Mathematical Model of Dynamic Operation and Optimum Control of Billet Reheating Furnace

被引:0
作者
刘日新
宁宝林
机构
[1] DeptofMetallurgyKunmingInstituteofTechnology,Kunming,,ChinaDeptofThermalEnergy,NortheastUniversityofTechnology,Shenyang,,China,DeptofMetallurgy,KunmingInstituteofTechnology,Kunming,,ChinaDeptofThermalEnergy,NortheastUniversityofTechnology,Shenyang,,China,
来源
Journal of Materials Science & Technology | 1992年 / 04期
关键词
reheating furnace; enthalpy increasing process; delay strategy; on-line computer control; mathematical model;
D O I
暂无
中图分类号
学科分类号
摘要
<正> This paper provides a mathematical model forthe billet reheating process in furnace.A newoptimum method is brought up that the objectivefunction is the integral value of enthalpy increasingprocess of a billet.Different delays are simulatedand calculated,some proper delay strategies are ob-tained.The on-line computer control model is de-veloped.The real production conditions simulated,the temperature deviation of drop out billet fromthe target temperature is kept within±15℃.
引用
收藏
页码:279 / 283
页数:5
相关论文
共 50 条
[31]   Dynamic furnace temperature setting research on combustion system of rolling mill reheating furnace [J].
Chen Wanli ;
Kong Ning ;
Wu Daohong .
12TH INTERNATIONAL CONFERENCE ON COMBUSTION & ENERGY UTILISATION, 2015, 66 :217-220
[32]   OPTIMIZING THE MODEL OF HEATING THE MATERIAL IN THE REHEATING FURNACE IN METALLURGY [J].
Spicka, I. ;
Heger, M. ;
Zimny, O. ;
Jancikova, Z. ;
Tykva, T. .
METALURGIJA, 2016, 55 (04) :719-722
[33]   An optimum operation and mathematical model of tidal energy system at red sea area [J].
Fahmy, FH .
ICEMS'2001: PROCEEDINGS OF THE FIFTH INTERNATIONAL CONFERENCE ON ELECTRICAL MACHINES AND SYSTEMS, VOLS I AND II, 2001, :664-667
[34]   Mathematical Model of Dynamic Heat‐ and Mass‐Exchange Processes in a Glassmaking Furnace [J].
V. É. Dzhashitov ;
V. M. Pankratov ;
A. V. Golikov .
Journal of Engineering Physics and Thermophysics, 2003, 76 (5) :1093-1103
[35]   Fuel gas operation management practices for reheating furnace in iron and steel industry [J].
Chen, D. M. ;
Liu, Y. H. ;
He, Y. H. ;
Xu, S. ;
Dai, F. Q. ;
Lu, B. .
ADVANCES IN PRODUCTION ENGINEERING & MANAGEMENT, 2020, 15 (02) :179-191
[36]   Adaptive Supervisory Control of an Industrial Steel Slab Reheating Furnace [J].
Waelen, A. A. ;
Young, Brent ;
Yu, Wei .
CHEMICAL PRODUCT AND PROCESS MODELING, 2009, 4 (03)
[37]   Simultaneous Optimization of Charging Scheduling and Heating Control in Reheating Furnace [J].
Fujii, Susumu ;
Urayama, Koji ;
Kashima, Kenji ;
Imura, Jun-ichi ;
Kurokawa, Tetsuaki ;
Adachi, Shuichi .
TETSU TO HAGANE-JOURNAL OF THE IRON AND STEEL INSTITUTE OF JAPAN, 2010, 96 (07) :B434-B442
[38]   Integrated Intelligence Control Based on Fuzzy and AI for Reheating Furnace [J].
Liao, Yingxin ;
Wu, Min ;
Hirota, Kaoru ;
Dong, Fangyan ;
Cao, Weihua .
JOURNAL OF ADVANCED COMPUTATIONAL INTELLIGENCE AND INTELLIGENT INFORMATICS, 2005, 9 (02) :211-222
[39]   Online simulation model of the slab-reheating process in a pusher-type furnace [J].
Jaklic, Anton ;
Vode, Franci ;
Kolenko, Tomaz .
APPLIED THERMAL ENGINEERING, 2007, 27 (5-6) :1105-1114
[40]   An Intelligent Temperature Control System for Nature Gas Reheating Furnace of Titanium [J].
Lv Yan ;
Wu Min ;
Lei Qi .
PROCEEDINGS OF THE 29TH CHINESE CONTROL CONFERENCE, 2010, :2588-2592
12345