Numerical Simulations and Experimental Validation of Squeeze Film Dampers for Aircraft Jet Engines

IF 3.1 3区工程技术 Q2 ENGINEERING, MECHANICAL

Lubricants Pub Date : 2024-07-13 DOI:10.3390/lubricants12070253

Markus Golek, Jakob Gleichner, Ioannis Chatzisavvas, Lukas Kohlmann, Marcus Schmidt, Peter Reinke, Adrian Rienäcker

引用次数: 0

Abstract

Squeeze film dampers are used to reduce vibration in aircraft jet engines supported by rolling element bearings. The underlying physics of the squeeze film dampers has been studied extensively over the past 50 years. However, the research on the SFDs is still ongoing due to the complexity of modeling of several effects such as fluid inertia and the modeling of the piston rings, which are often used to seal SFDs. In this work, a special experimental setup has been designed to validate the numerical models of SFDs. This experimental setup can be used with various SFD geometries (including piston ring seals) and simulate almost all conditions that may occur in an aircraft jet engine. This work also focuses on the inertia forces of the fluid. The hydrodynamic pressure distribution of a detailed 3D-CFD model is compared with the solution of the Reynolds equation including inertia effects. Finally, the simulation results are compared with experimental data and good agreement is observed.

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飞机喷气发动机挤压薄膜阻尼器的数值模拟和实验验证

挤压膜阻尼器用于减少由滚动轴承支撑的飞机喷气发动机的振动。在过去的 50 年中，人们对挤压膜阻尼器的基本物理原理进行了广泛的研究。然而，由于流体惯性和活塞环（通常用于密封 SFD）等几种效应建模的复杂性，有关 SFD 的研究仍在进行中。在这项工作中，设计了一种特殊的实验装置来验证 SFD 的数值模型。该实验装置可用于各种 SFD 几何结构（包括活塞环密封），并可模拟飞机喷气发动机中可能出现的几乎所有情况。这项工作还侧重于流体的惯性力。详细 3D-CFD 模型的流体动力压力分布与包含惯性效应的雷诺方程的解法进行了比较。最后，将模拟结果与实验数据进行了比较，结果表明两者吻合良好。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Lubricants Engineering-Mechanical Engineering

CiteScore

3.60

自引率

25.70%

发文量

293

审稿时长

11 weeks

期刊介绍： This journal is dedicated to the field of Tribology and closely related disciplines. This includes the fundamentals of the following topics: -Lubrication, comprising hydrostatics, hydrodynamics, elastohydrodynamics, mixed and boundary regimes of lubrication -Friction, comprising viscous shear, Newtonian and non-Newtonian traction, boundary friction -Wear, including adhesion, abrasion, tribo-corrosion, scuffing and scoring -Cavitation and erosion -Sub-surface stressing, fatigue spalling, pitting, micro-pitting -Contact Mechanics: elasticity, elasto-plasticity, adhesion, viscoelasticity, poroelasticity, coatings and solid lubricants, layered bonded and unbonded solids -Surface Science: topography, tribo-film formation, lubricant–surface combination, surface texturing, micro-hydrodynamics, micro-elastohydrodynamics -Rheology: Newtonian, non-Newtonian fluids, dilatants, pseudo-plastics, thixotropy, shear thinning -Physical chemistry of lubricants, boundary active species, adsorption, bonding