Laura Stops scite author profile

Process synthesis experiences a disruptive transformation accelerated by artificial intelligence. We propose a reinforcement learning algorithm for chemical process design based on a state-of-the-art actor-critic logic. Our proposed algorithm represents chemical processes as graphs and uses graph convolutional neural networks to learn from process graphs. In particular, the graph neural networks are implemented within the agent architecture to process the states and make decisions. We implement a hierarchical and hybrid decision-making process to generate flowsheets, where unit operations are placed iteratively as discrete decisions and corresponding design variables are selected as continuous decisions. We demonstrate the potential of our method to design economically viable flowsheets in an illustrative case study comprising equilibrium reactions, azeotropic separation, and recycles. The results show quick learning in discrete, continuous, and hybrid action spaces. The method is predestined to include large action-state spaces and an interface to process simulators in future research.

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Reduced order modeling of a pressure column of an air separation unit using the Dynamic Edmister Method

Kender

Stops

Krespach

et al. 2023

Computers & Chemical Engineering

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Flowsheet synthesis through hierarchical reinforcement learning and graph neural networks

Stops¹,

Roel²,

Gao³

et al. 2022

Preprint

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Process synthesis experiences a disruptive transformation accelerated by digitization and artificial intelligence. We propose a reinforcement learning algorithm for chemical process design based on a state-of-the-art actor-critic logic. Our proposed algorithm represents chemical processes as graphs and uses graph convolutional neural networks to learn from process graphs. In particular, the graph neural networks are implemented within the agent architecture to process the states and make decisions. Moreover, we implement a hierarchical and hybrid decision-making process to generate flowsheets, where unit operations are placed iteratively as discrete decisions and corresponding design variables are selected as continuous decisions. We demonstrate the potential of our method to design economically viable flowsheets in an illustrative case study comprising equilibrium reactions, azeotropic separation, and recycles. The results show quick learning in discrete, continuous, and hybrid action spaces. Due to the flexible architecture of the proposed reinforcement learning agent, the method is predestined to include large action-state spaces and an interface to process simulators in future research.

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Simulation of heat and mass transfer in a random packed column operated as a cooling tower using the TUM-WelChem cell model

Winkler

Stops

Siebe

et al. 2022

Chemical Engineering Research and Design

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Laura Stops

Flowsheet generation through hierarchical reinforcement learning and graph neural networks

Reduced order modeling of a pressure column of an air separation unit using the Dynamic Edmister Method

Flowsheet synthesis through hierarchical reinforcement learning and graph neural networks

Simulation of heat and mass transfer in a random packed column operated as a cooling tower using the TUM-WelChem cell model

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