Reduced-Order Modeling of Extreme Speed Turbochargers

Volume 6: Ceramics and Ceramic Composites; Coal, Biomass, Hydrogen, and Alternative Fuels; Microturbines, Turbochargers, and Small Turbomachines Pub Date : 2021-06-07 DOI:10.1115/gt2021-58759

D. Fellows, D. Bodony, R. Mcgowan

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Abstract

In order to improve their efficiency and performance, aircraft intermittent combustion engines often incorporate turbochargers that are adapted from ground-based applications. These turbochargers experience conditions outside of their design operating envelope and are found to experience high-cycle fatigue brought on by aerodynamically-induced blade resonances. The onset of fluid-structural interactions, such as flutter and forced response, in turbochargers at these conditions has not been extensively studied. A reduced-order model of the aeroelastic response of the turbine is developed using the Euler-Lagrange equation informed by numerical data from uncoupled computational fluid dynamic (CFD) and computational structural dynamic (CSD) calculations. The structural response of the reduced-order model is derived from a method of assumed modes approach. The unsteady fluid response is described by a modified version of piston theory as a first step towards including inhomogeneous aerodynamic forcing. Details of the reduced order model are given. The capability of the reduced-order model to predict the presence of flutter from a subset of the uncoupled numerical simulation data is discussed.

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超高速涡轮增压器的降阶建模

为了提高它们的效率和性能，飞机间歇燃烧发动机通常采用从地面应用改编的涡轮增压器。这些涡轮增压器在其设计工作包线之外的条件下会经历空气动力诱导的叶片共振带来的高周疲劳。在这些条件下，涡轮增压器的颤振和强迫响应等流固相互作用的发生尚未得到广泛研究。利用非耦合计算流体动力学(CFD)和计算结构动力学(CSD)的数值数据，利用欧拉-拉格朗日方程建立了涡轮气动弹性响应的降阶模型。采用假设模态法推导了降阶模型的结构响应。非定常流体响应是用一种改进的活塞理论来描述的，这是包括非均匀气动力的第一步。给出了降阶模型的细节。讨论了降阶模型从非耦合数值模拟数据子集中预测颤振存在的能力。

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Volume 6: Ceramics and Ceramic Composites; Coal, Biomass, Hydrogen, and Alternative Fuels; Microturbines, Turbochargers, and Small Turbomachines

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