Abstract
Optical fibre sensors are being investigated since many years as candidates of choice for supporting structural health monitoring (SHM) in aerospace applications. Fibre Bragg grating (FBG) sensors, more specifically, can provide for accurate strain measurements and therefore return useful data about the mechanical strain state of the structure to which they are attached. This functionality can serve the detection of damage in an aircraft structure. However, very few solutions for protecting and bonding optical fibres to a state-of-the-art aircraft composite material have been reported. Most proof-of-principle demonstrations using optical fibre sensors for aerospace SHM-related applications reported in literature indeed rely on unpackaged fibre sensors bonded to isotropic metallic surfaces in a mostly unspecified manner. Neither the operation of the sensor, nor the adhesive material and bonding procedure are tested for their endurance against a full set of standardized in-flight conditions. In this work we propose a specialty coated FBG sensor and its permanent installation on aerospace-grade composite materials, and we demonstrate the compatibility with aerospace in-flight conditions. To do so we thoroughly evaluate the quality of the operation of the FBG sensor by correlating the reflection spectra of the installed sensors before and after exposure to a full set of realistic in-flight conditions. We also evaluate the difference in strain measured by the FBG, since any damage in the adhesive bond line would lead to strain release. The applied test conditions are based on aerospace standards and include temperature cycling, pressure cycling, exposure to humidity and hydraulic fluid and fatigue loading. We show that both the bond line and the quality of the sensor signal were negligibly affected by the applied environmental and mechanical loads representing in-flight conditions and therefore conclude that it can be considered for SHM of aerospace-grade composite materials.
Highlights
Composites are rapidly replacing metals in aerospace structures, essentially owing to their higher stiffness-to-mass ratio
In this work we propose a specialty coated Fibre Bragg grating (FBG) sensor and its permanent installation on aerospace-grade composite materials, and we demonstrate the compatibility with aerospace in-flight conditions
The susceptibility to other environmental in-flight conditions has mostly been disregarded. We address these shortcomings, by proposing a solution based on an optical fibre equipped with draw-tower fibre Bragg gratings (DTG®) and coated with glass fibre reinforced polymer (GFRP) and high-density polyethylene (HDPE), named strain measurement wire (SMW) [18]
Summary
Composites are rapidly replacing metals in aerospace structures, essentially owing to their higher stiffness-to-mass ratio. Their proneness to impact damage calls for frequent inspection, which in its turn increases downtimes and operational costs. Fibre Bragg gratings (FBGs) in particular, have been commonly used as precise and accurate strain sensors. An FBG is a local and periodic refractive index perturbation in the core of a single mode optical fibre that reflects a narrow spectral band centred around the so-called Bragg wavelength. Measuring the wavelength shift allows determining the mechanical strain at the location of the FBG. An accurate measurement of the strain requires adequate quality of the FBG reflection spectrum and suitable signal acquisition hardware as well as adapted data-processing methods
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