Establishment and Application of Steel Composition Prediction Model Based on t-Distributed Stochastic Neighbor Embedding (t-SNE) Dimensionality Reduction Algorithm

IF 2.5 3区材料科学 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY

Journal of Sustainable Metallurgy Pub Date : 2024-03-19 DOI:10.1007/s40831-024-00798-2

Xin Liu, Yanping Bao, Lihua Zhao, Chao Gu

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Abstract

To meet the goals of the national "Dual Carbon" strategy and reduce energy consumption in the steel industry, accurate prediction of steel composition is crucial for precise control over alloy addition in steelmaking. Several models have been created to predict the composition of the converter endpoint with a high level of accuracy. However, the different shortcomings of each have prevented large-scale application in real production environments. CBR prediction model has limited scope to solve the problem. CNN model has complex data processing and no memory. RELM model has randomly given input layer weights and hidden layer deviations. In this study, correlation analysis was used to analyze the factors influencing the carbon content at the endpoint of converter steelmaking. A feasible model was established and applied to predict the carbon content at the endpoint of converter using t-distributed stochastic neighbor embedding (t-SNE), particle swarm optimization (PSO), and backpropagation (BP) neural network. The learning rate, training times, and hidden layer nodes number of the prediction model were optimized. The prediction hit ratios for the carbon content in the error ranges of ± 0.003%, ± 0.01%, and ± 0.02% are 61%, 86%, and 98%, respectively. Meanwhile, apply the established model to actual production, the carbon content of the product can be stably controlled between the lower and median limits, the control effect is significantly better than traditional methods. The results demonstrate that the t-SNE-PSO-BP model performs better than the known models. The accurate prediction of the carbon content at the endpoint of converter can greatly contribute to realizing a “narrow composition control” of the molten steel. Realize accurate prediction of carbon content at the endpoint of converter smelting, and has been effectively applied to industrial production.

Graphical Abstract

Under the traditional method of predicting the endpoint carbon content of the converter, the hit rate of the middle and lower limits of the carbon content in the product is 48%. The t-SNE-PSO-BP model predicts the carbon content at the endpoint of the converter model, and the product carbon content can be controlled stably between 0.21–0.23%. According to the study results and actual application effects, use the t-SNE-PSO-BP model to predict the carbon content at the endpoint of the converter is appropriate, and is conducive to the “narrow composition control” of the steel composition in the converter steelmaking process.

Abstract Image

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基于 t 分布随机邻域嵌入（t-SNE）降维算法的钢成分预测模型的建立与应用

为了实现国家 "双碳 "战略的目标并降低钢铁工业的能耗，准确预测钢水成分对于精确控制炼钢过程中的合金添加至关重要。目前已有多个模型可以高精度地预测转炉终点的成分。然而，由于每个模型都存在不同的缺点，因此无法在实际生产环境中大规模应用。CBR 预测模型解决问题的范围有限。CNN 模型的数据处理复杂且没有内存。RELM 模型的输入层权重和隐藏层偏差是随机给定的。本研究采用相关性分析方法来分析转炉炼钢终点含碳量的影响因素。利用 t 分布随机邻域嵌入（t-SNE）、粒子群优化（PSO）和反向传播（BP）神经网络，建立并应用了一个可行的模型来预测转炉终点的含碳量。对预测模型的学习率、训练次数和隐层节点数进行了优化。在误差范围为± 0.003%、± 0.01%和± 0.02%时，碳含量的预测命中率分别为 61%、86%和 98%。同时，将建立的模型应用到实际生产中，产品的碳含量可以稳定地控制在下限和中限之间，控制效果明显优于传统方法。结果表明，t-SNE-PSO-BP 模型的性能优于已知模型。准确预测转炉终点的碳含量，对实现钢水的 "窄成分控制 "大有裨益。实现转炉冶炼终点含碳量的精确预测，并已有效应用于工业生产。图文摘要在传统的转炉终点含碳量预测方法下，产品中含碳量的中下限命中率为 48%。采用 t-SNE-PSO-BP 模型预测转炉模型终点含碳量，可将产品含碳量稳定控制在 0.21-0.23% 之间。根据研究结果和实际应用效果，使用 t-SNE-PSO-BP 模型预测转炉终点碳含量是合适的，有利于转炉炼钢过程中钢成分的 "窄成分控制"。

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来源期刊

Journal of Sustainable Metallurgy Materials Science-Metals and Alloys

CiteScore

4.00

自引率

12.50%

发文量

151

期刊介绍： Journal of Sustainable Metallurgy is dedicated to presenting metallurgical processes and related research aimed at improving the sustainability of metal-producing industries, with a particular emphasis on materials recovery, reuse, and recycling. Its editorial scope encompasses new techniques, as well as optimization of existing processes, including utilization, treatment, and management of metallurgically generated residues. Articles on non-technical barriers and drivers that can affect sustainability will also be considered.