Evaluation of Energy Utilization Efficiency and Optimal Energy Matching Model of EAF Steelmaking Based on Association Rule Mining

Yang, Lingzhi; Li, Zhihui; Hu, Hang; Zou, Yuchi; Feng, Zeng; Chen, Weizhen; Chen, Feng; Wang, Shuai; Guo, Yufeng

doi:10.3390/met14040458

Cited by 2 publications

(1 citation statement)

References 42 publications

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“…На маршруте BF -BOF материальные и энергетические потоки тесно связаны, обеспечивая движение и трансформацию железосодержащих материалов и энергии [13]. Китайскими учеными разработаны структурные модели энергетических потоков в рамках концепции IDDD+N (Integration of the processes, Differentiation of the demand, Diversification of the supply, Decentralization of the grid, and Network of multi-energy flows) для оптимизации использования энергии, интеграции технологических процессов и децентрализации управления производством [14]. Структурная модель энергетических потоков включает системы преобразования, использования, рекуперации тепла, буфериза-current shortcomings of energy saving methods in metallurgical processes.…”

Section: Introductionunclassified

Energy saving model for related processes in steelmaking

Weishu,

Shuailong,

Weihui

et al. 2024

Izv. vysš. učebn. zaved., Čern. metall.

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In the development of advanced energy saving technologies in the metallurgical industry, a comprehensive approach to managing energy flows is crucial. This article presents an in-depth analysis of the steelmaking and metallurgical industry in China and Russia, focusing on the evolution and current shortcomings of energy saving methods in metallurgical processes. The authors thoroughly analyze various technological processes, including sintering, coking, pellet production, iron production in blast furnaces, steel production in oxygen converters and electric arc furnaces, as well as steel rolling, identifying significant potential for enhancing energy efficiency and reducing harmful emissions. The main outcome of the research is the development of structural models of technological processes based on the concept of energy saving “temperature matching, cascade utilization, and global linkage”, covering key stages of steelmaking. These models provide detailed descriptions of the role and interrelation of each process within the complete metallurgical cycle and combine into a comprehensive structural model of steelmaking technological process. The model includes not only specific operations and characteristics of each stage but also explains how these processes interact and depend on each other, forming an integrated and interconnected system of metallurgical production. This model encompasses comprehensive temperature-pressure and production links, providing a theoretical basis for the development of mathematical models of energy saving and the design of corresponding computer applications. The structural model of steelmaking technological process is important for understanding and optimizing the entire process of metallurgical production, contributing to its energy and ecological efficiency.

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Section: Introductionunclassified

Energy saving model for related processes in steelmaking

Weishu,

Shuailong,

Weihui

et al. 2024

Izv. vysš. učebn. zaved., Čern. metall.

View full text Add to dashboard Cite

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Numerical Study on Heat Transfer Characteristic of Hot Metal Transportation before EAF Steelmaking Process

Chen,

Hu,

Wang

et al. 2024

Metals

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The temperature of hot metal (HM) is crucial for the energy input and smelting in the electric arc furnace (EAF) steelmaking process with HM and scrap as the charge structure. However, due to the influence of many factors in the heat dissipation in HM transportation before the EAF steelmaking process, the temperature drop of HM before charged is usually fluctuating and uncertain. This situation is not conducive to the input energy control and energy optimization of the EAF steelmaking process. In this paper, a three-dimensional numerical model of a 90-ton hot metal ladle is established to simulate the heat transfer characteristic of HM transportation through ANSYS Fluent 2023 and verified by on-the-spot testing and sample analysis. The effects of ambient temperature, air velocity, slag thickness and furnace cover thickness on the temperature drop of HM are investigated and quantitatively analyzed in 30 numerical schemes. The results indicate that slag thickness is the most influential factor, followed by furnace cover thickness, air velocity and ambient temperature. In the case of 50 min transport time, the temperature drop of HM is 55.2, 15.06, 12.08, 10.38, 10.29 and 10.26 °C when the slag thickness is 0, 50, 100, 150, 200 and 250 mm, respectively. While HM is not covered by slag, the furnace cover can also greatly reduce the temperature drop. Based on the simulated data, a prediction model of HM temperature drop is obtained through the multi-factor coupling analysis and mathematical fitting. This study can help develop targeted insulation measures and determine the temperature of HM, which is expected to control the input energy for deep energy-saving optimization in the EAF steelmaking process.

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Evaluation of Energy Utilization Efficiency and Optimal Energy Matching Model of EAF Steelmaking Based on Association Rule Mining

Cited by 2 publications

References 42 publications

Energy saving model for related processes in steelmaking

Energy saving model for related processes in steelmaking

Numerical Study on Heat Transfer Characteristic of Hot Metal Transportation before EAF Steelmaking Process

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