The response of embedded FBG sensors to non-uniform strains in CFRP composites during processing and delamination

From airplanes to sailboats to bridges, composite materials have become a significant part of our everyday structures. With increasing demand, these materials are pushed to their limits to improve structural efficiency. As a consequence, research and development must continually improve products and provide support for the end user who will need to know the characteristics of their new material. Progress made in the area of optical fibre sensing has opened new avenues for measuring and monitoring fibre-reinforced polymer (FRP) composites, since they can be embedded directly into the composite during manufacturing. These globally noninvasive sensors can provide internal strain and temperature measurements from the moment processing starts until the final failure of the part. The goal of this research is to develop and demonstrate fibre optic sensing techniques that can characterize the internal strain state of FRP composites. In particular, this work focuses on measuring three-dimensional, non-uniform strain fields in carbon fibre-reinforced polymers (CFRP) using fibre Bragg grating (FBG) sensors. Although FBG sensors are becoming widespread for simple uniaxial strain measurements, their response to complex, non-homogeneous strain fields is still difficult to interpret. To illustrate advances in both experimental techniques and the interpretation of measured FBG data, two main areas of composite monitoring are addressed. They include the study of residual strain evolution and of delamination cracking, which both produce non-homogeneous strain fields. Unidirectional carbon fibre-reinforced polyphenylene sulphide (AS4/PPS) laminates are observed during processing to measure residual strain progression, and then later subjected to Mode I double cantilever beam delamination tests. These thermoplastic composite specimens are also produced in a cross-ply configuration, for the purpose of residual strain monitoring. In each laminate, a long-gauge length (20-35 mm) FBG is embedded parallel to the reinforcing fibres, and centred along the length of the plate. Results of polarization sensitive FBG monitoring indicate characteristic material state changes such as the glass-transition and the melting temperatures. These measurements take advantage of both the transverse and longitudinal strain sensitivity of the FBG. When transverse strains are unequal they induce birefringence in the FBG (defining a fast and a slow axis), which results in a split of the normally bell-shaped reflected spectrum. An evolution of this birefringence is monitored during cooling, culminating in average residual transverse strain differences in the embedded FBGs of 230 με and 410 με for unidirectional and cross-ply specimens respectively. Based on the wavelengths measured along the fast polarization axis of the fibre, (observed to be less sensitive to transverse strains) cross-ply specimens exhibit absolute longitudinal residual strains in the order of -350 με. Small longitudinal st