High-Altitude Airship Propeller Fluid–Structure Interaction Solver

Dongchen Wang; Bifeng Song; Dong Xue

doi:10.1007/978-981-99-8045-1_39

High-Altitude Airship Propeller Fluid–Structure Interaction Solver

Dongchen Wang, Bifeng Song, Dong Xue

航空学院

Northwestern Polytechnical University Xian

科研成果: 书/报告/会议事项章节 › 章节 › 同行评审

摘要

This paper presents a study on fluid–structure interaction (FSI) solver for propellers of composite materials, which are commonly used on high-altitude airships and require FSI consideration for better propulsion optimal design. The FSI solver consists of an aerodynamic solver and a structural solver. The aerodynamic solver is a RANS (Reynolds Average Navier–Stokes) solver based on an in-house code named ROTNS. The structural solver is based on the secondary development of a commercial finite element software using Patran Command Language (PCL). The general framework of the FSI solver is built using C++ language and a weak coupling approach. To validate the accuracy of the solver for propulsion optimal design, wind tunnel test, ground static thrust test and structural deformation test were conducted. The numerical results show good agreement with the experimental results.

源语言	英语
主期刊名	Springer Aerospace Technology
出版商	Springer Science and Business Media Deutschland GmbH
页	463-470
页数	8
DOI	https://doi.org/10.1007/978-981-99-8045-1_39
出版状态	已出版 - 2024

出版系列

姓名	Springer Aerospace Technology
卷	Part F3122
ISSN（印刷版）	1869-1730
ISSN（电子版）	1869-1749

访问文件

10.1007/978-981-99-8045-1_39

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引用此

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abstract = "This paper presents a study on fluid–structure interaction (FSI) solver for propellers of composite materials, which are commonly used on high-altitude airships and require FSI consideration for better propulsion optimal design. The FSI solver consists of an aerodynamic solver and a structural solver. The aerodynamic solver is a RANS (Reynolds Average Navier–Stokes) solver based on an in-house code named ROTNS. The structural solver is based on the secondary development of a commercial finite element software using Patran Command Language (PCL). The general framework of the FSI solver is built using C++ language and a weak coupling approach. To validate the accuracy of the solver for propulsion optimal design, wind tunnel test, ground static thrust test and structural deformation test were conducted. The numerical results show good agreement with the experimental results.",

keywords = "Fluid–structure interaction, High-altitude airship propeller, Reynolds average Navier–Stokes",

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AU - Song, Bifeng

AU - Xue, Dong

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.

PY - 2024

Y1 - 2024

N2 - This paper presents a study on fluid–structure interaction (FSI) solver for propellers of composite materials, which are commonly used on high-altitude airships and require FSI consideration for better propulsion optimal design. The FSI solver consists of an aerodynamic solver and a structural solver. The aerodynamic solver is a RANS (Reynolds Average Navier–Stokes) solver based on an in-house code named ROTNS. The structural solver is based on the secondary development of a commercial finite element software using Patran Command Language (PCL). The general framework of the FSI solver is built using C++ language and a weak coupling approach. To validate the accuracy of the solver for propulsion optimal design, wind tunnel test, ground static thrust test and structural deformation test were conducted. The numerical results show good agreement with the experimental results.

AB - This paper presents a study on fluid–structure interaction (FSI) solver for propellers of composite materials, which are commonly used on high-altitude airships and require FSI consideration for better propulsion optimal design. The FSI solver consists of an aerodynamic solver and a structural solver. The aerodynamic solver is a RANS (Reynolds Average Navier–Stokes) solver based on an in-house code named ROTNS. The structural solver is based on the secondary development of a commercial finite element software using Patran Command Language (PCL). The general framework of the FSI solver is built using C++ language and a weak coupling approach. To validate the accuracy of the solver for propulsion optimal design, wind tunnel test, ground static thrust test and structural deformation test were conducted. The numerical results show good agreement with the experimental results.

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M3 - 章节

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High-Altitude Airship Propeller Fluid–Structure Interaction Solver

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