Prediction of blast furnace silicon content and fluctuation based on skewness depth classification

被引：0

作者：

Luo S.-H. ^{[1
]}

Chen K. ^{[1
]}

机构：

[1] College of Statistics, Jiangxi University of Finance and Economics, Nanchang

来源：

Kongzhi yu Juece/Control and Decision | 2021年 / 36卷 / 02期

关键词：

Elman neural network; Logistic model; Prediction; Silicon content; Skew projection depth;

D O I：

10.13195/j.kzyjc.2019.1116

中图分类号：

学科分类号：

摘要：

Blast furnace smelting is a dynamic process with high complexity, chaos and time delay. In industry, molten iron silicon content is often used to feed back the fluctuation of blast furnace temperature and thermal state. The skew projection depth can reflect the outliers of the data well when the data is biased, and it is very robust in the classification calculation of high-dimensional data. Firstly, 11 influencing factors are determined as input variables through differential processing and correlation analysis in this paper, which are used to study the relationship between changes of various variables and changes of silicon content. Then, the data whose projection depth value is outside 90 % confidence interval are regarded as outliers and classified into stable and outliers. Finally, the stable data are predicted by Elman neural network prediction model, and the outliers are classified and predicted by Logistic model under different fluctuation directions of furnace temperature. The simulation results show that the prediction accuracy of stable class 157 furnace is up to 85.3 %, and that of outlier class is up to 82.6 %. Copyright ©2021 Control and Decision.

引用

页码：491 / 497

页数：6

共 18 条

[1] Shi L, Li Z L, Yu T, Et al., Model of hot metal silicon content in blast furnace based on principal component analysis application and partial least square, Journal of Iron and Steel Research (International), 18, 10, pp. 13-16, (2011)
[2] Chu M S, Yang X F, Shen F M., Numerical simulation of innovative operation of blast furnace based on multi-fluid model, Journal of Iron and Steel Research, 13, 6, pp. 8-15, (2006)
[3] Saxen H., Short-term prediction of silicon content in pig iron, Canadian Metallurgical Quarterly, 33, 4, pp. 319-326, (1994)
[4] Wen B J, Wu S L, Zhou H, Et al., Prediction model of silicon content in COREX molten iron based on BP neural network, Journal of Iron and Steel Research, 30, 10, pp. 776-781, (2018)
[5] Li Z L, Yang C J, Liu W H, Et al., Prediction of silicon content in molten iron based on lstm-rnn model, Journal of Chemical Engineering, 69, 3, pp. 992-997, (2018)
[6] Gong S H, Liu X G., Application of fuzzy bayesian network to predict the change trend of silicon content in molten iron of blast furnace, Metallurgical Automation, 29, 5, pp. 30-32, (2005)
[7] Liu X Y, Liu X G, Wang W H., Application of bayesian network in prediction of silicon content in molten iron of blast furnace, Iron and Steel, 40, 3, pp. 17-20, (2005)
[8] Xu X, Hua C C, Tang Y G, Et al., Modeling of the hot metal silicon content in blast furnace using support vector machine optimized by an improved particle swarm optimizer, Neural Computing and Applications, 27, 6, pp. 1451-1461, (2016)
[9] Zhao W, Ting Z S, Tao T, Et al., Adynamic particle filter-support vector regression method for reliability prediction, Reliability Engineering and System Safety, 119, 1, pp. 109-116, (2013)
[10] Fan Z F, Ma X P, Shao X G., Multistep predictive control of nonlinear RBF neural network, Control and Decision, 29, 7, pp. 1274-1278, (2014)

← 1 2 →