Prediction and Optimization of Blast Furnace Parameters Based on Machine Learning and Genetic Algorithm

doi:10.12068/j.issn.1005-3026.2020.09.008

Journal of Northeastern University Natural Science ›› 2020, Vol. 41 ›› Issue (9): 1262-1267.DOI: 10.12068/j.issn.1005-3026.2020.09.008

• Materials & Metallurgy • Previous Articles Next Articles

Prediction and Optimization of Blast Furnace Parameters Based on Machine Learning and Genetic Algorithm

LI Zhuang-nian¹， CHU Man-sheng¹， LIU Zheng-gen¹， LI Bao-feng²

1.School of Metallurgy， Northeastern University， Shenyang 110819， China; 2.Ironmaking Plant， Shanxi Taigang Stainless Iron Shares Co.， Ltd.， Taiyuan 030003， China.

Received:2019-10-11 Revised:2019-10-11 Online:2020-09-15 Published:2020-09-15
Contact: CHU Man-sheng
About author:-
Supported by:
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Abstract

Abstract: To address the problem of low accuracy in the blast furnace ironmaking model， a precise multi-objective optimization model for the blast furnace production process was established.Firstly， the massive data from blast furnace were pre-processed before machine learning. Then， six kind of machine learning algorithms were used to predict coke ratio and K value， including support vector machine， random forest， gradient boosting regression tree， XGBoost， LightGBM and artificial neural network.Feature engineering and hyper-parameter tuning were used to optimize the prediction results from machine learning.Finally， the new ensemble learning method was used for prediction.Consequently， the proposed machine learning method has not only high accuracy， but also good robustness.Based on the prediction from machine learning， multi-objective optimization analysis of blast furnace parameters is further carried out by NSGA-Ⅱ algorithm so that Pareto optimal solution can be obtained. Therefore， the blast furnace operator can select the corresponding control parameters， according to these multi-objective optimization results.

Key words: blast furnace (BF), machine learning, ensemble learning, genetic algorithm, parameter prediction

CLC Number:

TF531

LI Zhuang-nian， CHU Man-sheng， LIU Zheng-gen， LI Bao-feng. Prediction and Optimization of Blast Furnace Parameters Based on Machine Learning and Genetic Algorithm[J]. Journal of Northeastern University Natural Science, 2020, 41(9): 1262-1267.

References

[1]Mitchell T T.Machine learning［M］.1st ed.New York:McGraw-Hill Education，1997:1-8.
[2]周志华.机器学习［M］.北京:清华大学出版社，2016:1-14.(Zhou Zhi-hua.Machine learning［M］.Beijing:Tsinghua University Press，2016:1-14.)
[3]李壮年，储满生，柳政根，等.大型高炉布料模型的研究与应用［J］.东北大学学报(自然科学版)，2016，37(5):658-662.(Li Zhuang-nian，Chu Man-sheng，Liu Zheng-gen，et al.Research and application of burden charging model for large BF［J］.Journal of Northeastern University (Natural Science)， 2016，37(5):658-662.)
[4]Ke G L，Meng Q，Finley T，et al.LightGBM:a highly efficient gradient boosting decision tree［C］//Advances in Neural Information Processing Systems.Long Beach，California，2017:3149-3157.
[5]Harrington P.Machine learning in action［M］.Greenwich，Connecticut:Manning Publications，2012:18-36.
[6]Vapnik V N.The nature of statistical learning theory ［M］.Berlin:Springer-Verlag，1995:1-50.
[7]Vapnik V N，Lerner A.Pattern recognition using generalized portrait method［J］.Automation and Remote Control， 1963，24(6):774-780.
[8]Vanderplas J.Python data science handbook［M］.Cambridge，Massachusetts:O′Reilly Media，2016:421-432.
[9]Chen T，Guestrin C.XGBoost:a scalable tree boosting system［C］//Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining.Washington D C，2016:785-794.
[10]Theodoridis S.Neural networks and deep learning［M］.［S.l.］:Determination Press，2015:1-30.
[11]Deb K，Pratap A，Agarwal S，et al.A fast and elitist multiobjective genetic algorithm:NSGA-II［J］.IEEE Transactions on Evolutionary Computation， 2002，6(2):190-197.
[12]Srinivas N，Deb K.Multi-objective function optimization using nondominated sorting genetic algorithm［J］.Evolutionary Computation， 1995，2(3):221-248.
[15]关守平，房少纯.一种新型的区间-粒子群优化算法［J］.东北大学学报(自然科学版)，2012，33(10):1381-1384.(Guan Shou-ping，Fang Shao-chun.A new interval particle swarm optimization algorithm［J］.Journal of Northeastern University(Natural Science)，2012，33(10):1381-1384.)

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Prediction and Optimization of Blast Furnace Parameters Based on Machine Learning and Genetic Algorithm

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