Issue 30

G. Pitarresi et alii, Frattura ed Integrità Strutturale, 30 (2014) 127-137; DOI: 10.3221/IGF-ESIS.30.17 128 Hygroscopic swelling can indeed give rise to important internal stresses when materials interfaces are present, e.g. matrix/fibre, adhesive bonding, electronic packaging, etc. In order to simulate the long-term consequences of water uptake, accelerated aging is usually implemented by increasing the temperature of the conditioning environment, usually consisting of a water bath (hydro-thermal aging) or a controlled humid airborne climate chamber (hygro-thermal aging) [9,10]. The material is then monitored at specific stages by applying a number of physical characterizations, the most common of which are Gravimetric analyses and Dynamic Mechanical Thermal (DMTA) analyses [4]. Based on this approach, several studies are available who have focused on the interactions between the diffusion kinetics and the polymer network structure [1-10]. Some important aspects of the mechanical behavior of aged glassy polymers have though received relatively little attention so far, and in particular the evaluation of the residual internal stresses and strains induced by swelling, and the consequences of the polymer network modifications on the polymer fracture toughness. Regarding the first aspect, only a few experimental approaches have been proposed to determine swelling induced strains, and to quantify the swelling sensitivity of the polymer. An average strain can be measured by a Thermal Mechanical Analyzer (TMA) [11], and then correlated to water concentration to evaluate the Coefficient of Hygroscopic Swelling. This technique though does not take into account the transient non-uniform strain distribution in the sample. Full filed optical techniques such as Moirè Interferometry [7,12] or Digital Image Correlation [13-16] have been also implemented, being able to measure full field in-plain strains simultaneously to water diffusion. Both techniques though require staring at the sample constantly, and are then rather complicate to implement with hydrothermal conditioning. Furthermore, they require some degree of sample surface preparation. Regarding the second aspect of fracture toughness modifications, it is observed that water uptake usually produces a decrease of the Glass Transition temperature, T g , well detected by the DMTA [4,9]. Such increased polymer chain mobility is usually interpreted as a plasticization effect, and as such, it should produce an increase of fracture toughness. A direct verification of this correlation is though rarely found in the literature [9], although fracture toughness parameters for brittle plastics are well characterized by the theory [17], and measurable with standardized procedures [18,19]. Water uptake may also induce some generalized degradation effects in the material, which can counterbalance the plasticization. An example of such unpredictable behavior is the lack of a well established trend about the influence of water uptake on Mode I delamination toughness of FRPs [20]. The literature survey in [20] has also evidenced how most of work on delamination of aged FRPs do not investigate the modifications of fracture toughness in the resin matrix in bulk conditions. The present work implements a Photoelastic Stress Analysis (PSA) technique that is able to measure the evolution of stresses during water diffusion in epoxy materials [21]. Some unique features of the proposed approach include the possibility to directly measure stresses with a very high sensitivity, the fast acquisition of full-field non-contact measurements, and the use of a simple optical setup and low cost equipment [22]. The only restricting requirement is the need for transparency and optical birefringence of the material being tested. PSA is in particular used in this work to investigate the stress field arising in hydrothermally aging cracked samples. These consist of Single Edge Notched Bending (SENB), prepared according to ASTM D5045 [18] for the evaluation of fracture toughness. The material investigated is a model epoxy system, prepared by mixing a DGEBA monomer with an amine DDS curing agent, and cured with an optimized thermal cycle, able to determine a high T g (> 200 °C) and a fully cured and stress free state. The SENB samples have been aged by resting in a water bath at 80 °C, up to a fully saturated condition, achieved after about 1300 hours. A number of characterizations have been performed throughout the aging conditioning, comprising: Gravimetric Analysis, DMTA, PSA and Fracture Toughness tests. PSA in particular was carried out by placing the beam samples into a circular polariscope at regular intervals during aging. Isochromatic maps were acquired in both white and monochromatic light, and a quantitative analysis was carried out by implementing a Tardy Phase-Shifting Method (TPSM) [23]. The extensive characterization has allowed to conclude that the epoxy system increases its intrinsic fracture toughness K IC of about 39% at the fully saturated condition. At the early stages of water absorption the swelling stresses are particularly severe and determine an increase of fracture toughness that is due to compressive stresses settling near the crack tip. M ATERIALS AND METHODS he DGEBA-DDS epoxy analyzed in this work can be considered as a model system due to its widespread consideration in the literature. This base epoxy system is in fact present in many commercial matrix formulations adopted in the composites industry, in particular for the making of high T g matrices and pre-impregnated laminas. T