Design-oriented dynamic model of deployable fin under time-varying elevated temperature environment

H. Ren, Y. Wang, L. Wang, J.B. Zhou, H.J. Chang, Y. Cai, B. Lei
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Abstract

Coupling of clearance joint and harsh aerodynamic heating environment is an inevitable nonlinear factor in folding mechanism of the fin of high-speed aircrafts that remarkably modifies natural frequencies and modes of vibration from the initial design state. However, accurately predicting dynamic properties of deployable fin with full consideration of these effects is not common industry practice. A practical semi-analytical model based on Hertz contact theory and ESDU-78035 model is proposed in this study to investigate high-temperature connection stiffness of local hinged–locked mechanisms. Material property degradation and clearance variation caused by thermal expansion are comprehensively considered and quantified in this model. Vibration characteristics of the assembled deployable fin are then solved using finite element method (FEM). The real-time evolutionary process of thermal mode of the fin is discussed. And natural frequencies of fixed-value and time-varying connection stiffness are compared. The simulation results of this study demonstrate that the relative error of structure temperature between the sequential approach and fully coupled simulations is less than 6.98%. The connection stiffness (slope of the load-displacement curve) of the folding mechanism under high temperature conditions decreases by 3.52%, and the variation is mainly caused by the degradation of the elastic modulus of the material, while the clearance change due to the thermal expansion has no significant effect on the slope. The natural frequency of the deployable fin exhibits an inverse correlation with the temperature change trend, and the first three frequencies decrease by 1.67, 7.75, and 16.28 Hz compared to the initial value, respectively.
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时变高温环境下面向设计的可展开鳍动态模型
间隙接头与恶劣气动加热环境的耦合是高速飞机机翼折叠机构中不可避免的非线性因素,它显著地改变了机翼固有频率和振型。然而,在充分考虑这些影响的情况下,准确预测可展开鳍的动态特性并不是常见的行业实践。基于Hertz接触理论和ESDU-78035模型,提出了一种实用的半解析模型来研究局部铰锁机构的高温连接刚度。该模型综合考虑并量化了热膨胀引起的材料性能退化和间隙变化。然后用有限元法求解了组合展开鳍的振动特性。讨论了翅片热模态的实时演化过程。并对固定值连接刚度和时变连接刚度的固有频率进行了比较。仿真结果表明,序贯方法与全耦合模拟的结构温度相对误差小于6.98%。高温条件下折叠机构的连接刚度(荷载-位移曲线斜率)降低了3.52%,这种变化主要是由于材料弹性模量的退化造成的,而热膨胀引起的间隙变化对斜率没有显著影响。展开鳍的固有频率与温度变化趋势呈负相关,前三个频率分别比初始值降低了1.67、7.75和16.28 Hz。
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