A model for predicting the effect of deformation after solution treatment on the subsequent artificial aging behavior of AA7030 and AA7108 alloys

The effect of deformation after solution treatment on the two-step artificial aging response has been examined for AA7030 and AA7108 alloys. Aging experiments were conducted where the prestrain level was varied between 0 and 1.2. It was observed that the kinetics of aging were accelerated and the magnitude of the peak strength decreased in the presence of prestrain. This was attributed to the increased growth/coarsening rate of precipitates on dislocations and the widening of the precipitate-size distribution, respectively. A model was developed based on the internal state variable approach to predict yield stress as a function of the heat treatment and the level of prestrain. The increase in the kinetics of aging was accounted for in an average sense by the use of an effective diffusion coefficient that combines bulk and short-circuit diffusion. The precipitation model was based on two variables; the average spacing between precipitates and the average strength of precipitates. The variation of the average strength of precipitates with precipitate radius was varied to account for the change in the width of the precipitate-size distribution. Static recovery of the deformed structure during artificial aging was also accounted for in a first-order approximation. Good agreement was found between the model predictions and experimental results. Additional experimental data were obtained after the model was developed, and it was observed that the model made excellent predictions.