{"title":"The effects of magnetic field on supersonic flutter characteristics of dielectric plate: Dependence amplitude-speed","authors":"Marine A. Mikilyan, Iren A. Vardanyan","doi":"10.1016/j.jfluidstructs.2024.104140","DOIUrl":null,"url":null,"abstract":"<div><p>For aircraft design, design of the wing shape (for example, as a panel) is critical as it affects aerodynamic performance. In case, when panel is made of a material with magnetic properties, magnetic field of different origin plays an important role. As aircraft designers strive for improved efficiency and performance, accurate prediction of magneto-aeroelastic effects is becoming a necessity. For example, while high aspect ratio wings have higher aerodynamic efficiency, the structural deformation of the wing under the influence of both aerodynamic load and magnetic field is no longer negligible and a coupled analysis needs to be carried out to during the design phase.</p><p>This paper offers the authors’ views on critical magneto-aeroelastic behavior for dielectric rectangular isotropic plates and is a continuation of the work (<span>Baghdasaryan et al., 2023</span>): “Supersonic flutter characteristics of dielectric rectangular plate: The effects of magneto-aero-hydrodynamic interactions, Journal of Fluids and Structures, 2023”.</p><p>The work \"Supersonic flutter characteristics of dielectric rectangular plate: The effects of magneto-aero-hydrodynamic interactions\" presents both, linear and non-linear flutter behaviour of an isotropic dielectrical plate streamlined by a perfectly conductive supersonic gas flow and immersed in a longitudinal magnetic field. It is assumed, that flowing liquid is an inviscid, non-heat-conducting one with infinite conductivity. For the first time, an analytical expression of the aerodynamic pressure accounting for an applied magnetic field is presented. This expression generalizes the formula of piston theory to account for magnetic field interactions. Based on the linear problem of aero-magneto-flutter, stability conditions are obtained and corresponding stability boundary is found. As a result, of the analytical description, the influence of magnetic field on the critical speed is investigated for different geometrical parameters and different parameters of the magnetic field. The influence of the number of modes on the critical flutter speed is investigated as well. It is shown, that the magnetic field decreases the stability boundary of a steady flutter type oscillations of rectangular plate.</p><p>Using the expressions for forces, acting on the body, and the theory of thin flexible plates the system of equations, describing vibrations and stability of plates, is obtained. Having solved the formulated boundary-value problems both qualitative and quantitative influence of magnetic field and flowing stream on the existence of non-linear flutter type oscillations and on the dependence of the amplitude of oscillations on the frequency for the fixed values of flowing stream are investigated. The presented work differs from the previous one in the subject of research. There are many studies in the scientific literature that study the amplitude-frequency dependence of both natural and forced oscillations. There are numerous studies of the amplitude-velocity relationship of flutter oscillations without taking into account the magnetic field.</p><p>In the presented work is devoted to filling this gap and the influence of a magnetic field on the nonlinear characteristics of supersonic flutter, namely on the amplitude-velocity dependence of nonlinear flutter oscillations is investigated.</p></div>","PeriodicalId":54834,"journal":{"name":"Journal of Fluids and Structures","volume":null,"pages":null},"PeriodicalIF":3.4000,"publicationDate":"2024-06-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Fluids and Structures","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0889974624000756","RegionNum":2,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENGINEERING, MECHANICAL","Score":null,"Total":0}
引用次数: 0
Abstract
For aircraft design, design of the wing shape (for example, as a panel) is critical as it affects aerodynamic performance. In case, when panel is made of a material with magnetic properties, magnetic field of different origin plays an important role. As aircraft designers strive for improved efficiency and performance, accurate prediction of magneto-aeroelastic effects is becoming a necessity. For example, while high aspect ratio wings have higher aerodynamic efficiency, the structural deformation of the wing under the influence of both aerodynamic load and magnetic field is no longer negligible and a coupled analysis needs to be carried out to during the design phase.
This paper offers the authors’ views on critical magneto-aeroelastic behavior for dielectric rectangular isotropic plates and is a continuation of the work (Baghdasaryan et al., 2023): “Supersonic flutter characteristics of dielectric rectangular plate: The effects of magneto-aero-hydrodynamic interactions, Journal of Fluids and Structures, 2023”.
The work "Supersonic flutter characteristics of dielectric rectangular plate: The effects of magneto-aero-hydrodynamic interactions" presents both, linear and non-linear flutter behaviour of an isotropic dielectrical plate streamlined by a perfectly conductive supersonic gas flow and immersed in a longitudinal magnetic field. It is assumed, that flowing liquid is an inviscid, non-heat-conducting one with infinite conductivity. For the first time, an analytical expression of the aerodynamic pressure accounting for an applied magnetic field is presented. This expression generalizes the formula of piston theory to account for magnetic field interactions. Based on the linear problem of aero-magneto-flutter, stability conditions are obtained and corresponding stability boundary is found. As a result, of the analytical description, the influence of magnetic field on the critical speed is investigated for different geometrical parameters and different parameters of the magnetic field. The influence of the number of modes on the critical flutter speed is investigated as well. It is shown, that the magnetic field decreases the stability boundary of a steady flutter type oscillations of rectangular plate.
Using the expressions for forces, acting on the body, and the theory of thin flexible plates the system of equations, describing vibrations and stability of plates, is obtained. Having solved the formulated boundary-value problems both qualitative and quantitative influence of magnetic field and flowing stream on the existence of non-linear flutter type oscillations and on the dependence of the amplitude of oscillations on the frequency for the fixed values of flowing stream are investigated. The presented work differs from the previous one in the subject of research. There are many studies in the scientific literature that study the amplitude-frequency dependence of both natural and forced oscillations. There are numerous studies of the amplitude-velocity relationship of flutter oscillations without taking into account the magnetic field.
In the presented work is devoted to filling this gap and the influence of a magnetic field on the nonlinear characteristics of supersonic flutter, namely on the amplitude-velocity dependence of nonlinear flutter oscillations is investigated.
在飞机设计中,机翼形状(如面板)的设计至关重要,因为它会影响空气动力性能。如果面板由具有磁性的材料制成,不同来源的磁场将发挥重要作用。随着飞机设计人员努力提高效率和性能,对磁气动弹性效应进行精确预测已成为一种必然。例如,虽然高纵横比机翼具有更高的气动效率,但机翼在气动载荷和磁场影响下的结构变形已不容忽视,因此需要在设计阶段进行耦合分析。本文是作者对介电矩形各向同性板临界磁气动弹性行为的看法,是其研究成果(Baghdasaryan et al:)"电介质矩形板的超音速扑翼特性:The effects of magneto-aero-hydrodynamic interactions, Journal of Fluids and Structures, 2023":磁-气-流体动力学相互作用的影响 "介绍了完全导电超音速气流流线型各向同性介质板的线性和非线性扑动行为,并将其浸入纵向磁场中。假定流动液体为无粘性、非导热液体,具有无限传导性。首次提出了考虑到外加磁场的空气动力压力的分析表达式。该表达式概括了活塞理论公式,以考虑磁场相互作用。根据气动磁翻腾的线性问题,得到了稳定条件,并找到了相应的稳定边界。通过分析描述,研究了不同几何参数和不同磁场参数下磁场对临界速度的影响。同时还研究了模式数对临界扑翼速度的影响。利用作用在主体上的力的表达式和薄柔性板的理论,得到了描述板的振动和稳定性的方程组。在解决了所提出的边界值问题后,研究了磁场和流体对非线性扑动式振荡存在的定性和定量影响,以及在流体值固定的情况下振荡幅度对频率的依赖性。本研究在研究主题上与之前的研究有所不同。科学文献中有许多研究自然振荡和强迫振荡的振幅-频率相关性。本文致力于填补这一空白,研究磁场对超音速扑翼非线性特性的影响,即对非线性扑翼振荡的振幅-速度依赖性的影响。
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