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Chemical Thermodynamics and Reaction Kinetics of Bayer Process Desilication Read chapter Read first chapter

2024 | OriginalPaper | Chapter

Construction and Application of Digital Twin in Aluminum Electrolysis

Authors : Jiaqi Li, Kejia Qiang, Chunhua Yang, Xiaofang Chen, Jie Li, Hongliang Zhang

Published in: Light Metals 2024

Publisher: Springer Nature Switzerland

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Abstract

The fourth industrial revolution, commonly referred to as Industry 4.0, with smart manufacturing at its forefront has arrived. This work focuses on the deep integration of advanced digital twin technology and traditional aluminium electrolysis technology, involving the overall architecture design, core technological development, and demonstrative application study. A five-dimensional modeling method and a standard application framework for aluminum electrolysis are proposed for the first time. The constructed digital twin of aluminium electrolysis comprises three levels: electrolysis plant, workshop, and equipment, and is equipped with advanced functions such as real-time monitoring, data management, virtual-real mapping, and intelligent decision-making. The engineering applications of digital twin technology in aluminium electrolysis have demonstrated its efficacy, producing favourable results in terms of labour downsizing, energy conservation, and pollution reduction. This research is expected to establish a solid groundwork for the digitalization and intelligent advancement of aluminium electrolysis.

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previous chapter Predicting Electrolyte and Liquidus Temperatures of Aluminium Smelting Cells for Power Modulation Using Dynamic Model
next chapter Estimation of the Spatial Alumina Concentration of an Aluminium Smelting Cell Using a Huber Function-Based Kalman Filter
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Metadata
Title
Construction and Application of Digital Twin in Aluminum Electrolysis
Authors
Jiaqi Li
Kejia Qiang
Chunhua Yang
Xiaofang Chen
Jie Li
Hongliang Zhang
Copyright Year
2024
Book
Light Metals 2024

Print ISBN: 978-3-031-50307-8

Electronic ISBN: 978-3-031-50308-5

Copyright Year: 2024

DOI
https://doi.org/10.1007/978-3-031-50308-5_58

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