English

Deep reinforcement learning uncovers processes for separating azeotropic mixtures without prior knowledge

Machine Learning 2023-10-11 v1

Abstract

Process synthesis in chemical engineering is a complex planning problem due to vast search spaces, continuous parameters and the need for generalization. Deep reinforcement learning agents, trained without prior knowledge, have shown to outperform humans in various complex planning problems in recent years. Existing work on reinforcement learning for flowsheet synthesis shows promising concepts, but focuses on narrow problems in a single chemical system, limiting its practicality. We present a general deep reinforcement learning approach for flowsheet synthesis. We demonstrate the adaptability of a single agent to the general task of separating binary azeotropic mixtures. Without prior knowledge, it learns to craft near-optimal flowsheets for multiple chemical systems, considering different feed compositions and conceptual approaches. On average, the agent can separate more than 99% of the involved materials into pure components, while autonomously learning fundamental process engineering paradigms. This highlights the agent's planning flexibility, an encouraging step toward true generality.

Keywords

Cite

@article{arxiv.2310.06415,
  title  = {Deep reinforcement learning uncovers processes for separating azeotropic mixtures without prior knowledge},
  author = {Quirin Göttl and Jonathan Pirnay and Jakob Burger and Dominik G. Grimm},
  journal= {arXiv preprint arXiv:2310.06415},
  year   = {2023}
}

Comments

36 pages, 7 figures, 4 tables. G\"ottl and Pirnay contributed equally as joint first authors. Burger and Grimm contributed equally as joint last authors

R2 v1 2026-06-28T12:45:38.388Z