Hybrid self-learning model for the prediction and control of sintering furnace temperature

IF 5.4 2区 计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS Control Engineering Practice Pub Date : 2024-11-18 DOI:10.1016/j.conengprac.2024.106159
Yuanshen Dai , Ning Chen , Zhijiang Shao
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Abstract

Ternary cathode materials are important components of lithium-ion batteries. However, the sintering process during manufacturing is challenging to control due to the inaccessibility of key dynamic variables and the frequent fluctuations in operating conditions. These lead to high energy consumption and inconsistent product quality. In this paper, we propose a hybrid self-learning prediction model and control method for sintering furnace temperature based on both first-principle and process data. Firstly, a mechanism model with temperature time delay is established based on energy flow analysis in the furnace. To capture the tail gas temperature dynamic in the mechanism model, a Ventingformer-based prediction data-driven model is proposed. In this model, a memory updating technique and an autoregressive module based on the Transformer framework are developed to identify long-time dependencies and respond to variations in input sequences. Then, a hybrid self-learning modeling framework is designed. Based on the established hybrid model, a multiscale objective function-based nonlinear model predictive control (MSCF-NMPC) method is proposed to achieve precise tracking control of the internal temperature in the furnace. A multiscale objective function with short-term cost in terms of energy consumption and tracking accuracy as well as long-term cost in terms of energy loss is constructing in the control optimization problem. Finally, the proposed hybrid self-learning model and MSCF-NMPC method are verified using the actual process data from a sintering furnace, demonstrating the effectiveness of the proposed method. The results offer practical guidance for industrial applications.
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预测和控制烧结炉温度的混合自学模型
三元正极材料是锂离子电池的重要组成部分。然而,由于无法获得关键的动态变量以及操作条件的频繁波动,生产过程中的烧结工艺难以控制。这导致了高能耗和产品质量不稳定。本文提出了一种基于第一原理和过程数据的烧结炉温度混合自学习预测模型和控制方法。首先,基于炉内能量流分析,建立了温度时间延迟的机理模型。为了在机理模型中捕捉尾气温度动态,提出了基于 Ventingformer 的预测数据驱动模型。在该模型中,开发了基于变压器框架的记忆更新技术和自回归模块,以识别长期依赖关系并对输入序列的变化做出响应。然后,设计了一个混合自学习建模框架。基于建立的混合模型,提出了一种基于多尺度目标函数的非线性模型预测控制(MSCF-NMPC)方法,以实现对炉内温度的精确跟踪控制。在控制优化问题中,构建了一个多尺度目标函数,其中包括能耗和跟踪精度方面的短期成本以及能量损失方面的长期成本。最后,利用烧结炉的实际工艺数据对所提出的混合自学习模型和 MSCF-NMPC 方法进行了验证,证明了所提方法的有效性。这些结果为工业应用提供了实际指导。
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来源期刊
Control Engineering Practice
Control Engineering Practice 工程技术-工程:电子与电气
CiteScore
9.20
自引率
12.20%
发文量
183
审稿时长
44 days
期刊介绍: Control Engineering Practice strives to meet the needs of industrial practitioners and industrially related academics and researchers. It publishes papers which illustrate the direct application of control theory and its supporting tools in all possible areas of automation. As a result, the journal only contains papers which can be considered to have made significant contributions to the application of advanced control techniques. It is normally expected that practical results should be included, but where simulation only studies are available, it is necessary to demonstrate that the simulation model is representative of a genuine application. Strictly theoretical papers will find a more appropriate home in Control Engineering Practice''s sister publication, Automatica. It is also expected that papers are innovative with respect to the state of the art and are sufficiently detailed for a reader to be able to duplicate the main results of the paper (supplementary material, including datasets, tables, code and any relevant interactive material can be made available and downloaded from the website). The benefits of the presented methods must be made very clear and the new techniques must be compared and contrasted with results obtained using existing methods. Moreover, a thorough analysis of failures that may happen in the design process and implementation can also be part of the paper. The scope of Control Engineering Practice matches the activities of IFAC. Papers demonstrating the contribution of automation and control in improving the performance, quality, productivity, sustainability, resource and energy efficiency, and the manageability of systems and processes for the benefit of mankind and are relevant to industrial practitioners are most welcome.
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