New manufacturing techniques such as 3D printing have recently enabled the creation of previously infeasible chemical reactor designs. Optimizing the geometry of the next generation of chemical reactors is important to understand the underlying physics and to ensure reactor feasibility in the real world. This optimization problem is computationally expensive, nonlinear, and derivative-free making it challenging to solve. In this work, we apply deep Gaussian processes (DGPs) to model multi-fidelity coiled-tube reactor simulations in a Bayesian optimization setting. By applying a multi-fidelity Bayesian optimization method, the search space of reactor geometries is explored through an amalgam of different fidelity simulations which are chosen based on prediction uncertainty and simulation cost, maximizing the use of computational budget. The use of DGPs provides an end-to-end model for five discrete mesh fidelities, enabling less computational effort to gain good solutions during optimization. The accuracy of simulations for these five fidelities is determined against experimental data obtained from a 3D printed reactor configuration, providing insights into appropriate hyper-parameters. We hope this work provides interesting insight into the practical use of DGP-based multi-fidelity Bayesian optimization for engineering discovery.
翻译:3D 印刷等新制造技术最近促成了以前不可行的化学反应堆设计。优化下一代化学反应堆的几何测量对于理解基础物理和确保反应堆在现实世界的可行性非常重要。优化问题在计算上成本昂贵、非线性和无衍生物性,因此难以解决。在这项工作中,我们运用深高山流程(DGPs)在巴伊西亚优化环境中模拟多纤维性共闭式反应堆模拟。通过应用多纤维性贝叶西亚优化法,通过根据预测不确定性和模拟成本选择不同的忠实性模拟来探索反应堆地貌的搜索空间,最大限度地利用计算预算。DGPs为五个离散的精密性提供了端对端模型,使较少的计算努力能够在优化过程中获得良好的解决方案。根据从3D 印刷反应堆配置中获得的实验数据,为适当的超离子体优化提供深刻的洞察力。我们希望DGPS的探索能为Bay工程提供有趣的洞察力。