Distributed Asynchronous Optimization With Inseparable Coupled Constraints and Its Application

Considering the complexity of centralized plant-wide optimization and the presence of communication delay in production units, a distributed asynchronous optimization framework is developed for energy consumption optimization problem during ethylene production. First, the energy consumption optimiza...

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Bibliographic Details
Published in:IEEE transactions on automation science and engineering Vol. 22; pp. 13458 - 13469
Main Authors: Wang, Ting, Liu, Weihan, Li, Zhongmei, Ye, Zhencheng, Peng, Xin, Du, Wenli
Format: Journal Article
Language:English
Published: IEEE 2025
Subjects:
asynchronous algorithm
Automation
constraint node
Convergence
Delay effects
Delays
Distributed optimization
Energy consumption
ethylene separation process
Heating systems
Industries
Optimization
plant-wide optimization
Production
Separation processes
ISSN:1545-5955, 1558-3783
Online Access:Get full text
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Summary:Considering the complexity of centralized plant-wide optimization and the presence of communication delay in production units, a distributed asynchronous optimization framework is developed for energy consumption optimization problem during ethylene production. First, the energy consumption optimization problem of ethylene process is formulated into a distributed asynchronous optimization problem. Then, considering multiple production units and the material transfer time involved, each unit is treated as a node, and each node is decomposed into calculation nodes, constraint nodes, and delay nodes. Specifically, each production unit can be optimized asynchronously without the necessity for synchronization. To overcome the impact of communication delay on asynchronous process, state vectors are incorporated into the distributed parameter projection algorithm. Additionally, to ensure that the inseparable coupled constraints between nodes during asynchronous operations are met, the parameter projection algorithm is employed. Numerical experiments and industrial simulations demonstrate the proposed algorithm exhibits faster convergence speeds compared to distributed synchronous algorithms, and the energy consumption is lower than the results obtained by the centralized algorithm. Note to Practitioners-As the scale of ethylene production expands, traditional centralized optimization methods struggle to meet the demands of plant-wide optimization due to their high model complexity and slow convergence rates. In this study, we develop a distributed optimization framework, in which the large-scale complex model is decomposed into small parts, and the global optimization task is accomplished cooperatively through local information exchange. Furthermore, considering the time delay due to material residence time in processing units, a distributed asynchronous parameter projection algorithm is proposed to solve the energy consumption issue in ethylene plant. Experimental results demonstrate that the proposed method is capable of converging to the feasible solution in the presence of time delay. Compared with the existing centralized methods, the proposed asynchronous distributed algorithm exhibits better performance, i.e. lower energy consumption. Besides, the proposed asynchronous distributed optimization framework holds potential for application in other process industries, such as the metallurgical industry and steel production process.
ISSN:1545-5955
1558-3783
DOI:10.1109/TASE.2025.3550740