气体压缩机
振动
声学
激光多普勒测速
航空发动机
刀(考古)
激光扫描测振法
喷气发动机
激光多普勒测振仪
材料科学
激光器
工程类
机械工程
光学
物理
激光束
内科学
血流
医学
作者
Mohammed Lamine Mekhalfia,Pavel Procházka,Radislav Šmíd,Elizaveta Voronova,Robert Hodbod’,Peter Russhard,Dušan Maturkanič,Eder Batista Tchawou Tchuisseu
标识
DOI:10.1109/tim.2025.3574912
摘要
Ensuring the structural integrity and operational reliability of aero-engine compressors requires precise vibration measurement of rotating blades. Blade Tip Timing (BTT) is a widely used non-contact measurement technique, but its accuracy is inherently influenced by the blade’s twisted geometry and probe positioning. This study introduces a calibration framework that improves BTT precision by integrating Finite Element (FE) modeling to account for blade geometry and vibration characteristics. By extracting vibration mode shapes from the FE model and converting them into an equivalent measurement plane, this method enhances the reliability of BTT measurements. The calibration is validated using Laser Doppler Vibrometry (LDV), which serves as a high-precision reference in controlled laboratory conditions. Results show that this approach significantly reduces measurement discrepancies from 10% to a range of 2–3%, strengthening BTT’s robustness in industrial applications where LDV is not deployable. Additionally, the study establishes a crucial restriction on sensor positioning near the blade tip, identifying areas where BTT probes may fail to capture meaningful data depending on the mode shape. This work lays the foundation for standardized calibration methodologies in turbomachinery health monitoring, ultimately improving predictive maintenance strategies and diagnostics.
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