A Study of Ultra-Thin Surface-Mounted MEMS Fibre-Optic Fabry–Pérot Pressure Sensors for the In Situ Monitoring of Hydrodynamic Pressure on the Hull of Large Amphibious Aircraft

A Study of Ultra-Thin Surface-Mounted MEMS Fibre-Optic Fabry–Pérot Pressure Sensors for the In Situ Monitoring of Hydrodynamic Pressure on the Hull of Large Amphibious Aircraft

Hydrodynamic slamming loads during water landing are one of the main concerns for the structural design and wave resistance performance of large amphibious aircraft. However, current existing sensors are not used for full-scale hydrodynamic load flight tests on complex models due to their large size...

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Bibliographic Details
Main Authors: Tianyi Feng, Xi Chen, Ye Chen, Bin Wu, Fei Xu, Lingcai Huang
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Photonics
Subjects:
large amphibious aircraft
micro-electromechanical systems (MEMSs)
Fabry–Pérot
pressure sensors
hydrodynamic pressure monitoring
water-entry test
Online Access:https://www.mdpi.com/2304-6732/12/7/627
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Summary:Hydrodynamic slamming loads during water landing are one of the main concerns for the structural design and wave resistance performance of large amphibious aircraft. However, current existing sensors are not used for full-scale hydrodynamic load flight tests on complex models due to their large size, fragility, intrusiveness, limited range, frequency response limitations, accuracy issues, and low sampling frequency. Fibre-optic sensors’ small size, immunity to electromagnetic interference, and reduced susceptibility to environmental disturbances have led to their progressive development in maritime and aeronautic fields. This research proposes a novel hydrodynamic profile encapsulation method using ultra-thin surface-mounted micro-electromechanical system (MEMS) fibre-optic Fabry–Pérot pressure sensors (total thickness of 1 mm). The proposed sensor exhibits an exceptional linear response and low-temperature sensitivity in hydrostatic calibration tests and shows superior response and detection accuracy in water-entry tests of wedge-shaped bodies. This work exhibits significant potential for the in situ monitoring of hydrodynamic loads during water landing, contributing to the research of large amphibious aircraft. Furthermore, this research demonstrates, for the first time, the proposed surface-mounted pressure sensor in conjunction with a high-speed acquisition system for the in situ monitoring of hydrodynamic pressure on the hull of a large amphibious prototype. Following flight tests, the sensors remained intact throughout multiple high-speed hydrodynamic taxiing events and 12 full water landings, successfully acquiring the complete dataset. The flight test results show that this proposed pressure sensor exhibits superior robustness in extreme environments compared to traditional invasive electrical sensors and can be used for full-scale hydrodynamic load flight tests.
ISSN:2304-6732

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