Abstract
Fiber Bragg grating (FBG) temperature sensors are embedded in composites to detect localized temperature gradients resulting from high energy infrared laser radiation. The goal is to detect the presence of radiation on a composite structure as rapidly as possible and to identify its location, much the same way human skin senses heat. A secondary goal is to determine how a network of sensors can be optimized to detect thermal damage in laser-irradiated composite materials or structures. Initial tests are conducted on polymer matrix composites reinforced with either carbon or glass fiber with a single optical fiber embedded into each specimen. As many as three sensors in each optical fiber measure the temporal and spatial thermal response of the composite to high energy radiation incident on the surface. Additional tests use a 2 × 2 × 3 array of 12 sensors embedded in a carbon fiber/epoxy composite to simultaneously measure temperature variations at locations on the composite surface and through the thickness. Results indicate that FBGs can be used to rapidly detect temperature gradients in a composite and their location, even for a direct strike of laser radiation on a sensor, when high temperatures can cause a non-uniform thermal response and FBG decay.
Highlights
Optical fiber sensors provide a number of advantages for sensing either temperature or strain in polymer matrix composites
Arrays of Fiber Bragg grating (FBG) sensors were used to characterize the thermal conductivity and absorptivity of carbon fiber and E-glass fiber/epoxy composites based on their response to the localized temperature gradient caused by the laser radiation
The material-dependent response is important, for example, laser radiation was detected more rapidly by sensors embedded in a carbon fiber/epoxy composite than in an E-glass fiber/epoxy composite [19], so that fewer sensors would be needed per unit area in materials with higher thermal conductivity
Summary
Optical fiber sensors provide a number of advantages for sensing either temperature or strain in polymer matrix composites They are relatively nonintrusive, lightweight, and flexible. Fiber Bragg grating (FBG) sensors, in particular, can be used to accurately detect localized perturbations in strain and temperature with a high degree of spatial resolution due to their compact size [4,5] This makes them especially attractive for structural health monitoring in polymer matrix composites to detect flames, radiation, or damage [6,7,8]. The emphasis of this study is to determine the speed at which standard embedded FBG temperature sensors detect the temporal and spatial thermal response of a composite material or structure when high energy radiation is incident on the surface. Advanced signal processing may be needed to quickly isolate a laser-induced thermal response of an irradiated composite from mechanical strain
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