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用于斜激波边界层相互作用非定常性研究的丝网印刷聚偏氟乙烯压电压力传感器

Screen-Printed PVDF Piezoelectric Pressure Transducer for Unsteadiness Study of Oblique Shock Wave Boundary Layer Interaction.

作者信息

Wang Bei, Corsi Cosimo, Weiland Thomas, Wang Zhenyu, Grund Thomas, Pohl Olaf, Bienia Johannes Max, Weiss Julien, Ngo Ha Duong

机构信息

Department of Microsystem Technology, University of Applied Sciences Berlin, 12459 Berlin, Germany.

Department of Aerodynamics Engineer, Technical University of Berlin, 10587 Berlin, Germany.

出版信息

Micromachines (Basel). 2024 Nov 27;15(12):1423. doi: 10.3390/mi15121423.

DOI:10.3390/mi15121423
PMID:39770177
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11676075/
Abstract

Shock wave boundary/layer interactions (SWBLIs) are critical in high-speed aerodynamic flows, particularly within supersonic regimes, where unsteady dynamics can induce structural fatigue and degrade vehicle performance. Conventional measurement techniques, such as pressure-sensitive paint (PSP), face limitations in frequency response, calibration complexity, and intrusive instrumentation. Similarly, MEMS-based sensors, like Kulite sensors, present challenges in terms of intrusiveness, cost, and integration complexity. This study presents a flexible, lightweight polyvinylidene fluoride (PVDF) piezoelectric sensor array designed for high-resolution wall-pressure measurements in SWBLI research. The primary objective is to optimize low-frequency pressure fluctuation detection, addressing SWBLI's need for accurate, real-time measurements of low-frequency unsteadiness. Fabricated using a double-sided screen-printing technique, this sensor array is low-cost, flexible, and provides stable, high-sensitivity data. Finite Element Method (FEM) simulations indicate that the sensor structure also has potential for high-frequency responses, behaving as a high-pass filter with minimal signal attenuation up to 300 kHz, although the current study's experimental testing is focused on low-frequency calibration and validation. A custom low-frequency sound pressure setup was used to calibrate the PVDF sensor array, ensuring uniform pressure distribution across sensor elements. Wind tunnel tests at Mach 2 verified the PVDF sensor's ability to capture pressure fluctuations and unsteady behaviors consistent with those recorded by Kulite sensors. The findings suggest that PVDF sensors are promising alternatives for capturing low-frequency disturbances and intricate flow structures in advanced aerodynamic research, with high-frequency performance to be further explored in future work.

摘要

冲击波边界层相互作用(SWBLIs)在高速空气动力学流动中至关重要,特别是在超音速状态下,其中不稳定的动力学可能会导致结构疲劳并降低飞行器性能。传统的测量技术,如压敏漆(PSP),在频率响应、校准复杂性和侵入性仪器方面存在局限性。同样,基于MEMS的传感器,如Kulite传感器,在侵入性、成本和集成复杂性方面也存在挑战。本研究提出了一种灵活、轻便的聚偏二氟乙烯(PVDF)压电传感器阵列,专为SWBLI研究中的高分辨率壁面压力测量而设计。主要目标是优化低频压力波动检测,满足SWBLI对低频不稳定进行准确、实时测量的需求。该传感器阵列采用双面丝网印刷技术制造,成本低、灵活性高,并能提供稳定、高灵敏度的数据。有限元方法(FEM)模拟表明,该传感器结构在高频响应方面也具有潜力,在高达300 kHz的频率下表现为高通滤波器,信号衰减最小,尽管本研究的实验测试集中在低频校准和验证上。使用定制的低频声压装置对PVDF传感器阵列进行校准,确保传感器元件上的压力分布均匀。在马赫数为2的风洞试验中,验证了PVDF传感器捕捉压力波动和不稳定行为的能力,与Kulite传感器记录的结果一致。研究结果表明,PVDF传感器是在先进空气动力学研究中捕捉低频扰动和复杂流动结构的有前途的替代方案,其高频性能将在未来的工作中进一步探索。

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