A CFD/CTD/CSD BASED AERO-THERMO-ELASTIC FRAMEWORK FOR FULL-VEHICLE SCALE ANALYSIS

Liang Ma; Zhiqiang Wan; Xiaozhe Wang; Keyu Li; Chang Li; Longfei He

A CFD/CTD/CSD BASED AERO-THERMO-ELASTIC FRAMEWORK FOR FULL-VEHICLE SCALE ANALYSIS

Liang Ma
, Zhiqiang Wan
, Xiaozhe Wang^*
, Keyu Li
, Chang Li
, Longfei He

^*此作品的通讯作者

科研成果: 会议稿件 › 论文 › 同行评审

摘要

Due to the significant multidisciplinary coupling mechanism inherent in hypersonic flight mission, unnecessary and wasteful trade-off in vehicle performance will be cost if complex load distribution and aerodynamic heating effect are neglected at the early stage of design. This paper establishes an CFD/CTD/CSD based aero-thermo-elastic framework for analysis of the full-vehicle scale. The loose coupling strategy is chosen in this framework to reveal the specific efforts of each disciplinary, and the RBF-TFI method is introduced for mesh deformation. This study is carried on the rudders assembled on a hypersonic missile, with the high-fidelity aerodynamic data of the full-vehicle model extracted by CFD and only the component deformation of the rudders extracted by FEM. This paper demonstrates the aero-thermo-elastic effects of those factors concealed by engineering algorithms, with the influence mechanism revealed from the results discussed.

源语言	英语
出版状态	已出版 - 2024
活动	2024 International Forum on Aeroelasticity and Structural Dynamics, IFASD 2024 - The Hague, 荷兰期限: 17 6月 2024 → 21 6月 2024

会议

会议	2024 International Forum on Aeroelasticity and Structural Dynamics, IFASD 2024
国家/地区	荷兰
市	The Hague
时期	17/06/24 → 21/06/24

其它文件与链接

链接到 Scopus 的出版物

引用此

@conference{eb01f21cfb0c409d90eb7d58a65eb45d,

title = "A CFD/CTD/CSD BASED AERO-THERMO-ELASTIC FRAMEWORK FOR FULL-VEHICLE SCALE ANALYSIS",

abstract = "Due to the significant multidisciplinary coupling mechanism inherent in hypersonic flight mission, unnecessary and wasteful trade-off in vehicle performance will be cost if complex load distribution and aerodynamic heating effect are neglected at the early stage of design. This paper establishes an CFD/CTD/CSD based aero-thermo-elastic framework for analysis of the full-vehicle scale. The loose coupling strategy is chosen in this framework to reveal the specific efforts of each disciplinary, and the RBF-TFI method is introduced for mesh deformation. This study is carried on the rudders assembled on a hypersonic missile, with the high-fidelity aerodynamic data of the full-vehicle model extracted by CFD and only the component deformation of the rudders extracted by FEM. This paper demonstrates the aero-thermo-elastic effects of those factors concealed by engineering algorithms, with the influence mechanism revealed from the results discussed.",

keywords = "CFD method, FEM method, Hypersonic, aero-thermo-elasticity, partitioned loose coupling strategy",

author = "Liang Ma and Zhiqiang Wan and Xiaozhe Wang and Keyu Li and Chang Li and Longfei He",

note = "Publisher Copyright: {\textcopyright} 2024 International Forum on Aeroelasticity and Structural Dynamics, IFASD 2024. All rights reserved.; 2024 International Forum on Aeroelasticity and Structural Dynamics, IFASD 2024 ; Conference date: 17-06-2024 Through 21-06-2024",

year = "2024",

language = "英语",

}

TY - CONF

T1 - A CFD/CTD/CSD BASED AERO-THERMO-ELASTIC FRAMEWORK FOR FULL-VEHICLE SCALE ANALYSIS

AU - Ma, Liang

AU - Wan, Zhiqiang

AU - Wang, Xiaozhe

AU - Li, Keyu

AU - Li, Chang

AU - He, Longfei

PY - 2024

Y1 - 2024

N2 - Due to the significant multidisciplinary coupling mechanism inherent in hypersonic flight mission, unnecessary and wasteful trade-off in vehicle performance will be cost if complex load distribution and aerodynamic heating effect are neglected at the early stage of design. This paper establishes an CFD/CTD/CSD based aero-thermo-elastic framework for analysis of the full-vehicle scale. The loose coupling strategy is chosen in this framework to reveal the specific efforts of each disciplinary, and the RBF-TFI method is introduced for mesh deformation. This study is carried on the rudders assembled on a hypersonic missile, with the high-fidelity aerodynamic data of the full-vehicle model extracted by CFD and only the component deformation of the rudders extracted by FEM. This paper demonstrates the aero-thermo-elastic effects of those factors concealed by engineering algorithms, with the influence mechanism revealed from the results discussed.

AB - Due to the significant multidisciplinary coupling mechanism inherent in hypersonic flight mission, unnecessary and wasteful trade-off in vehicle performance will be cost if complex load distribution and aerodynamic heating effect are neglected at the early stage of design. This paper establishes an CFD/CTD/CSD based aero-thermo-elastic framework for analysis of the full-vehicle scale. The loose coupling strategy is chosen in this framework to reveal the specific efforts of each disciplinary, and the RBF-TFI method is introduced for mesh deformation. This study is carried on the rudders assembled on a hypersonic missile, with the high-fidelity aerodynamic data of the full-vehicle model extracted by CFD and only the component deformation of the rudders extracted by FEM. This paper demonstrates the aero-thermo-elastic effects of those factors concealed by engineering algorithms, with the influence mechanism revealed from the results discussed.

KW - CFD method

KW - FEM method

KW - Hypersonic

KW - aero-thermo-elasticity

KW - partitioned loose coupling strategy

UR - https://www.scopus.com/pages/publications/105019524728

M3 - 论文

AN - SCOPUS:105019524728

T2 - 2024 International Forum on Aeroelasticity and Structural Dynamics, IFASD 2024

Y2 - 17 June 2024 through 21 June 2024

ER -

A CFD/CTD/CSD BASED AERO-THERMO-ELASTIC FRAMEWORK FOR FULL-VEHICLE SCALE ANALYSIS

摘要

会议

其它文件与链接

指纹

引用此