疏多项式混沌展开计算. (a) 热效应下中心刚体−梁系统, (b) 非侵入式自适应稀疏多项式混沌展开算法, (c) 梁末端横向变形标准差 (Rong et al. 2023)

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图 10FORM-α-URA方法原理 (孟欣佳 2016)

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