Numerical and experimental investigations on the dynamic behavior of a rotor-AMBs system considering shrink-fit assembly

IF 7.9 1区 工程技术 Q1 ENGINEERING, MECHANICAL
Yang Zhou , Yuanping Xu , Jin Zhou , Yue Zhang , Jarir Mahfoud
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引用次数: 0

Abstract

Rotor-Active Magnetic Bearings (rotor-AMBs) systems nowadays have been widely used in turbomachinery where different methods for assembly were used such as impeller mounted using shrink-fit. In our experiments we noticed that the conditions of shrink-ft assembly can introduce instabilities on the levitated rotor at rest. To understand and give recommendations (on the assembly conditions), a numerical model was developed and then was validated experimentally. The effect of the shrink-fit interface contact was modelled as a contact force acting on the rotor-AMBs system introduced by distributed spring units with a given contact stiffness. Considering that there was partial separation in the contact interface due to the AMBs levitating forces, a novel contact force model related to contact status was established by calculating the real-time contact area. A microscopic contact model based on fractal theory was developed to calculate the contact stiffness. The model developed was then validated experimentally simulating the levitating rotor at rest. The rotor response was analyzed in frequency domains by applying the different conditions of shrink-fit interference and contact length. The shrink-fit contact conditions influenced the system stability and made the fourth bending mode unstable. The increase of shrink-fit interference and contact length decreased closed-loop system stability and increased the amplitude of the rotor vibration response. The model reliability was assessed and a stable region using combinations of shrink-fit parameters on the assembly conditions based on the results of stability analysis was established.
考虑收缩装配的转子-AMBs 系统动态行为的数值和实验研究
转子有源磁悬浮轴承(转子-AMB)系统如今已广泛应用于透平机械中,并采用了不同的装配方法,如使用收缩装配法安装叶轮。在我们的实验中,我们注意到缩尺装配条件会给静止时的悬浮转子带来不稳定性。为了了解情况并给出建议(装配条件),我们开发了一个数值模型,然后进行了实验验证。收缩配合界面接触的影响被模拟为转子-AMBs 系统上的接触力,该接触力由给定接触刚度的分布式弹簧单元引入。考虑到 AMBs 悬浮力导致接触界面部分分离,通过计算实时接触面积,建立了与接触状态相关的新型接触力模型。基于分形理论建立的微观接触模型用于计算接触刚度。随后,通过模拟静止状态下的悬浮转子,对所建立的模型进行了实验验证。通过采用不同的收缩配合干涉条件和接触长度,对转子的响应进行了频域分析。收缩接触条件影响了系统的稳定性,使第四弯曲模式变得不稳定。增加收缩配合过盈量和接触长度会降低闭环系统的稳定性,并增加转子振动响应的振幅。对模型的可靠性进行了评估,并根据稳定性分析结果,利用装配条件上的收缩配合参数组合确定了稳定区域。
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来源期刊
Mechanical Systems and Signal Processing
Mechanical Systems and Signal Processing 工程技术-工程:机械
CiteScore
14.80
自引率
13.10%
发文量
1183
审稿时长
5.4 months
期刊介绍: Journal Name: Mechanical Systems and Signal Processing (MSSP) Interdisciplinary Focus: Mechanical, Aerospace, and Civil Engineering Purpose:Reporting scientific advancements of the highest quality Arising from new techniques in sensing, instrumentation, signal processing, modelling, and control of dynamic systems
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