Abstract
Manufacturing process optimisation usually amounts to searching optima in high-dimensional parameter spaces. In industrial practice, this search is most often directed by human-subjective expert judgment and trial-and-error experiments. In contrast, high-fidelity simulation models in combination with general-purpose optimisation algorithms, e.g. finite element models and evolutionary algorithms, enable a methodological, virtual process exploration and optimisation. However, reliable process models generally entail significant computation times, which often renders classical, iterative optimisation impracticable. Thus, efficiency is a key factor in optimisation. One option to increase efficiency is surrogate-based optimisation (SBO): SBO seeks to reduce the overall computational load by constructing a numerically inexpensive, data-driven approximation („surrogate“) of the expensive simulation. Traditionally, classical regression techniques are applied for surrogate construction. However, they typically predict a predefined, scalar performance metric only, which limits the amount of usable information gained from simulations. The advent of machine learning (ML) techniques introduces additional options for surrogates: in this work, a deep neural network (DNN) is trained to predict the full strain field instead of a single scalar during textile forming („draping“). Results reveal an improved predictive accuracy as more process-relevant information from the supplied simulations can be extracted. Application of the DNN in an SBO- framework for blank holder optimisation shows improved convergence compared to classical evolutionary algorithms. Thus, DNNs are a promising option for future surrogates in SBO.
Highlights
Optimum operation of production lines in terms of part quality, cycle time or cost generally requires diligent parameterisation of manufacturing processes
This work investigates the effect of different surrogate strategies at the example of artificial neural networks (ANNs)
This work examines the use of deep neural networks as surrogate models in virtual manufacturing process optimisation at the example of gripper-assisted textile forming
Summary
Optimum operation of production lines in terms of part quality, cycle time or cost generally requires diligent parameterisation of manufacturing processes. Identification of such optimum parameters during production ramp-up usually involves many time and resource-intensive experimental trials and experiential expert judgment. An entirely experimental optimisation rapidly becomes cumbersome. This holds all the more for complex processes and delicate materials, e.g. such as technical textiles used in fibre-reinforced components. In combination with general-purpose optimisation algorithms, e.g. evolutionary algorithms [1], they provide options to systematically and reliably optimise manufacturing. Often termed “virtual process optimisation”, such approaches may help determine promising parameters prior to actual experimental trials. [2], reliable models typically require considerable computation times of e.g. hours and days.
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