Abstract EN:

Behaviour in creep and identification of the damage mechanisms of composite materials as glass/polyester unidirectional, with cross ply and SMC (sheet moulding compound), are studied in situ by acoustic emission (AE) and ultrasounds. The analysis of the signals of AE made it possible for certain materials to identify the damage mechanisms. The follow-up of the mechanical properties in creep through the longitudinal ultrasonic velocity is measured in situ. The loss of stiffness determined from ultrasonic velocity measurements observed and its good correlation with the AE testify to the capacity of the two methods to follow the damage and consolidate the idea of a global solution for health control of materials. In addition, we observed during primary creep a relaxation in power law (Andrade’s law) for the strain rate and AE rate (Omori’s law). Tertiary creep as for it, is characterized by a singularity in power law of the strain rates and AE culminating with the total rupture of materials. Interesting correlations were observed between some characteristics of the primary creep and tertiary regime, in particular between the time of rupture tc and the transition time of primary, secondary and tertiary creep tm. This significant result shows the bonds between the two modes and makes it possible to consider a means of prediction of the rupture. These experimental results are supported by a model derived from the democratic model of fibres called DFBM (Democratic fibre bundle model) in which the material is represented by a series of elements constituted of a spring assembled in parallel with a nonlinear shock absorber of viscosity of Eyring type. This model permits to explain the correlation between tc and tm and makes it possible to find again relaxation with andrade law in primary creep and the singularity of power law in tertiary creep with critical exponents of the same order as those observed in experiments.