Global Engineering and Materials, Inc., along with University of Illinois Urbana-Champaign, Wichita State University, and YB Numerics Inc., proposes to develop an integrated mechanics/data-driven multiphysics framework to predict the time-dependent/space-varying local boundary conditions during autoclave processes of composite parts. A high-fidelity thermal fluid-structure interaction (FSI) model will be developed to determine the local flow, temperature, and pressure for parts in the presence of the thermal-mechanical coupling on bagging-tooling surfaces. An immersogeometric approach will be used for efficient FSI simulations of multiple parts with arbitrary placement directly using parts CAD model to capture the flow-part interaction with a universal fluid mesh. The spatial-temporal distribution of heat fluxes on the part surface will be included in the FSI model. Actual autoclave runs will be performed using single and multiple parts with in-situ sensors to measure the local/remote flow and temperature for model validation and physics-informed data fusion to further improve the models accuracy and fidelity. The validated framework can quickly and reliably evaluate the local boundary conditions and intelligently place multiple parts to achieve the correct cure profile. It paves the way towards the teams ultimate goal to achieve: efficient, optimized, and adjustable autoclave processes by building a multiphysics simulation-based dynamic control system.
Benefit: The research will result in a versatile, user-friendly, and computationally efficient toolkit for virtual simulation of local environmental conditions in an autoclave with multiple parts to maximize the throughput with the correct cure profile of each part. The toolkit will allow composite manufacturers to determine the optimal manufacturing procedures to reduce the trial-and-error testing required to develop the recipes for each unique combination of autoclave and part batch. The developed physics-based data fusion process can provide an accelerated insertion of an active loop to control the processing parameters via the collected data from the in-situ sensors such as pressure transducers, thermocouples, and vacuum gauges. The developed toolkit can be linked with other physics models to describe cure kinetics, cure history-dependent viscoelastic constitutive relations, the micromechanics model, and progressive damage analysis with a given distribution of fabrication-induced defects. The integrated technology will also allow composite manufacturers to determine the optimal manufacturing procedures to minimize process-induced defects and variations while significantly reducing the trial-and-error testing on expensive physical prototyping. This will enable faster design and process validation and verification, leading to low development costs and adding the values of lightweight, high-performance composites to a long-term production cycle.
Keywords: fluid-structure interaction, fluid-structure interaction, Autoclave processing, Thermal-Mechanical Coupling, Immersogeometric Analysis, date fusion, In-Situ Sensors
