Abstract
Primary aluminum production is an uninterrupted and complex process that must operate in a closed loop, hindering possibilities for experiments to improve production. In this sense, it is important to have ways to simulate this process computationally without acting directly on the plant, since such direct intervention could be dangerous, expensive, and time-consuming. This problem is addressed in this paper by combining real data, the artificial neural network technique, and clustering methods to create soft sensors to estimate the temperature, the aluminum fluoride percentage in the electrolytic bath, and the level of metal of aluminum reduction cells (pots). An innovative strategy is used to split the entire dataset by section and lifespan of pots with automatic clustering for soft sensors. The soft sensors created by this methodology have small estimation mean squared error with high generalization power. Results demonstrate the effectiveness and feasibility of the proposed approach to soft sensors in the aluminum industry that may improve process control and save resources.
Highlights
Pure aluminum (Al) is one of nature’s most abundant elements, it is extremely difficult to extract, and extraction is not possible without the occurrence of some chemical reaction
This same behavior was identified for the other outputs and lifespan divisions
After testing different neural net and considering two differenttwo training algorithms, and testing different the best topologies and considering different trainingtraining algorithms, training and testingmodels, 5940 different models, the best model of each output variable was selected and it was possible to ensure that these models generate high generalization power and very small errors that are fully tolerated by process engineers
Summary
Pure aluminum (Al) is one of nature’s most abundant elements, it is extremely difficult to extract, and extraction is not possible without the occurrence of some chemical reaction. Al is always attached to some other chemical element in the form of salts or oxides, which makes separation necessary. In the 1880s, the young students Charles Hall and Paul Héroult used electrolysis to separate the Al of oxygen from alumina (Al2 O3 ) grains into salts fluxes such as cryolite (Na3 AlF6 ) This is the separation of alumina into alumina and oxygen, but the process requires the participation of other elements such as flux salts, gases, and chemical additives to maintain process stability, which makes the process more complex [1,3].
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