"The project work has included a characterization campaign for an epoxy system suitable for out of autoclave manufacture of aircraft composites. This was done to obtain material data to use in simulation subroutines developed during the project.
The first portion of the project refined and improved a high-fidelity simulation code for residual stress analysis previously developed in-house. The effect of the changing modulus during the rubbery stages of the matrix curing was included. These code used to develop a method for rapid cure distortion analysis based on linear analysis using equivalent properties. This ""rapid method"" has so far led to one conference publication (ECCM18, Athens), and one manuscript for submission to a scientific journal. In addition, portions of the work have been discussed directly with other research groups around the world working on similar problems, in addition to popular science presentations in Sweden.
Manufacturing was also performed to create small coupons, and large parts for validation. Distortions were measured with a high accuracy laser scanning system and compared to the simulation results. The accuracy of the two modelling approaches were examined in detail. In both cases, good agreement between simulated distortions and measured distortions were observed, however there was a large amount of scatter in the results from manufacturing. The materials and manufacturing methods used proved impossible to obtain the level of precision and manufacturing tolerance associated with prepreg manufacture in an autoclave. Evaluation of the distortion of the components also required quite detailed study of the laser scanning results, due to the tendency of e.g. local curvatures to confound typical measurements of angles etc.
In the second half of the project, a method for optimization of the shape and layup of the composite parts was developed. A new metric to measure the distortion severity was developed which accounts for displacement and local stiffness in the model. A novel stacking sequence generation algorithm was developed to create a composite stack based on ratios of allowed orientations, and some basic design rules from industry. These tools were implemented in python scripts to work with Abaqus CAE.
In addition, a toolbox to interface between CAD and CAE software was developed. This allowed a parameterized CAD model to be included directly in the optimization loop. This means the native geometry CAD model could be updated with a few clicks in the software post optimization. This reduces design time caused by iterations between CAD and FEA specialists.
The complete set of tools were finally demonstrated on a used case part. A large, stiffened panel assembly was optimized to minimize distortion while simultaneously maintaining minimum buckling load factor constraints.
The work has led to one conference presentation, and two manuscripts for submission to academic journals. In addition, publications in social media, popular science articles and presentations have been part of the dissemination. Further, discussions to incorporate and market the tools in future projects is ongoing."