Real-Time Optimization and Control of Nonlinear Processes Using Machine Learning

Machine learning has attracted extensive interest in the process engineering field, due to the capability of modeling complex nonlinear process behavior. This work presents a method for combining neural network models with first-principles models in real-time optimization (RTO) and model predictive...

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Bibliographic Details
Published in:Mathematics (Basel) 2019-10, Vol.7 (10), p.890
Main Authors: Zhang, Zhihao, Wu, Zhe, Rincon, David, Christofides, Panagiotis
Format: Article
Language:English
Subjects:
chemical reactor control
Continuously stirred tank reactors
Distillation
distillation column control
Energy costs
Exothermic reactions
Fault diagnosis
First principles
Industrial applications
Knowledge
Machine learning
model predictive control
Neural networks
Neurons
Nonlinear control
nonlinear processes
Nonlinearity
Optimization
Parameter identification
Phase equilibria
Predictive control
process control
Process controls
Product development
Real time
real-time optimization
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Summary:Machine learning has attracted extensive interest in the process engineering field, due to the capability of modeling complex nonlinear process behavior. This work presents a method for combining neural network models with first-principles models in real-time optimization (RTO) and model predictive control (MPC) and demonstrates the application to two chemical process examples. First, the proposed methodology that integrates a neural network model and a first-principles model in the optimization problems of RTO and MPC is discussed. Then, two chemical process examples are presented. In the first example, a continuous stirred tank reactor (CSTR) with a reversible exothermic reaction is studied. A feed-forward neural network model is used to approximate the nonlinear reaction rate and is combined with a first-principles model in RTO and MPC. An RTO is designed to find the optimal reactor operating condition balancing energy cost and reactant conversion, and an MPC is designed to drive the process to the optimal operating condition. A variation in energy price is introduced to demonstrate that the developed RTO scheme is able to minimize operation cost and yields a closed-loop performance that is very close to the one attained by RTO/MPC using the first-principles model. In the second example, a distillation column is used to demonstrate an industrial application of the use of machine learning to model nonlinearities in RTO. A feed-forward neural network is first built to obtain the phase equilibrium properties and then combined with a first-principles model in RTO, which is designed to maximize the operation profit and calculate optimal set-points for the controllers. A variation in feed concentration is introduced to demonstrate that the developed RTO scheme can increase operation profit for all considered conditions.
ISSN:2227-7390
2227-7390
DOI:10.3390/math7100890