Deep Reinforcement Learning Enables Conceptual Design of Processes for Separating Azeotropic Mixtures Without Prior Knowledge

45 Pages Posted: 28 Mar 2024

See all articles by Quirin Göttl

Quirin Göttl

affiliation not provided to SSRN

Jonathan Pirnay

affiliation not provided to SSRN

Jakob Burger

Technische Universität München (TUM)

Dominik G. Grimm

Technische Universität München (TUM)

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. We further develop those concepts and present a general deep reinforcement learning approach for flowsheet synthesis. We demonstrate the adaptability of an agent to the general task of separating binary azeotropic mixtures. The agent is trained to set up the discrete process topology alongside choosing continuous specifications for the individual unit operations. Without prior knowledge, it learns within one training cycle to craft flowsheets for multiple chemical systems, considering different feed compositions and conceptual approaches. The agent discovers autonomously fundamental process engineering paradigms as azeotropic distillation or entrainer distillation.

Keywords: Automated Process Synthesis, Reinforcement Learning, Conceptual Design, Process Simulation

Suggested Citation

Göttl, Quirin and Pirnay, Jonathan and Burger, Jakob and Grimm, Dominik G., Deep Reinforcement Learning Enables Conceptual Design of Processes for Separating Azeotropic Mixtures Without Prior Knowledge. Available at SSRN: https://ssrn.com/abstract=4776784 or http://dx.doi.org/10.2139/ssrn.4776784

Quirin Göttl (Contact Author)

affiliation not provided to SSRN ( email )

No Address Available

Jonathan Pirnay

affiliation not provided to SSRN ( email )

No Address Available

Jakob Burger

Technische Universität München (TUM) ( email )

Dominik G. Grimm

Technische Universität München (TUM) ( email )

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